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</div><h2>HL Paper 2</h2><div class="specification">
<p class="p1">The periodic table shows the relationship between electron configuration and the properties of elements and is a valuable tool for making predictions in chemistry.</p>
</div>
<div class="specification">
<p class="p1">The ten elements in the first-row d-block have characteristic properties and many uses.</p>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">Define the term <em>electronegativity</em>.</p>
<div class="marks">[2]</div>
<div class="question_part_label">b.i.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">(i) <span class="Apple-converted-space"> </span>Outline <strong>two </strong>reasons why a sodium ion has a smaller radius than a sodium atom.</p>
<p class="p1">(ii) <span class="Apple-converted-space"> </span>Explain why the ionic radius of \({{\text{P}}^{3 - }}\) is <strong>greater </strong>than the ionic radius of \({\text{S}}{{\text{i}}^{4 + }}\).</p>
<div class="marks">[4]</div>
<div class="question_part_label">c.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">The graph below represents the successive ionization energies of sodium. The vertical axis plots log (ionization energy) instead of ionization energy to allow the data to be represented without using an unreasonably long vertical axis.</p>
<p class="p1"><img src="images/Schermafbeelding_2016-10-11_om_06.18.18.png" alt="M10/4/CHEMI/HP2/ENG/TZ2/06.d"></p>
<p class="p1">State the full electron configuration of sodium and explain how the successive ionization energy data for sodium are related to its electron configuration.</p>
<div class="marks">[4]</div>
<div class="question_part_label">d.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">(i) Explain why the first ionization energy of aluminium is <strong>lower </strong>than the first ionization energy of magnesium.</p>
<p class="p1">(ii) Explain why the first ionization energy of sulfur is <strong>lower </strong>than the first ionization energy of phosphorus.</p>
<div class="marks">[4]</div>
<div class="question_part_label">e.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">State and explain the type of reaction that takes place between \({\text{F}}{{\text{e}}^{3 + }}\) and \({{\text{H}}_{\text{2}}}{\text{O}}\) to form \({{\text{[Fe(}}{{\text{H}}_{\text{2}}}{\text{O}}{{\text{)}}_{\text{6}}}{\text{]}}^{3 + }}\) in terms of acid-base theories.</p>
<div class="marks">[2]</div>
<div class="question_part_label">f.i.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">Explain why \({{\text{[Fe(}}{{\text{H}}_{\text{2}}}{\text{O}}{{\text{)}}_{\text{6}}}{\text{]}}^{3 + }}\) is coloured.</p>
<div class="marks">[3]</div>
<div class="question_part_label">f.ii.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">Outline the economic significance of the use of a catalyst in the Haber process which is an exothermic reaction.</p>
<div class="marks">[2]</div>
<div class="question_part_label">f.iii.</div>
</div>
<h2 style="margin-top: 1em">Markscheme</h2>
<div class="question" style="padding-left: 20px;">
<p class="p1">power/strength/ability of an atom to attract electrons/shared electron pair / <em>OWTTE</em>;</p>
<p class="p1">in a (covalent) bond;</p>
<p class="p1"><em>Accept the word “element” in place of “atom”.</em></p>
<p class="p1"><em>Do not accept electron (singular).</em></p>
<div class="question_part_label">b.i.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p class="p1">(i) <span class="Apple-converted-space"> </span><em>Na</em>: 11 p, 11/ 2.8.1 \({{\text{e}}^ - }\) <strong>and </strong>\({\text{N}}{{\text{a}}^ + }\): 11 p, 10 / 2.8 \({{\text{e}}^ - }\) / same number of protons, less electrons / \({\text{N}}{{\text{a}}^ + }\) has 2 shells/energy levels, Na has 3 / <em>OWTTE</em>;</p>
<p class="p1"><em>Na</em><sup><span class="s2"><em>+</em></span></sup>: has greater net positive charge/same number of protons pulling smaller number of electrons;</p>
<p class="p1">(ii) <span class="Apple-converted-space"> </span><em>Si</em><sup><span class="s2"><em>4+</em></span></sup>: 10 \({{\text{e}}^ - }\) in 2 (filled) energy levels / electron arrangement 2.8 / <em>OWTTE</em>;</p>
<p class="p1"><em>P</em><sup><span class="s2"><em>3−</em></span></sup>: 18 \({{\text{e}}^ - }\) in 3 (filled) energy levels / electron arrangement 2.8.8, thus larger / <em>OWTTE</em>;</p>
<p class="p1"><strong>OR</strong></p>
<p class="p1">\({\text{S}}{{\text{i}}^{4 + }}\): has 2 energy levels where as \({{\text{P}}^{3 - }}\) has 3/ \({{\text{P}}^{3 - }}\) has one more (filled) energy</p>
<p class="p1">level;</p>
<p class="p1">\({\text{S}}{{\text{i}}^{4 + }}\): 10 \({{\text{e}}^ - }\) in 2 energy levels where as \({{\text{P}}^{3 - }}\)<span class="s2"> </span>has 18 \({{\text{e}}^ - }\), thus larger;</p>
<div class="question_part_label">c.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p class="p1">\({\text{1}}{{\text{s}}^{\text{2}}}{\text{2}}{{\text{s}}^{\text{2}}}{\text{2}}{{\text{p}}^{\text{6}}}{\text{3}}{{\text{s}}^{\text{1}}}\);</p>
<p class="p1"><em>Do not accept [Ne] 3s</em><sup><span class="s1"><em>1</em></span></sup>.</p>
<p class="p1">first electron easy/easiest to remove <span class="s2"><strong>/ </strong></span>1 electron in outermost/\({\text{n}} = 3\) energy level;</p>
<p class="p1">large increase between 1<sup><span class="s3">st </span></sup>and 2<sup><span class="s3">nd </span></sup>IE as electron now removed from \({\text{n}} = 2\) / next 8 electrons more difficult to remove / show (relatively) small increase as these electrons are in the same energy level/second energy level/\({\text{n}} = 2\);</p>
<p class="p1">large increase between 9<sup><span class="s3">th </span></sup>and 10<sup><span class="s3">th </span></sup>IE as electron now removed from n = 1 / 2</p>
<p class="p1">electrons very hard/most difficult to remove <span class="s2"><strong>/ </strong></span>innermost/lowest/closest to the nucleus/energy level/\({\text{n}} = 1\) / <em>OWTTE</em>;</p>
<p class="p1">electron 11 also comes from 1s, so shows a small increase;</p>
<div class="question_part_label">d.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p class="p1">(i) outer electron in Al is in 3p/p orbital/sub-shell/sub-level;</p>
<p class="p1">higher orbital/sub-shell / e<sup>–</sup><span class="s1"> </span>further from nucleus / shielded by 3s electrons;</p>
<p class="p1">(ii) in S, electron paired in 3p/p orbital/sub-shell/sub-level;</p>
<p class="p1"><em>Accept extra stability associated with half filled p sub-shell (in P).</em></p>
<p class="p1">repulsion between paired electrons (and therefore easier to remove);</p>
<div class="question_part_label">e.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p class="p1">Lewis acid-base (reaction);</p>
<p class="p1">\({{\text{H}}_{\text{2}}}{\text{O}}\): e-pair donor, \({\text{F}}{{\text{e}}^{3 + }}\): \({{\text{e}}^ - }\) pair acceptor / \({{\text{H}}_{\text{2}}}{\text{O}}\) donates an electron pair to \({\text{F}}{{\text{e}}^{3 + }}\);</p>
<div class="question_part_label">f.i.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p class="p1">d sub-levels are split into two sets of orbitals (of different energies);</p>
<p class="p1">electron transitions between (d) orbitals of different energies / d-d transition(s);</p>
<p class="p1">transmitted (visible) light is complementary colour;</p>
<div class="question_part_label">f.ii.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p class="p1">(exothermic reactions) low temperature/less energy increases ammonia yield;</p>
<p class="p1">(iron) catalyst used to increase rate of reaction / equilibrium reached faster / same yield but produced faster/in shorter/less time;</p>
<div class="question_part_label">f.iii.</div>
</div>
<h2 style="margin-top: 1em">Examiners report</h2>
<div class="question" style="padding-left: 20px;">
<p class="p1">Generally, the definition of electronegativity was good, but some made the error of saying that it was the attraction of one electron only; others did not specify that it is the ability of an atom to attract a shared electron pair in a covalent bond.</p>
<div class="question_part_label">b.i.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p class="p1">Reasons why a sodium ion has a smaller radius than a sodium atom solicited incomplete answers. The answer requires the number of shells, electrons and protons of both the ion and the atom. Many candidates correctly said that \({\text{N}}{{\text{a}}^ + }\) had the same number of protons but one electron less so the pulling effect on the electrons was greater. Not many candidates gave the electronic structure or number of shells of the two ions, \({{\text{P}}^{3 - }}\) and \({\text{S}}{{\text{i}}^{4 + }}\), to explain their difference in ionic radius.</p>
<div class="question_part_label">c.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p class="p1">The graphical question on successive ionization energies of sodium was well answered by many. Typically, they explained how the successive ionization energies of sodium are related to its electron configuration from the data given. Most candidates realized that aluminium’s outer electron is in the 3p orbital so further from the nucleus and thus easier to ionize than magnesium. Similarly, sulfur has a paired electron in the 3p sub-shell and the repulsion between paired electrons is greater than in phosphorus which has a half filled p sub-shell.</p>
<div class="question_part_label">d.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p class="p1">Many candidates did not give sufficient answers to the part on transition elements. Some realised that it was a Lewis acid-base reaction where the electrons are donated by the water molecule to \({\text{F}}{{\text{e}}^{3 + }}\). Explanations given for the colour of complex ions continue to be muddled and the language used imprecise. Many wrote of “<strong>a </strong>split d <strong>orbital</strong><em>” </em>rather than the d sub-level being split into two sets of orbitals (of different energies). The colour seen was often attributed to electrons emitting those wavelengths in transitions from higher energy to lower energy d orbitals rather than the transmitted visible light being the complementary colour of the one absorbed.</p>
<div class="question_part_label">e.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p class="p1">Few complete answers were given about economic significance of the use of a catalyst in the Haber process. A point that was missing often was that because the reaction is exothermic the forward reaction would be favoured (and the yield) if the temperature is lowered, but this would bring about a slower reaction so a catalyst is necessary to reach the equilibrium faster. However, there were misconceptions both in as far as catalysts and energetic is concerned. It was surprising to see the number of candidates who referred to activation energy but used the concept incorrectly<span class="s1"><strong>. </strong></span>Few candidates established a connection with equilibrium.</p>
<div class="question_part_label">f.i.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p class="p1">Few complete answers were given about economic significance of the use of a catalyst in the Haber process. A point that was missing often was that because the reaction is exothermic the forward reaction would be favoured (and the yield) if the temperature is lowered, but this would bring about a slower reaction so a catalyst is necessary to reach the equilibrium faster. However, there were misconceptions both in as far as catalysts and energetic is concerned. It was surprising to see the number of candidates who referred to activation energy but used the concept incorrectly<span class="s1"><strong>. </strong></span>Few candidates established a connection with equilibrium.</p>
<div class="question_part_label">f.ii.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p class="p1">Few complete answers were given about economic significance of the use of a catalyst in the Haber process. A point that was missing often was that because the reaction is exothermic the forward reaction would be favoured (and the yield) if the temperature is lowered, but this would bring about a slower reaction so a catalyst is necessary to reach the equilibrium faster. However, there were misconceptions both in as far as catalysts and energetic is concerned. It was surprising to see the number of candidates who referred to activation energy but used the concept incorrectly<span class="s1"><strong>. </strong></span>Few candidates established a connection with equilibrium.</p>
<div class="question_part_label">f.iii.</div>
</div>
<br><hr><br><div class="specification">
<p>The emission spectrum of an element can be used to identify it.</p>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Hydrogen spectral data give the frequency of 3.28 × 10<sup>15</sup> s<sup>−1</sup> for its convergence limit.</p>
<p>Calculate the ionization energy, in J, for a single atom of hydrogen using sections 1 and 2 of the data booklet.</p>
<div class="marks">[1]</div>
<div class="question_part_label">a.iii.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Calculate the wavelength, in m, for the electron transition corresponding to the frequency in (a)(iii) using section 1 of the data booklet.</p>
<div class="marks">[1]</div>
<div class="question_part_label">a.iv.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Deduce any change in the colour of the electrolyte during electrolysis.</p>
<div class="marks">[1]</div>
<div class="question_part_label">c.iv.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Deduce the gas formed at the anode (positive electrode) when graphite is used in place of copper.</p>
<div class="marks">[1]</div>
<div class="question_part_label">c.v.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Explain why transition metals exhibit variable oxidation states in contrast to alkali metals.</p>
<p><img 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"></p>
<p> </p>
<div class="marks">[2]</div>
<div class="question_part_label">d.</div>
</div>
<h2 style="margin-top: 1em">Markscheme</h2>
<div class="question" style="padding-left: 20px;">
<p>IE <strong>«</strong>= Δ<em>E =</em> <em>h</em>ν = 6.63 × 10<sup>–34</sup> J s × 3.28 × 10<sup>15</sup> s<sup>–1</sup><strong>» =</strong> 2.17 × 10<sup>–18</sup> <strong>«</strong>J<strong>»</strong></p>
<p><em><strong>[1 mark]</strong></em></p>
<div class="question_part_label">a.iii.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p><strong>«</strong>\(\lambda = \frac{C}{{\text{v}}} = \frac{{3.00 \times {{10}^8}{\text{ m}}{{\text{s}}^{ - 1}}}}{{3.28 \times {{10}^{15}}{\text{ }}{{\text{s}}^{ - 1}}}} = \)<strong>»</strong> 9.15 × 10<sup>–8</sup> <strong>«</strong>m<strong>»</strong></p>
<p><em><strong>[1 mark]</strong></em></p>
<div class="question_part_label">a.iv.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p>no change <strong>«</strong>in colour<strong>»</strong></p>
<p> </p>
<p><em>Do </em><strong><em>not </em></strong><em>accept “solution around cathode </em><em>will become paler and solution around </em><em>the anode will become darker”.</em></p>
<p><strong><em>[1 mark]</em></strong></p>
<div class="question_part_label">c.iv.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p>oxygen/O<sub>2</sub></p>
<p> </p>
<p><em>Accept “carbon dioxide/CO2”.</em></p>
<p><strong><em>[1 mark]</em></strong></p>
<div class="question_part_label">c.v.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p><em>Transition metals:</em></p>
<p><strong>«</strong>contain<strong>» </strong>d and s orbitals <strong>«</strong>which are close in energy<strong>»</strong></p>
<p><strong><em>OR</em></strong></p>
<p><strong>«</strong>successive<strong>» </strong>ionization energies increase gradually</p>
<p> </p>
<p><em>Alkali metals</em>:</p>
<p>second electron removed from <strong>«</strong>much<strong>» </strong>lower energy level</p>
<p><strong><em>OR</em></strong></p>
<p>removal of second electron requires large increase in ionization energy</p>
<p><em><strong>[2 marks]</strong></em></p>
<div class="question_part_label">d.</div>
</div>
<h2 style="margin-top: 1em">Examiners report</h2>
<div class="question" style="padding-left: 20px;">
[N/A]
<div class="question_part_label">a.iii.</div>
</div>
<div class="question" style="padding-left: 20px;">
[N/A]
<div class="question_part_label">a.iv.</div>
</div>
<div class="question" style="padding-left: 20px;">
[N/A]
<div class="question_part_label">c.iv.</div>
</div>
<div class="question" style="padding-left: 20px;">
[N/A]
<div class="question_part_label">c.v.</div>
</div>
<div class="question" style="padding-left: 20px;">
[N/A]
<div class="question_part_label">d.</div>
</div>
<br><hr><br><div class="specification">
<p class="p1">Copper is a metal that has been used by humans for thousands of years.</p>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">State the full electron configuration of \(^{{\text{65}}}{\text{Cu}}\).</p>
<div class="marks">[1]</div>
<div class="question_part_label">a.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">State one difference in the physical properties of the isotopes \(^{{\text{63}}}{\text{Cu}}\) and \(^{{\text{65}}}{\text{Cu}}\) and explain why their chemical properties are the same.</p>
<p class="p1">Physical:</p>
<p class="p1"> </p>
<p class="p1">Chemical:</p>
<div class="marks">[2]</div>
<div class="question_part_label">b.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">Describe the bonding in solid copper.</p>
<div class="marks">[2]</div>
<div class="question_part_label">c.</div>
</div>
<h2 style="margin-top: 1em">Markscheme</h2>
<div class="question" style="padding-left: 20px;">
<p class="p1">\({\text{1}}{{\text{s}}^{\text{2}}}{\text{2}}{{\text{s}}^{\text{2}}}{\text{2}}{{\text{p}}^{\text{6}}}{\text{3}}{{\text{s}}^{\text{2}}}{\text{3}}{{\text{p}}^{\text{6}}}{\text{3}}{{\text{d}}^{{\text{10}}}}{\text{4}}{{\text{s}}^{\text{1}}}{\text{/1}}{{\text{s}}^{\text{2}}}{\text{2}}{{\text{s}}^{\text{2}}}{\text{2}}{{\text{p}}^{\text{6}}}{\text{3}}{{\text{s}}^{\text{2}}}{\text{3}}{{\text{p}}^{\text{6}}}{\text{4}}{{\text{s}}^{{\text{13}}}}{{\text{d}}^{{\text{10}}}}\);</p>
<div class="question_part_label">a.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p class="p1"><em>Physical:</em></p>
<p class="p1">\(^{{\text{63}}}{\text{Cu}}\) lower boiling point/melting point/density/greater rate of diffusion than \(^{{\text{65}}}{\text{Cu}}\);</p>
<p class="p1"><em>Accept converse argument.</em></p>
<p class="p1"><em>Do not accept “different mass”.</em></p>
<p class="p1"><em>Chemical:</em></p>
<p class="p1">(properties identical because) same electron configuration/arrangement of electrons;</p>
<p class="p1"><em>Accept “same number of protons </em><strong><em>and </em></strong><em>electrons”.</em></p>
<p class="p1"><em>Do not accept “same number of electrons” OR “same valence (electrons)” OR “same atomic number” only.</em></p>
<div class="question_part_label">b.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p class="p1"><span style="text-decoration: underline;">electrostatic</span> attraction;</p>
<p class="p1">between (a lattice of) cations/positive ions <strong>and </strong>delocalized/sea of electrons;</p>
<p class="p1"><em>Do not award any mark for only stating “metallic bonding”.</em></p>
<div class="question_part_label">c.</div>
</div>
<h2 style="margin-top: 1em">Examiners report</h2>
<div class="question" style="padding-left: 20px;">
<p class="p1">Most were able to quote the electron configuration of copper correctly; but some gave [Ar] \({\text{4}}{{\text{s}}^{\text{1}}}\,{\text{3}}{{\text{d}}^{\text{9}}}\) when they were specifically asked for the <em>full </em>configuration. A few, inevitably gave \({\text{3}}{{\text{d}}^{\text{9}}}\,{\text{4}}{{\text{s}}^{\text{2}}}\). In (b), few related the difference in mass to a <em>property </em>and most did not give the comparison; “the same number of electrons and protons” was more popular than “the same electron configuration”. The descriptions of metallic bonding were disappointing; the mark for electrostatic attraction was rarely scored and many confused “nuclei” with “cations/positive ions”.</p>
<div class="question_part_label">a.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p class="p1">Most were able to quote the electron configuration of copper correctly; but some gave [Ar] \({\text{4}}{{\text{s}}^{\text{1}}}\,{\text{3}}{{\text{d}}^{\text{9}}}\) when they were specifically asked for the <em>full </em>configuration. A few, inevitably gave \({\text{3}}{{\text{d}}^{\text{9}}}\,{\text{4}}{{\text{s}}^{\text{2}}}\). In (b), few related the difference in mass to a <em>property </em>and most did not give the comparison; “the same number of electrons and protons” was more popular than “the same electron configuration”. The descriptions of metallic bonding were disappointing; the mark for electrostatic attraction was rarely scored and many confused “nuclei” with “cations/positive ions”.</p>
<div class="question_part_label">b.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p class="p1">Most were able to quote the electron configuration of copper correctly; but some gave [Ar] \({\text{4}}{{\text{s}}^{\text{1}}}\,{\text{3}}{{\text{d}}^{\text{9}}}\) when they were specifically asked for the <em>full </em>configuration. A few, inevitably gave \({\text{3}}{{\text{d}}^{\text{9}}}\,{\text{4}}{{\text{s}}^{\text{2}}}\). In (b), few related the difference in mass to a <em>property </em>and most did not give the comparison; “the same number of electrons and protons” was more popular than “the same electron configuration”. The descriptions of metallic bonding were disappointing; the mark for electrostatic attraction was rarely scored and many confused “nuclei” with “cations/positive ions”.</p>
<div class="question_part_label">c.</div>
</div>
<br><hr><br><div class="specification">
<p>Bonds can be formed in many ways.</p>
</div>
<div class="specification">
<p>Bonds can be formed in many ways.</p>
</div>
<div class="specification">
<p>The equilibrium for a mixture of NO<sub>2</sub> and N<sub>2</sub>O<sub>4</sub> gases is represented as:</p>
<p style="text-align: center;">2NO<sub>2</sub>(g) \( \rightleftharpoons \) N<sub>2</sub>O<sub>4</sub>(g)</p>
<p>At 100°C, the equilibrium constant, <em>K</em><sub>c</sub>, is 0.21.</p>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Discuss the bonding in the resonance structures of ozone.</p>
<div class="marks">[3]</div>
<div class="question_part_label">b.i.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Deduce one resonance structure of ozone and the corresponding formal charges on each oxygen atom.</p>
<div class="marks">[2]</div>
<div class="question_part_label">b.ii.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>The first six ionization energies, in kJ mol<sup>–1</sup>, of an element are given below.</p>
<p style="text-align: left;"><img src="images/Schermafbeelding_2017-09-21_om_08.29.16.png" alt="M17/4/CHEMI/HP2/ENG/TZ2/04.c"></p>
<p>Explain the large increase in ionization energy from IE<sub>3</sub> to IE<sub>4</sub>.</p>
<div class="marks">[2]</div>
<div class="question_part_label">c.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>At a given time, the concentration of NO<sub>2</sub>(g) and N<sub>2</sub>O<sub>4</sub>(g) were 0.52 and \(0.10{\text{ mol}}\,{\text{d}}{{\text{m}}^{ - 3}}\) respectively.</p>
<p>Deduce, showing your reasoning, if the forward or the reverse reaction is favoured at this time.</p>
<div class="marks">[2]</div>
<div class="question_part_label">d.i.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Comment on the value of Δ<em>G</em> when the reaction quotient equals the equilibrium constant, <em>Q</em> = <em>K</em>.</p>
<div class="marks">[2]</div>
<div class="question_part_label">d.ii.</div>
</div>
<h2 style="margin-top: 1em">Markscheme</h2>
<div class="question" style="padding-left: 20px;">
<p>lone pair on p orbital «of O atom» overlaps/delocalizes with pi electrons «from double bond»</p>
<p>both O–O bonds have equal bond length<br><em><strong>OR</strong></em><br>both O–O bonds have same/1.5 bond order<br><em><strong>OR</strong></em><br>both O–O are intermediate between O–O <em><strong>AND</strong> </em>O=O </p>
<p>both O–O bonds have equal bond energy</p>
<p> </p>
<p><em>Accept “p/pi/\(\pi \) electrons are delocalized/not localized”.</em></p>
<p><strong><em>[3 marks]</em></strong></p>
<div class="question_part_label">b.i.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p><em><strong>ALTERNATIVE 1:</strong></em></p>
<p><img src="data:image/png;base64,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"></p>
<p>FC: –1 <em><strong>AND</strong> </em>+1 <em><strong>AND</strong> </em>0</p>
<p> </p>
<p><em><strong>ALTERNATIVE 2:</strong></em></p>
<p><img src="data:image/png;base64,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"></p>
<p>FC: 0 <em><strong>AND</strong> </em>+1 <em><strong>AND</strong> </em>–1</p>
<p> </p>
<p><em>Accept any combination of lines, dots or crosses to represent electrons.</em></p>
<p><em>Do not accept structure that represents 1.5 bonds.</em></p>
<p><em>Do not penalize missing lone pairs if already penalized in 3(b).</em></p>
<p><em>If resonance structure is incorrect, no ECF.</em></p>
<p><em>Any one of the structures with correct formal charges for <strong>[2 max]</strong>.</em></p>
<p><strong><em>[2 marks]</em></strong></p>
<div class="question_part_label">b.ii.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p><em>Any two of:</em><br>IE<sub>4</sub>: electron in lower/inner shell/energy level<br><em><strong>OR</strong></em><br>IE<sub>4</sub>: more stable/full electron shell</p>
<p>IE<sub>4</sub>: electron closer to nucleus<br><em><strong>OR</strong></em><br>IE<sub>4</sub>: electron more tightly held by nucleus</p>
<p>IE<sub>4</sub>: less shielding by complete inner shells</p>
<p> </p>
<p><em>Accept “increase in effective nuclear charge” for M2.</em></p>
<p><strong><em>[2 marks]</em></strong></p>
<div class="question_part_label">c.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p>«<em>Q</em><sub>c</sub> = \(\frac{{0.10}}{{{{0.52}^2}}}\) =» 0.37<br>reaction proceeds to the left/NO<sub>2</sub>(g) «until Q = <em>K</em><sub>c</sub>»<br><em><strong>OR</strong></em><br>reverse reaction «favoured»</p>
<p> </p>
<p><em>Do not award M2 without a calculation for M1 but remember to apply ECF.</em></p>
<p><strong><em>[2 marks]</em></strong></p>
<div class="question_part_label">d.i.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p>Δ<em>G</em> = 0<br>reaction at equilibrium<br><em><strong>OR</strong></em><br>rate of forward and reverse reaction is the same<br><em><strong>OR</strong></em><br>constant macroscopic properties</p>
<p><em><strong>[2 marks]</strong></em></p>
<div class="question_part_label">d.ii.</div>
</div>
<h2 style="margin-top: 1em">Examiners report</h2>
<div class="question" style="padding-left: 20px;">
[N/A]
<div class="question_part_label">b.i.</div>
</div>
<div class="question" style="padding-left: 20px;">
[N/A]
<div class="question_part_label">b.ii.</div>
</div>
<div class="question" style="padding-left: 20px;">
[N/A]
<div class="question_part_label">c.</div>
</div>
<div class="question" style="padding-left: 20px;">
[N/A]
<div class="question_part_label">d.i.</div>
</div>
<div class="question" style="padding-left: 20px;">
[N/A]
<div class="question_part_label">d.ii.</div>
</div>
<br><hr><br><div class="specification">
<p>Magnesium, a reactive metal found in many common minerals, is also an essential nutrient for both plants and animals.</p>
</div>
<div class="specification">
<p>Successive ionization energies of magnesium are given in the table below.</p>
<p><img src="images/Schermafbeelding_2016-08-14_om_07.56.03.png" alt="M14/4/CHEMI/HP2/ENG/TZ2/08.b"></p>
</div>
<div class="specification">
<p>Magnesium metal is mainly used as a component in lightweight alloys, particularly in combination with aluminium and titanium.</p>
</div>
<div class="specification">
<p>Magnesium is usually produced by the electrolysis of molten magnesium chloride.</p>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Define the term <em>first ionization energy</em>.</p>
<div class="marks">[2]</div>
<div class="question_part_label">a.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>(i) Explain why the second ionization energy is greater than the first ionization energy.</p>
<p> </p>
<p> </p>
<p> </p>
<p> </p>
<p>(ii) Explain why the third ionization energy is much greater than the second ionization energy.</p>
<div class="marks">[4]</div>
<div class="question_part_label">b.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Although magnesium is usually found as \({\text{M}}{{\text{g}}^{2 + }}\) in its compounds, it is possible to use the Born-Haber cycle to investigate the possibility of \({\text{M}}{{\text{g}}^ + }\) being able to form stable compounds.</p>
<p>Use the ionization energy data from part (b), along with the other data provided below, to determine the enthalpy change of formation of MgCl(s). Assume that, because \({\text{M}}{{\text{g}}^ + }\) would be similar in size to \({\text{N}}{{\text{a}}^ + }\), MgCl would have a similar lattice enthalpy to NaCl.</p>
<p> Enthalpy of atomization of Mg \( + 146{\text{ kJ}}\,{\text{mo}}{{\text{l}}^{ - 1}}\)</p>
<p> Bond enthalpy in \({\text{C}}{{\text{l}}_{\text{2}}}\) \( + 243{\text{ kJ}}\,{\text{mo}}{{\text{l}}^{ - 1}}\)</p>
<p> Electron affinity of Cl \( + 349{\text{ kJ}}\,{\text{mo}}{{\text{l}}^{ - 1}}\)</p>
<p> Lattice enthalpy of NaCl \( + 790{\text{ kJ}}\,{\text{mo}}{{\text{l}}^{ - 1}}\)</p>
<div class="marks">[3]</div>
<div class="question_part_label">c.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Consider the lattice enthalpies of \({\text{Mg}}{{\text{F}}_{\text{2}}}\), \({\text{MgC}}{{\text{l}}_2}\) and \({\text{CaC}}{{\text{l}}_{\text{2}}}\). List these from the most endothermic to the least endothermic and explain your order.</p>
<p> </p>
<p>\({\text{Most endothermic}} \to {\text{Least endothermic}}\)</p>
<div class="marks">[3]</div>
<div class="question_part_label">d.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Magnesium hydroxide, \({\text{Mg(OH}}{{\text{)}}_{\text{2}}}\), is only sparingly soluble in water and the equilibrium below exists when excess solid is in contact with a saturated solution.</p>
<p>\[{\text{Mg(OH}}{{\text{)}}_2}{\text{(s)}} \rightleftharpoons {\text{M}}{{\text{g}}^{2 + }}{\text{(aq)}} + {\text{2O}}{{\text{H}}^ - }{\text{(aq)}}\]</p>
<p>Outline how the solubility of magnesium hydroxide will vary with pH.</p>
<div class="marks">[2]</div>
<div class="question_part_label">e.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>(i) Describe the bonding present in magnesium metal.</p>
<p> </p>
<p> </p>
<p> </p>
<p>(ii) Suggest why magnesium is harder than sodium.</p>
<p> </p>
<p> </p>
<p>(iii) Outline why alloys are generally less malleable than their component metals.</p>
<div class="marks">[4]</div>
<div class="question_part_label">f.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>(i) Draw a labelled diagram of a suitable apparatus for the electrolysis.</p>
<p> </p>
<p>(ii) State equations for the reactions that take place at the electrodes.</p>
<p> </p>
<p>Negative electrode (cathode) reaction:</p>
<p> </p>
<p>Positive electrode (anode) reaction:</p>
<p> </p>
<p>(iii) When dilute aqueous magnesium chloride is used as the electrolyte, the reactions at both electrodes are different. State equations for the reactions that occur in aqueous solution.</p>
<p> </p>
<p>Negative electrode (cathode) reaction:</p>
<p> </p>
<p>Positive electrode (anode) reaction:</p>
<p> </p>
<p>(iv) Outline why magnesium metal is not produced in the electrolysis of aqueous magnesium chloride.</p>
<div class="marks">[7]</div>
<div class="question_part_label">g.</div>
</div>
<h2 style="margin-top: 1em">Markscheme</h2>
<div class="question" style="padding-left: 20px;">
<p><span style="text-decoration: underline;">minimum</span> energy required to remove one electron / energy required to remove most loosely bound/outermost electron;</p>
<p>from gaseous/isolated atom;</p>
<p><em>Accept “gaseous state”.</em></p>
<p><em>More extensive definitions involving one mole may be given.</em></p>
<div class="question_part_label">a.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p>(i) electrons lost in same orbital/valence shell;</p>
<p>(second) electron/electron (being lost from \({\text{M}}{{\text{g}}^ + }\) is) closer to the nucleus;</p>
<p>(second) electron/electron (being lost from \({\text{M}}{{\text{g}}^ + }\)) not subject to e-e repulsion from others in same level;</p>
<p><em>Apply OWTTE for all marking points.</em></p>
<p><em>Do </em><strong><em>not </em></strong><em>accept “less electrons to share the charge” or answers employing this concept.</em></p>
<p>(ii) electron in lower energy level / more stable electron shell;</p>
<p>electron closer to nucleus;</p>
<p>less shielding by complete inner shells / increase in effective nuclear charge;</p>
<p><em>Apply OWTTE for all marking points.</em></p>
<div class="question_part_label">b.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p>\(\Delta {H_{{\text{at}}}}{\text{(Cl)}} = \frac{1}{2} \times 243{\text{ (kJ}}\,{\text{mo}}{{\text{l}}^{ - 1}}{\text{)}}\);</p>
<p><em>Correct calculation of atomization enthalpy of Cl.</em></p>
<p>\(\Delta {H_{\text{f}}} = + 146 + \frac{1}{2}243 + 738 + ( - 349) + ( - 790)\);</p>
<p><em>Correct sign and magnitude of all terms.</em></p>
<p>\( = - {\text{134 (kJ}}\,{\text{mo}}{{\text{l}}^{ - 1}}{\text{)}}\);</p>
<p><em>Award </em><strong><em>[3] </em></strong><em>for correct final answer.</em></p>
<p><em>Final mark involves correct computation of equation the student has produced.</em></p>
<p><em>Award </em><strong><em>[2] </em></strong><em>for –12 (bond enthalpy of Cl not halved) or +134 (signs wrong).</em></p>
<p><em>Award </em><strong><em>[1] </em></strong><em>for +12 (bond enthalpy of Cl not halved and signs wrong).</em></p>
<div class="question_part_label">c.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p>\({\text{Mg}}{{\text{F}}_2}\) –\({\text{MgC}}{{\text{l}}_2}\) –\({\text{CaC}}{{\text{l}}_2}\);</p>
<p>\({{\text{F}}^ - }\) smaller (ionic radius) than \({\text{C}}{{\text{l}}^ - }\) / \({\text{C}}{{\text{l}}^ - }\) larger (ionic radius) than \({{\text{F}}^ - }\);</p>
<p>\({\text{M}}{{\text{g}}^{2 + }}\) smaller (ionic radius) than \({\text{C}}{{\text{a}}^{2 + }}\) / \({\text{C}}{{\text{a}}^{2 + }}\) larger (ionic radius) than \({\text{M}}{{\text{g}}^{2 + }}\);</p>
<p><em>Accept use of atomic radius rather than ionic radius.</em></p>
<div class="question_part_label">d.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p>more soluble at low pH / less soluble at high pH;</p>
<p>higher pH / \({\text{O}}{{\text{H}}^ - }\) will shift the equilibrium to the left / lower pH / \({{\text{H}}^ + }\) will (react with \({\text{O}}{{\text{H}}^ - }\) and) shift the equilibrium to the right;</p>
<div class="question_part_label">e.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p>(i) <span style="text-decoration: underline;">lattice/layers/framework</span> of cations/magnesium ions/\({\text{M}}{{\text{g}}^{2 + }}\);</p>
<p>surrounded by <span style="text-decoration: underline;">delocalized</span> electrons / in a sea/flux of <span style="text-decoration: underline;">delocalized</span> electrons;</p>
<p><em>Accept “mobile” instead of “delocalized”.</em></p>
<p>(ii) Mg has more delocalized electrons (than Na);</p>
<p><em>Accept “Mg has more valence electrons than Na” / “Mg is Mg</em><sup><em>2+ </em></sup><em>but Na is only Na</em><em><sup>+</sup>”</em><em>.</em></p>
<p>(iii) layers of ions/atoms/particles cannot slide over each other so easily (as different sized ions/atoms/particles) / <em>OWTTE</em>;</p>
<div class="question_part_label">f.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p>(i) <img src="images/Schermafbeelding_2016-08-14_om_09.36.50.png" alt="M14/4/CHEMI/HP2/ENG/TZ2/08.g.i/M"></p>
<p><em>Diagram:</em></p>
<p>two electrodes connected to a power pack/battery and immersed in an electrolyte;</p>
<p><em>Do </em><strong><em>not </em></strong><em>award mark if salt bridge included in diagram.</em></p>
<p><em>Labelling:</em></p>
<p>anode/positive electrode, cathode/negative electrode, <span style="text-decoration: underline;">molten</span> magnesium chloride/MgCl<sub>2</sub> (l)/electrolyte correctly labelled;</p>
<p><em>Check candidates know which end of a battery symbol is which charge.</em></p>
<p>(ii) <em>Negative electrode (cathode): </em>\({\text{M}}{{\text{g}}^{2 + }}{\text{(l)}} + {\text{2}}{{\text{e}}^ - } \to {\text{Mg (s)}}\);</p>
<p><em>Positive electrode (anode):</em> \[{\text{2C}}{{\text{l}}^ - }{\text{(l)}} \to {\text{C}}{{\text{l}}_2}{\text{(g)}} + {\text{2}}{{\text{e}}^ - }\];</p>
<p><em>Accept </em>\(C{l^ - }(l) \to \frac{1}{2}C{l_2}(g) + {e^ - }\)<em>.</em></p>
<p><em>Ignore state symbols.</em></p>
<p><em>Allow e instead of e</em><sup><em>–</em></sup><em>.</em></p>
<p><em>If both correct equations are given for the wrong electrodes award </em><strong><em>[1 max]</em></strong><em>.</em></p>
<p>(iii) <em>Negative electrode </em>(<em>cathode):</em></p>
<p>\({\text{2}}{{\text{H}}_2}{\text{O(l)}} + {\text{2}}{{\text{e}}^ - } \to {{\text{H}}_2}{\text{(g)}} + {\text{2O}}{{\text{H}}^ - }{\text{(aq)}}/{\text{2}}{{\text{H}}^ + }{\text{(aq)}} + {\text{2}}{{\text{e}}^ - } \to {{\text{H}}_2}{\text{(g)}}\);</p>
<p><em>Accept </em>\(4{H_2}O(l) + 4{e^ - } \to 2{H_2}(g) + 4O{H^ - }(aq) / 4{H^ + }(aq) + 4{e^ - } \to 2{H_2}(g)\)<em> / </em>\({H_2}O(l) + {e^ - } \to \frac{1}{2}{H_2}(g) + O{H^ - }(aq)/{H^ + }(aq) + {e^ - } \to \frac{1}{2}{H_2}(g)\).</p>
<p><em>Positive electrode (anode):</em></p>
<p>\({\text{2}}{{\text{H}}_2}{\text{O(l)}} \to {{\text{O}}_2}{\text{(g)}} + {\text{4}}{{\text{H}}^ + }{\text{(aq)}} + {\text{4}}{{\text{e}}^ - }/{\text{4O}}{{\text{H}}^ - }{\text{(aq)}} \to {{\text{O}}_2}{\text{(g)}} + {\text{2}}{{\text{H}}_2}{\text{O(l)}} + {\text{4}}{{\text{e}}^ - }\);</p>
<p><em>Accept </em>\({H_2}O(l) \to \frac{1}{2}{O_2}(g) + 2{H^ + }(aq) + 2{e^ - } / 2O{H^ - }(aq) \to \frac{1}{2}{O_2}(g) + {H_2}O(l) + 2{e^ - }\)<em>.</em></p>
<p><em>State symbols not required.</em></p>
<p><em>Allow e instead of e</em><sup><em>–</em></sup><em>.</em></p>
<p><em>If both correct equations are given for the wrong electrodes award </em><strong><em>[1 max]</em></strong><em>.</em></p>
<p>(iv) water/hydrogen ions more easily reduced/better oxidizing agents/have a more positive \({E^\Theta }\) (than magnesium ions);</p>
<p><em>Accept converse statements for magnesium ions.</em></p>
<p><em>Accept “magnesium is very reactive/high in reactivity series” / OWTTE.</em></p>
<div class="question_part_label">g.</div>
</div>
<h2 style="margin-top: 1em">Examiners report</h2>
<div class="question" style="padding-left: 20px;">
<p>This was the most popular of the Section B questions, which was surprising because it was often not well answered. Most students were aware of the change involved in ionization, some realised this relates to the most easily lost electron, some that it refers to gas phase changes and a few both. Explanations of the changes in the values of successive ionization energies in terms of the attraction of the nucleus and the repulsion from other electrons were generally weak, however candidates quite often recognised that the third electron lost had to come from a more stable electron energy level. Very few were able to correctly sum the enthalpy terms involved in the Born-Haber cycle, in addition candidates rarely halved the bond enthalpy of chlorine and a significant number appeared not to realise the question referred to MgCl rather than \({\text{MgC}}{{\text{l}}_2}\). There were some G2 comments that space should have been left for students to draw a cycle, but this would have implied that such a drawing was required, hence it is better to train students to use additional paper for any background support they may require. Quite a lot of students correctly deduced the order of lattice enthalpy of the group (II) halides, and a number correctly explained this in terms of ionic radii, though many incorrectly invoked electronegativities. Many students could correctly explain the effect of pH on the solubility of \({\text{Mg(OH}}{{\text{)}}_{\text{2}}}\), though a significant number attempted to answer the opposite question; how pH would depend on the concentration of dissolved \({\text{Mg(OH}}{{\text{)}}_{\text{2}}}\)! It was surprising how few students could correctly describe metallic bonding, how it is affected by the number of delocalized electrons per cation and the way it leads to malleability. Alloys are not specifically mentioned in the syllabus but the mark scheme gave credit for answers that indicated the student was aware that malleability is associated with layers of metal atoms/cations sliding over each other. Most students were able to draw appropriately labelled diagrams of electrolysis apparatus, though sometimes the labelling of the polarity of the electrodes did not correspond to the polarity of the battery symbol drawn. Quite a few candidates could quote equations for the reactions occurring the electrodes in both the liquid and aqueous state; both seemed to be equally well answered which was perhaps a little surprisingly. Many could also give good explanations as to why electrolysis of the aqueous solution did not produce magnesium metal, though confusions in terminology (such as hydrogen rather than hydrogen ions being reduced) were not uncommon.</p>
<div class="question_part_label">a.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p>This was the most popular of the Section B questions, which was surprising because it was often not well answered. Most students were aware of the change involved in ionization, some realised this relates to the most easily lost electron, some that it refers to gas phase changes and a few both. Explanations of the changes in the values of successive ionization energies in terms of the attraction of the nucleus and the repulsion from other electrons were generally weak, however candidates quite often recognised that the third electron lost had to come from a more stable electron energy level. Very few were able to correctly sum the enthalpy terms involved in the Born-Haber cycle, in addition candidates rarely halved the bond enthalpy of chlorine and a significant number appeared not to realise the question referred to MgCl rather than \({\text{MgC}}{{\text{l}}_2}\). There were some G2 comments that space should have been left for students to draw a cycle, but this would have implied that such a drawing was required, hence it is better to train students to use additional paper for any background support they may require. Quite a lot of students correctly deduced the order of lattice enthalpy of the group (II) halides, and a number correctly explained this in terms of ionic radii, though many incorrectly invoked electronegativities. Many students could correctly explain the effect of pH on the solubility of \({\text{Mg(OH}}{{\text{)}}_{\text{2}}}\), though a significant number attempted to answer the opposite question; how pH would depend on the concentration of dissolved \({\text{Mg(OH}}{{\text{)}}_{\text{2}}}\)! It was surprising how few students could correctly describe metallic bonding, how it is affected by the number of delocalized electrons per cation and the way it leads to malleability. Alloys are not specifically mentioned in the syllabus but the mark scheme gave credit for answers that indicated the student was aware that malleability is associated with layers of metal atoms/cations sliding over each other. Most students were able to draw appropriately labelled diagrams of electrolysis apparatus, though sometimes the labelling of the polarity of the electrodes did not correspond to the polarity of the battery symbol drawn. Quite a few candidates could quote equations for the reactions occurring the electrodes in both the liquid and aqueous state; both seemed to be equally well answered which was perhaps a little surprisingly. Many could also give good explanations as to why electrolysis of the aqueous solution did not produce magnesium metal, though confusions in terminology (such as hydrogen rather than hydrogen ions being reduced) were not uncommon.</p>
<div class="question_part_label">b.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p>This was the most popular of the Section B questions, which was surprising because it was often not well answered. Most students were aware of the change involved in ionization, some realised this relates to the most easily lost electron, some that it refers to gas phase changes and a few both. Explanations of the changes in the values of successive ionization energies in terms of the attraction of the nucleus and the repulsion from other electrons were generally weak, however candidates quite often recognised that the third electron lost had to come from a more stable electron energy level. Very few were able to correctly sum the enthalpy terms involved in the Born-Haber cycle, in addition candidates rarely halved the bond enthalpy of chlorine and a significant number appeared not to realise the question referred to MgCl rather than \({\text{MgC}}{{\text{l}}_2}\). There were some G2 comments that space should have been left for students to draw a cycle, but this would have implied that such a drawing was required, hence it is better to train students to use additional paper for any background support they may require. Quite a lot of students correctly deduced the order of lattice enthalpy of the group (II) halides, and a number correctly explained this in terms of ionic radii, though many incorrectly invoked electronegativities. Many students could correctly explain the effect of pH on the solubility of \({\text{Mg(OH}}{{\text{)}}_{\text{2}}}\), though a significant number attempted to answer the opposite question; how pH would depend on the concentration of dissolved \({\text{Mg(OH}}{{\text{)}}_{\text{2}}}\)! It was surprising how few students could correctly describe metallic bonding, how it is affected by the number of delocalized electrons per cation and the way it leads to malleability. Alloys are not specifically mentioned in the syllabus but the mark scheme gave credit for answers that indicated the student was aware that malleability is associated with layers of metal atoms/cations sliding over each other. Most students were able to draw appropriately labelled diagrams of electrolysis apparatus, though sometimes the labelling of the polarity of the electrodes did not correspond to the polarity of the battery symbol drawn. Quite a few candidates could quote equations for the reactions occurring the electrodes in both the liquid and aqueous state; both seemed to be equally well answered which was perhaps a little surprisingly. Many could also give good explanations as to why electrolysis of the aqueous solution did not produce magnesium metal, though confusions in terminology (such as hydrogen rather than hydrogen ions being reduced) were not uncommon.</p>
<div class="question_part_label">c.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p>This was the most popular of the Section B questions, which was surprising because it was often not well answered. Most students were aware of the change involved in ionization, some realised this relates to the most easily lost electron, some that it refers to gas phase changes and a few both. Explanations of the changes in the values of successive ionization energies in terms of the attraction of the nucleus and the repulsion from other electrons were generally weak, however candidates quite often recognised that the third electron lost had to come from a more stable electron energy level. Very few were able to correctly sum the enthalpy terms involved in the Born-Haber cycle, in addition candidates rarely halved the bond enthalpy of chlorine and a significant number appeared not to realise the question referred to MgCl rather than \({\text{MgC}}{{\text{l}}_2}\). There were some G2 comments that space should have been left for students to draw a cycle, but this would have implied that such a drawing was required, hence it is better to train students to use additional paper for any background support they may require. Quite a lot of students correctly deduced the order of lattice enthalpy of the group (II) halides, and a number correctly explained this in terms of ionic radii, though many incorrectly invoked electronegativities. Many students could correctly explain the effect of pH on the solubility of \({\text{Mg(OH}}{{\text{)}}_{\text{2}}}\), though a significant number attempted to answer the opposite question; how pH would depend on the concentration of dissolved \({\text{Mg(OH}}{{\text{)}}_{\text{2}}}\)! It was surprising how few students could correctly describe metallic bonding, how it is affected by the number of delocalized electrons per cation and the way it leads to malleability. Alloys are not specifically mentioned in the syllabus but the mark scheme gave credit for answers that indicated the student was aware that malleability is associated with layers of metal atoms/cations sliding over each other. Most students were able to draw appropriately labelled diagrams of electrolysis apparatus, though sometimes the labelling of the polarity of the electrodes did not correspond to the polarity of the battery symbol drawn. Quite a few candidates could quote equations for the reactions occurring the electrodes in both the liquid and aqueous state; both seemed to be equally well answered which was perhaps a little surprisingly. Many could also give good explanations as to why electrolysis of the aqueous solution did not produce magnesium metal, though confusions in terminology (such as hydrogen rather than hydrogen ions being reduced) were not uncommon.</p>
<div class="question_part_label">d.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p>This was the most popular of the Section B questions, which was surprising because it was often not well answered. Most students were aware of the change involved in ionization, some realised this relates to the most easily lost electron, some that it refers to gas phase changes and a few both. Explanations of the changes in the values of successive ionization energies in terms of the attraction of the nucleus and the repulsion from other electrons were generally weak, however candidates quite often recognised that the third electron lost had to come from a more stable electron energy level. Very few were able to correctly sum the enthalpy terms involved in the Born-Haber cycle, in addition candidates rarely halved the bond enthalpy of chlorine and a significant number appeared not to realise the question referred to MgCl rather than \({\text{MgC}}{{\text{l}}_2}\). There were some G2 comments that space should have been left for students to draw a cycle, but this would have implied that such a drawing was required, hence it is better to train students to use additional paper for any background support they may require. Quite a lot of students correctly deduced the order of lattice enthalpy of the group (II) halides, and a number correctly explained this in terms of ionic radii, though many incorrectly invoked electronegativities. Many students could correctly explain the effect of pH on the solubility of \({\text{Mg(OH}}{{\text{)}}_{\text{2}}}\), though a significant number attempted to answer the opposite question; how pH would depend on the concentration of dissolved \({\text{Mg(OH}}{{\text{)}}_{\text{2}}}\)! It was surprising how few students could correctly describe metallic bonding, how it is affected by the number of delocalized electrons per cation and the way it leads to malleability. Alloys are not specifically mentioned in the syllabus but the mark scheme gave credit for answers that indicated the student was aware that malleability is associated with layers of metal atoms/cations sliding over each other. Most students were able to draw appropriately labelled diagrams of electrolysis apparatus, though sometimes the labelling of the polarity of the electrodes did not correspond to the polarity of the battery symbol drawn. Quite a few candidates could quote equations for the reactions occurring the electrodes in both the liquid and aqueous state; both seemed to be equally well answered which was perhaps a little surprisingly. Many could also give good explanations as to why electrolysis of the aqueous solution did not produce magnesium metal, though confusions in terminology (such as hydrogen rather than hydrogen ions being reduced) were not uncommon.</p>
<div class="question_part_label">e.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p>This was the most popular of the Section B questions, which was surprising because it was often not well answered. Most students were aware of the change involved in ionization, some realised this relates to the most easily lost electron, some that it refers to gas phase changes and a few both. Explanations of the changes in the values of successive ionization energies in terms of the attraction of the nucleus and the repulsion from other electrons were generally weak, however candidates quite often recognised that the third electron lost had to come from a more stable electron energy level. Very few were able to correctly sum the enthalpy terms involved in the Born-Haber cycle, in addition candidates rarely halved the bond enthalpy of chlorine and a significant number appeared not to realise the question referred to MgCl rather than \({\text{MgC}}{{\text{l}}_2}\). There were some G2 comments that space should have been left for students to draw a cycle, but this would have implied that such a drawing was required, hence it is better to train students to use additional paper for any background support they may require. Quite a lot of students correctly deduced the order of lattice enthalpy of the group (II) halides, and a number correctly explained this in terms of ionic radii, though many incorrectly invoked electronegativities. Many students could correctly explain the effect of pH on the solubility of \({\text{Mg(OH}}{{\text{)}}_{\text{2}}}\), though a significant number attempted to answer the opposite question; how pH would depend on the concentration of dissolved \({\text{Mg(OH}}{{\text{)}}_{\text{2}}}\)! It was surprising how few students could correctly describe metallic bonding, how it is affected by the number of delocalized electrons per cation and the way it leads to malleability. Alloys are not specifically mentioned in the syllabus but the mark scheme gave credit for answers that indicated the student was aware that malleability is associated with layers of metal atoms/cations sliding over each other. Most students were able to draw appropriately labelled diagrams of electrolysis apparatus, though sometimes the labelling of the polarity of the electrodes did not correspond to the polarity of the battery symbol drawn. Quite a few candidates could quote equations for the reactions occurring the electrodes in both the liquid and aqueous state; both seemed to be equally well answered which was perhaps a little surprisingly. Many could also give good explanations as to why electrolysis of the aqueous solution did not produce magnesium metal, though confusions in terminology (such as hydrogen rather than hydrogen ions being reduced) were not uncommon.</p>
<div class="question_part_label">f.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p>This was the most popular of the Section B questions, which was surprising because it was often not well answered. Most students were aware of the change involved in ionization, some realised this relates to the most easily lost electron, some that it refers to gas phase changes and a few both. Explanations of the changes in the values of successive ionization energies in terms of the attraction of the nucleus and the repulsion from other electrons were generally weak, however candidates quite often recognised that the third electron lost had to come from a more stable electron energy level. Very few were able to correctly sum the enthalpy terms involved in the Born-Haber cycle, in addition candidates rarely halved the bond enthalpy of chlorine and a significant number appeared not to realise the question referred to MgCl rather than \({\text{MgC}}{{\text{l}}_2}\). There were some G2 comments that space should have been left for students to draw a cycle, but this would have implied that such a drawing was required, hence it is better to train students to use additional paper for any background support they may require. Quite a lot of students correctly deduced the order of lattice enthalpy of the group (II) halides, and a number correctly explained this in terms of ionic radii, though many incorrectly invoked electronegativities. Many students could correctly explain the effect of pH on the solubility of \({\text{Mg(OH}}{{\text{)}}_{\text{2}}}\), though a significant number attempted to answer the opposite question; how pH would depend on the concentration of dissolved \({\text{Mg(OH}}{{\text{)}}_{\text{2}}}\)! It was surprising how few students could correctly describe metallic bonding, how it is affected by the number of delocalized electrons per cation and the way it leads to malleability. Alloys are not specifically mentioned in the syllabus but the mark scheme gave credit for answers that indicated the student was aware that malleability is associated with layers of metal atoms/cations sliding over each other. Most students were able to draw appropriately labelled diagrams of electrolysis apparatus, though sometimes the labelling of the polarity of the electrodes did not correspond to the polarity of the battery symbol drawn. Quite a few candidates could quote equations for the reactions occurring the electrodes in both the liquid and aqueous state; both seemed to be equally well answered which was perhaps a little surprisingly. Many could also give good explanations as to why electrolysis of the aqueous solution did not produce magnesium metal, though confusions in terminology (such as hydrogen rather than hydrogen ions being reduced) were not uncommon.</p>
<div class="question_part_label">g.</div>
</div>
<br><hr><br><div class="specification">
<p>A sample of magnesium contains three isotopes: magnesium-24, magnesium-25 and magnesium-26, with abundances of 77.44%, 10.00% and 12.56% respectively.</p>
</div>
<div class="specification">
<p>A graph of the successive ionization energies of magnesium is shown below.</p>
<p style="text-align: center;"><img src="images/Schermafbeelding_2016-08-21_om_17.46.25.png" alt="N14/4/CHEMI/HP2/ENG/TZ0/08.b"></p>
</div>
<div class="specification">
<p>The graph below shows pressure and volume data collected for a sample of carbon dioxide gas at 330 K.</p>
<p style="text-align: center;"><img src="images/Schermafbeelding_2016-08-21_om_19.19.59.png" alt="N14/4/CHEMI/HP2/ENG/TZ0/08.e"></p>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>(i) Calculate the relative atomic mass of this sample of magnesium correct to <strong>two</strong> decimal places.</p>
<p> </p>
<p> </p>
<p> </p>
<p> </p>
<p>(ii) Predict the relative atomic radii of the three magnesium isotopes, giving your reasons.</p>
<div class="marks">[4]</div>
<div class="question_part_label">a.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>(i) Explain the increase in ionization energy values from the 3rd to the 8th electrons.</p>
<p> </p>
<p> </p>
<p>(ii) Explain the sharp increase in ionization energy values between the 10th and 11th electrons.</p>
<div class="marks">[3]</div>
<div class="question_part_label">b.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>(i) Magnesium reacts with oxygen to form an ionic compound, magnesium oxide. Describe how the ions are formed, and the structure and bonding in magnesium oxide.</p>
<p> </p>
<p> </p>
<p> </p>
<p> </p>
<p>(ii) Carbon reacts with oxygen to form a covalent compound, carbon dioxide. Describe what is meant by a covalent bond.</p>
<p> </p>
<p> </p>
<p>(iii) State why magnesium and oxygen form an ionic compound while carbon and oxygen form a covalent compound.</p>
<div class="marks">[4]</div>
<div class="question_part_label">c.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>(i) Predict the type of hybridization of the carbon and oxygen atoms in \({\text{C}}{{\text{O}}_{\text{2}}}\).</p>
<p> </p>
<p> </p>
<p>(ii) Sketch the orbitals of an oxygen atom in \({\text{C}}{{\text{O}}_{\text{2}}}\) on the energy level diagram provided, including the electrons that occupy each orbital.</p>
<p style="text-align: center;"><img src="images/Schermafbeelding_2016-08-21_om_19.10.24.png" alt="N14/4/CHEMI/HP2/ENG/TZ0/08.d.ii"></p>
<p>(iii) Define the term electronegativity.</p>
<p> </p>
<p> </p>
<p>(iv) Explain why oxygen has a larger electronegativity than carbon.</p>
<div class="marks">[7]</div>
<div class="question_part_label">d.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>(i) Draw a best-fit curve for the data on the graph.</p>
<p>(ii) Use the data point labelled <strong>X</strong> to determine the amount, in mol, of carbon dioxide gas in the sample.</p>
<div class="marks">[4]</div>
<div class="question_part_label">e.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>(i) Most indicators are weak acids. Describe qualitatively how indicators work.</p>
<p> </p>
<p> </p>
<p> </p>
<p> </p>
<p> </p>
<p> </p>
<p>(ii) Identify a suitable indicator for a titration between a weak acid and a strong base, using Table 16 of the Data Booklet.</p>
<div class="marks">[3]</div>
<div class="question_part_label">f.</div>
</div>
<h2 style="margin-top: 1em">Markscheme</h2>
<div class="question" style="padding-left: 20px;">
<p>(i) \(\left( {\frac{{(77.44 \times 24) + (10.00 \times 25) + (12.56 \times 26)}}{{100}}} \right)\);</p>
<p>24.35;</p>
<p><em>Award </em><strong><em>[2] </em></strong><em>for correct final answer.</em></p>
<p><em>Two decimal places are required for M2.</em></p>
<p><em>Do not award any marks for 24.31 without showing method (as the value can be copied from the Data Booklet).</em></p>
<p>(ii) same atomic radii / 160 pm;</p>
<p>isotopes only differ by number of neutrons/size of nucleus / radius determined by electron shells and number of protons / <em>OWTTE</em>;</p>
<p><em>Accept neutrons do not affect distance of electrons / OWTTE.</em></p>
<div class="question_part_label">a.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p>(i) decreasing repulsion between electrons / radius decreases as electrons are removed;</p>
<p><em>Accept increasing positive charge on ion attracts electrons more strongly.</em></p>
<p>(ii) 10<sup>th</sup> electron is in second energy level/shell while 11<sup>th</sup> electron is in first energy level/shell / 10<sup>th</sup> is removing electron from electronic arrangement 2,1 while 11<sup>th</sup> ionization energy is removing electron from electronic arrangement 2;</p>
<p>11<sup>th</sup> electron removed is much closer to the nucleus / 11<sup>th</sup> electron removed from a (much) lower energy level/shell;</p>
<p><em>Accept opposite statement for 10<sup>th</sup></em> <em>electron.</em></p>
<div class="question_part_label">b.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p>(i) magnesium (atom) gives two electrons to oxygen (atom) / oxygen (atom) takes two electrons from magnesium (atom) / magnesium (atom) loses two electrons <strong>and </strong>oxygen (atom) gains two electrons;</p>
<p>3-dimensional/3-D arrangement of ions / lattice of ions;</p>
<p>(electrostatic) attraction between oppositely charged ions/\({\text{M}}{{\text{g}}^{2 + }}\) and \({{\text{O}}^{2 - }}\);</p>
<p>(ii) electrostatic attraction between a pair of electrons and (positively charged) nuclei;</p>
<p><em>Accept a/two pairs of shared electrons.</em></p>
<p>(iii) difference in <span style="text-decoration: underline;">electronegativity</span> is larger between Mg and O/smaller between C and O;</p>
<p><em>Accept reference to a numerical value of difference in electronegativity such as above and below 1.80.</em></p>
<div class="question_part_label">c.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p>(i) C: sp hybridization;</p>
<p>O: \({\text{s}}{{\text{p}}^{\text{2}}}\) hybridization;</p>
<p><em>Award </em><strong><em>[1] </em></strong><em>if the answer is sp without specifying C or O atoms.</em></p>
<p>(ii) <img src="images/Schermafbeelding_2016-08-21_om_19.15.25.png" alt="N14/4/CHEMI/HP2/ENG/TZ0/08.d.ii/M"></p>
<p>three \({\text{s}}{{\text{p}}^{\text{2}}}\) orbitals <strong>and </strong>one p-orbital at higher energy;</p>
<p>\({\text{s}}{{\text{p}}^{\text{2}}}\) orbitals contain: two, two and one electron <strong>and </strong>p-orbital contains one electron;</p>
<p><em>Do not allow ECF from (d)(i).</em></p>
<p>(iii) ability of atom/nucleus to attract bonding/shared pair of electrons / attraction of nucleus for bonding/shared pair of electrons / <em>OWTTE</em>;</p>
<p>(iv) (same number of shells but) increase in nuclear charge/atomic number/number of protons increases electronegativity / O has more protons than C;</p>
<p><em>Accept oxygen has a higher effective nuclear charge.</em></p>
<p>decrease in radius along the period increases electronegativity / O has smaller radius than C;</p>
<div class="question_part_label">d.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p>(i) smooth curve through the data;</p>
<p><em>Do not accept a curve that passes through </em><strong><em>all </em></strong><em>of the points or an answer that joins the points using lines.</em></p>
<p>(ii) \(p = 21 \times {10^5}/2.1 \times {10^6}{\text{ (Pa)}}/2.1 \times {10^3}{\text{ (kPa)}}\) <strong>and</strong></p>
<p>\(V = 50 \times {10^{ - 6}}/5.0 \times {10^{ - 5}}{\text{ }}({{\text{m}}^3})/5.0 \times {10^{ - 2}}{\text{ }}({\text{d}}{{\text{m}}^3})\);</p>
<p>\(\left( {n = \frac{{pV}}{{RT}}} \right)\frac{{2.1 \times {{10}^6} \times 5.0 \times {{10}^{ - 5}}}}{{8.31 \times 330}}\);</p>
<p>\(n = 0.038{\text{ (mol)}}\);</p>
<p><em>Award </em><strong><em>[3] </em></strong><em>for correct final answer.</em></p>
<p><em>For M3 apply ECF for correct computation of the equation the student has written, unless more than one mistake is made prior this point.</em></p>
<div class="question_part_label">e.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p>(i) equilibrium between HIn and \({\text{I}}{{\text{n}}^ - }/{\text{HIn}} \rightleftharpoons {\text{I}}{{\text{n}}^ - } + {{\text{H}}^ + }\);</p>
<p>the colours of HIn and \({\text{I}}{{\text{n}}^ - }\) are different;</p>
<p>if added to acid, the equilibrium shifts to the left and the colour of HIn is seen / <em>OWTTE</em>;</p>
<p>if added to base/alkali, the equilibrium shifts to the right and the colour of \({\text{I}}{{\text{n}}^ - }\) is seen / <em>OWTTE</em>;</p>
<p>(ii) phenolphthalein;</p>
<p><em>Accept phenol red.</em></p>
<div class="question_part_label">f.</div>
</div>
<h2 style="margin-top: 1em">Examiners report</h2>
<div class="question" style="padding-left: 20px;">
<p>(i) Most candidates were able to calculate the relative atomic mass to the correct number of decimal places.</p>
<p>(ii) Only strong candidates were able to predict the same radius for the isotopes and gave correct reasoning. However, the majority of candidates predicted that a larger number of neutrons resulted is a smaller radius, reflecting a poor understanding of atomic structure.</p>
<div class="question_part_label">a.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p>(i) Very few candidates were able to explain the increase in successive ionization energies for electrons removed from the same sub-shell. Many candidates gave incorrect reasoning. </p>
<p>(ii) The increase between the 10<sup>th</sup> and 11<sup>th</sup> ionization energies of magnesium was explained correctly by about half of the candidates. Few candidates scored the first mark by identifying the correct shells or sub-shells the electrons are removed from. </p>
<div class="question_part_label">b.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p>(i) Well answered by many candidates. A few candidates were confusing ionic with covalent bonding, and some referred to a linear MgO molecule in an ionic lattice.</p>
<p>(ii) Few candidates were able to describe the covalent bond precisely. Those who didn’t score usually didn’t make any reference to pairs of electrons.</p>
<p>(iii) Many candidates obtained this mark with satisfactory arguments. It was disappointing to see the abundance of answers based on “is a metal with a non-metal” or “both are non-metals”.</p>
<div class="question_part_label">c.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p>(i) A few candidates identified sp hybridization based on a linear structure. Only the strongest candidates were able to give the correct hybridization for oxygen as well.</p>
<p>(ii) This was the most challenging question on the paper. It was rare to see a correct answer. It seems candidates did not have a good understanding of hybridization.</p>
<p>(iii) Less than half the candidates were able to define electronegativity precisely. Many candidates did not relate it to the pair of electrons in a covalent bond, and simply talked about attracting electrons, which was not sufficient for the mark.</p>
<p>(iv) Many candidates gained the first mark by stating that oxygen has more protons than carbon. But very few candidates identified the second factor, which is the smaller radius of oxygen.</p>
<div class="question_part_label">d.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p>(i) More than half of the candidates drew a smooth curve that was central to the data points. Errors included straight lines, curves joining all data points, or a curve that was not central to the points.</p>
<p>(ii) A very well answered question. Some candidates converted the units of <em>p </em>and <em>V </em>incorrectly and others did not read the scales of the graph correctly.</p>
<div class="question_part_label">e.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p>(i) Many candidates could explain the behaviour of indicators, but there were also some poor answers that did not acknowledge the importance of equilibrium in the action of an indicator.</p>
<p>(ii) Most candidates suggested a suitable indicator.</p>
<div class="question_part_label">f.</div>
</div>
<br><hr><br><div class="specification">
<p class="p1">Lithium and boron are elements in period 2 of the periodic table. Lithium occurs in group 1 (the alkali metals) and boron occurs in group 3. Isotopes exist for both elements.</p>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">The electron configuration of boron is \({\text{1}}{{\text{s}}^{\text{2}}}{\text{2}}{{\text{s}}^{\text{2}}}{\text{2}}{{\text{p}}^{\text{1}}}\). Draw the shape of an s orbital and a \({{\text{p}}_x}\) orbital on the axes below.</p>
<p class="p1" style="text-align: center;"><img src="images/Schermafbeelding_2016-09-22_om_07.40.13.png" alt="N12/4/CHEMI/HP2/ENG/T2.a.iii/XX"></p>
<div class="marks">[1]</div>
<div class="question_part_label">a.iii.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">(ii) <span class="Apple-converted-space"> </span>Cobalt is a transition metal. One common ion of cobalt is \({\text{C}}{{\text{o}}^{3 + }}\). Draw the orbital diagram (using the arrow-in-box notation) for the \({\text{C}}{{\text{o}}^{3 + }}\) ion.</p>
<p class="p1"><img src="images/Schermafbeelding_2016-09-22_om_07.50.02.png" alt="N12/4/CHEMI/HP2/ENG/TZ0/02.b"></p>
<p class="p1">(iii) <span class="Apple-converted-space"> </span>State the other most common ion of cobalt.</p>
<p class="p1">(iv) <span class="Apple-converted-space"> </span>Explain why the complex \({\text{[Co(N}}{{\text{H}}_{\text{3}}}{{\text{)}}_{\text{6}}}{\text{]C}}{{\text{l}}_{\text{3}}}\) is coloured.</p>
<div class="marks">[5]</div>
<div class="question_part_label">b.</div>
</div>
<h2 style="margin-top: 1em">Markscheme</h2>
<div class="question" style="padding-left: 20px;">
<p class="p1">symmetrical shape of s orbital <strong>and </strong>dumbbell-shaped p orbital with electron density along <em>x</em>-axis;</p>
<p class="p1"><img src="images/Schermafbeelding_2016-09-22_om_07.42.24.png" alt="N12/4/CHEMI/HP2/ENG/TZ0/02.a.iii/M"></p>
<div class="question_part_label">a.iii.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p class="p1">(ii) <span class="Apple-converted-space"> <img src="images/Schermafbeelding_2016-09-22_om_07.56.47.png" alt="N12/4/CHEMI/HP2/ENG/TZ0/02.b/M"></span></p>
<p><em>Allow full arrows instead of half-arrows for example </em>\( \uparrow \downarrow \)<em>.</em></p>
<p><em>Do not allow arrows with the same spin for example </em>\( \uparrow \uparrow \)<em> or </em>\( \downarrow \downarrow \)<em> in the same orbital.</em></p>
<p><em>Do not allow an orbital diagram with a </em><em>\(4{s^1}3{d^5}\) </em><em>configuration.</em></p>
<p>(iii) \({\text{C}}{{\text{o}}^{2 + }}\);</p>
<p><em>Accept +2, 2+, cobalt(II), II.</em></p>
<p>(iv) partially filled/incomplete d subshell/sub-level/orbitals;</p>
<p>d orbitals split (into two sets of different energies);</p>
<p>(colour due to) electron transition between (split) d orbitals / d to d transitions / frequencies of visible light absorbed by electrons moving from lower to higher d levels ;</p>
<p>colour due to remaining frequencies / complementary colour seen;</p>
<p><em>Allow wavelength as well as frequency</em>.</p>
<div class="question_part_label">b.</div>
</div>
<h2 style="margin-top: 1em">Examiners report</h2>
<div class="question" style="padding-left: 20px;">
<p class="p1">In part (iii), a common mistake involved candidates drawing the lobe of electron density around the y or z axes for the \({{\text{p}}_x}\)<span class="s1"> </span>orbital. Some candidates drew three dumbells for the s-orbital. Other candidates incorrectly drew hybrid orbitals.</p>
<div class="question_part_label">a.iii.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p class="p1">The orbital diagram in (ii) also proved to be quite a good discriminating question. Many candidates failed to realise that the electrons are removed from the 4s level before the 3d for a first-row transition metal ion. In addition, a significant number of candidates showed poor understanding of Hund‟s Rule of Maximum Multiplicity which states that when degenerate orbitals are available, electrons fill the orbitals singly before filling them in pairs. Hence, in many cases incorrect representations were seen for the 3d which involved three pairs of electrons of opposite spin being inserted in three 3d orbitals. Most candidates stated the \({\text{C}}{{\text{o}}^{2 + }}\) ion, though a common incorrect answer was \({\text{C}}{{\text{o}}^{4 + }}\). Part (iv) involved candidates having to explain why the complex \({\text{[Co(N}}{{\text{H}}_{\text{3}}}{{\text{)}}_{\text{6}}}{\text{]C}}{{\text{l}}_{\text{3}}}\) is coloured. This question was asked a number of times in previous examinations and previously was typically really very poorly answered. In N12, the explanations certainly were better though some candidates mixed up the principles of the line emission spectrum of hydrogen with the d to d transitions involved in the explanation of colour pertaining to a transition metal complex.</p>
<div class="question_part_label">b.</div>
</div>
<br><hr><br><div class="specification">
<p class="p1">The Born-Haber cycle for MgO under standard conditions is shown below.</p>
<p class="p1" style="text-align: center;"><img src="images/Schermafbeelding_2016-10-02_om_15.47.42.png" alt="N09/4/CHEMI/HP2/ENG/TZ0/07.a_1"></p>
<p class="p1">The values are shown in the table below.</p>
<p class="p1" style="text-align: center;"><img src="images/Schermafbeelding_2016-10-02_om_15.48.28.png" alt="N09/4/CHEMI/HP2/ENG/TZ0/07.a_2"></p>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">Identify the processes represented by <strong>A</strong>, <strong>B </strong>and <strong>D </strong>in the cycle.</p>
<div class="marks">[3]</div>
<div class="question_part_label">a.i.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">Define the enthalpy change, <strong>F</strong>.</p>
<div class="marks">[2]</div>
<div class="question_part_label">a.ii.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">Determine the value of the enthalpy change, <strong>E</strong>.</p>
<div class="marks">[2]</div>
<div class="question_part_label">a.iii.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">Define the enthalpy change <strong>C </strong>for the first value. Explain why the second value is significantly larger than the first.</p>
<div class="marks">[4]</div>
<div class="question_part_label">a.iv.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">The inter-ionic distance between the ions in NaF is very similar to that between the ions in MgO. Suggest with a reason, which compound has the higher lattice enthalpy value.</p>
<div class="marks">[2]</div>
<div class="question_part_label">a.v.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">The standard enthalpy change of three combustion reactions is given below in kJ.</p>
<p class="p1">\[\begin{array}{*{20}{l}} {{\text{2}}{{\text{C}}_{\text{2}}}{{\text{H}}_{\text{6}}}{\text{(g)}} + {\text{7}}{{\text{O}}_{\text{2}}}{\text{(g)}} \to {\text{4C}}{{\text{O}}_{\text{2}}}{\text{(g)}} + {\text{6}}{{\text{H}}_{\text{2}}}{\text{O(l)}}}&{\Delta {H^\Theta } = - 3120} \\ {{\text{2}}{{\text{H}}_2}({\text{g)}} + {{\text{O}}_2}{\text{(g)}} \to {\text{2}}{{\text{H}}_2}{\text{O(l)}}}&{\Delta {H^\Theta } = - {\text{572}}} \\ {{{\text{C}}_2}{{\text{H}}_4}({\text{g)}} + {\text{3}}{{\text{O}}_2}{\text{(g)}} \to {\text{2C}}{{\text{O}}_2}{\text{(g)}} + 2{{\text{H}}_2}{\text{O(l)}}}&{\Delta {H^\Theta } = - {\text{1411}}} \end{array}\]</p>
<p class="p1">Based on the above information, calculate the standard change in enthalpy, \(\Delta {H^\Theta }\), for the following reaction.</p>
<p class="p1">\[{{\text{C}}_2}{{\text{H}}_6}({\text{g)}} \to {{\text{C}}_2}{{\text{H}}_4}({\text{g)}} + {{\text{H}}_2}{\text{(g)}}\]</p>
<div class="marks">[4]</div>
<div class="question_part_label">b.i.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">Predict, stating a reason, whether the sign of \({\Delta {S^\Theta }}\) for the above reaction would be positive or negative.</p>
<div class="marks">[2]</div>
<div class="question_part_label">b.ii.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">Discuss why the above reaction is non-spontaneous at low temperature but becomes spontaneous at high temperatures.</p>
<div class="marks">[2]</div>
<div class="question_part_label">b.iii.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">Using bond enthalpy values, calculate \(\Delta {H^\Theta }\) for the following reaction.</p>
<p class="p1">\[{{\text{C}}_2}{{\text{H}}_6}({\text{g)}} \to {{\text{C}}_2}{{\text{H}}_4}({\text{g)}} + {{\text{H}}_2}{\text{(g)}}\]</p>
<div class="marks">[3]</div>
<div class="question_part_label">b.iv.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">Suggest with a reason, why the values obtained in parts (b) (i) and (b) (iv) are different.</p>
<div class="marks">[1]</div>
<div class="question_part_label">b.v.</div>
</div>
<h2 style="margin-top: 1em">Markscheme</h2>
<div class="question" style="padding-left: 20px;">
<p class="p1"><strong>A: </strong>sublimation/atomization;</p>
<p class="p1"><strong>B: </strong>atomization/half dissociation enthalpy;</p>
<p class="p1"><strong>D: </strong>(sum of 1<sup><span class="s1">st </span></sup>and 2<sup><span class="s1">nd</span></sup>) electron affinity;</p>
<p class="p1"><em>Do not accept vaporization for A and B.</em></p>
<p class="p1"><em>Accept </em>\(\Delta {H_{AT}}\)\( \cdot \)<em> or </em>\(\Delta {H_{EA}}\)<span class="s1"><em>.</em></span></p>
<div class="question_part_label">a.i.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p class="p1">enthalpy change when one mole of the compound is formed from its elements (in their standard states);</p>
<p class="p1">under standard conditions / 25 °C/298 K <strong>and </strong>1 atm/\({\text{101.3 kPa/1.01}} \times {\text{105 Pa}}\);</p>
<div class="question_part_label">a.ii.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p class="p1">\( - 602 = 150 + 248 + 2186 + 702 + E\);</p>
<p class="p1">\( - {\text{3888 (kJ}}\,{\text{mo}}{{\text{l}}^{ - 1}}{\text{)}}\);</p>
<p class="p1"><em>Do not allow 3889 (given in data booklet).</em></p>
<p class="p1"><em>Allow 3888 (i.e no minus sign).</em></p>
<p class="p1"><em>Award </em><strong><em>[2] </em></strong><em>for the correct final answer.</em></p>
<div class="question_part_label">a.iii.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p class="p1">energy required to remove one electron;</p>
<p class="p1">from an atom in its <span style="text-decoration: underline;">gaseous</span> state;</p>
<p class="p1">electron removed from a positive ion;</p>
<p class="p1">decrease in electron-electron repulsion / increase in nucleus-electron attraction;</p>
<div class="question_part_label">a.iv.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p class="p1">MgO;</p>
<p class="p1">double ionic charge / both ions carry +2 and –2 charge/greater charge compared to +1 and –1;</p>
<div class="question_part_label">a.v.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p>\[\begin{array}{*{20}{l}} {\left( {{{\text{C}}_2}{{\text{H}}_6}{\text{(g)}} + {\text{3}}\frac{1}{2}{{\text{O}}_2}{\text{(g)}} \to {\text{2C}}{{\text{O}}_2}{\text{(g)}} + {\text{3}}{{\text{H}}_2}{\text{O(l)}}} \right)}&{\Delta {H^\Theta } = - {\text{1560;}}} \\ {\left( {{{\text{H}}_2}{\text{O(l)}} \to {{\text{H}}_2}{\text{(g)}} + \frac{1}{2}{{\text{O}}_2}{\text{(g)}}} \right)}&{\Delta {H^\Theta } = + {\text{286;}}} \\ {\left( {{\text{2C}}{{\text{O}}_2}{\text{(g)}} + {\text{2}}{{\text{H}}_2}{\text{O(l)}} \to {{\text{C}}_2}{{\text{H}}_4}{\text{(g)}} + {\text{3}}{{\text{O}}_2}{\text{(g)}}} \right)}&{\Delta {H^\Theta } = + {\text{1411;}}} \\ {\left( {{{\text{C}}_2}{{\text{H}}_6}{\text{(g)}} \to {{\text{C}}_2}{{\text{H}}_4}{\text{(g)}} + {{\text{H}}_2}{\text{(g)}}} \right)}&{\Delta {H^\Theta } = + {\text{137 (kJ);}}} \end{array}\]</p>
<p class="p1"><em>Allow other correct methods.</em></p>
<p class="p1"><em>Award </em><strong><em>[2] </em></strong><em>for –137.</em></p>
<p class="p1"><em>Allow ECF for the final marking point.</em></p>
<div class="question_part_label">b.i.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p class="p1">positive;</p>
<p class="p1">increase in number of moles of <span style="text-decoration: underline;">gas</span>;</p>
<div class="question_part_label">b.ii.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p class="p1">at low temperature, \({\Delta {H^\Theta }}\) is positive <strong>and</strong> \({\Delta G}\) is positive;</p>
<p class="p1">at high temperature, factor \({\text{T}}\Delta {S^\Theta }\) predominates <strong>and </strong>\({\Delta G}\) is negative;</p>
<div class="question_part_label">b.iii.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p class="p1">Bonds broken (1C–C, 6C–H, or 1C–C, 2C–H) = 2825/1173;</p>
<p class="p1">Bonds made (1C=C, 1H–H, 4C–H) = 2700/1048;</p>
<p class="p1">+125 (kJ);</p>
<p class="p2"><em>Allow 125 but not –125 (kJ ) for the final mark.</em></p>
<p class="p2"><em>Award </em><span class="s1"><strong><em>[3] </em></strong></span><em>for the correct final answer.</em></p>
<div class="question_part_label">b.iv.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p class="p1">bond enthalpy values are average values;</p>
<div class="question_part_label">b.v.</div>
</div>
<h2 style="margin-top: 1em">Examiners report</h2>
<div class="question" style="padding-left: 20px;">
<p class="p1">This was the second most popular question and in general candidates demonstrated a good understanding of the Born Haber cycle. Some candidates identified the process A as vaporization instead of atomization.</p>
<div class="question_part_label">a.i.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p class="p1">Most candidates correctly stated the definition of enthalpy change of formation although some omitted to specify the standard conditions.</p>
<div class="question_part_label">a.ii.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p class="p1">The majority of candidates correctly calculated the lattice enthalpy value.</p>
<div class="question_part_label">a.iii.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p class="p1">The definition of the first ionization energy was stated correctly by most candidates but in a few cases the term gaseous state was missing.</p>
<div class="question_part_label">a.iv.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p class="p1">The compound with higher lattice enthalpy was correctly identified including the reason.</p>
<div class="question_part_label">a.v.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p class="p1">The majority of candidates manipulated the thermo-chemical equations and calculated the correct answer of +137 kJ although some reversed the sign.</p>
<div class="question_part_label">b.i.</div>
</div>
<div class="question" style="padding-left: 20px;">
[N/A]
<div class="question_part_label">b.ii.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p class="p1">The explanation for why the reaction was non-spontaneous at low temperature but became spontaneous at high temperature was not always precise and deprived many candidates of at least one mark.</p>
<div class="question_part_label">b.iii.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p class="p1">The bond enthalpy calculation had the usual mistakes of using the wrong value from the data booklet, bond making minus bond breaking and –125 kJ instead of +125 kJ.</p>
<div class="question_part_label">b.iv.</div>
</div>
<div class="question" style="padding-left: 20px;">
[N/A]
<div class="question_part_label">b.v.</div>
</div>
<br><hr><br><div class="question">
<p class="p1"><img src="images/Schermafbeelding_2016-10-11_om_05.35.39.png" alt="M10/4/CHEMI/HP2/ENG/TZ2/02.b"></p>
<p class="p1">On the above diagram, draw the line that corresponds to the first ionization energy of hydrogen and explain your reasoning.</p>
</div>
<h2 style="margin-top: 1em">Markscheme</h2>
<div class="question">
<p class="p1">for showing the energy to remove electron from \({\text{n}} = 1\) to \({\text{n}} = \infty \) on the above diagram;</p>
<p class="p1">to ionize an element, electron must be removed from the atom/no longer under influence of nucleus/removed beyond \({\text{n}} = \infty \) / <em>OWTTE</em>;</p>
</div>
<h2 style="margin-top: 1em">Examiners report</h2>
<div class="question">
<p class="p1">Candidates in some schools, however, appeared not to have encountered these ideas at all. Common errors were to label the first energy level as\({\text{n}} = 0\) rather than\({\text{n}} = 1\) and to only include one transition for each series. Sometimes the arrows showing the transitions were shown from the bottom up.</p>
<p class="p1">While more candidates managed to obtain at least a mark with regard to the first ionization energy of hydrogen, it was less common to find the correct graphical representation of the first IE with diagrams which often were unrelated.</p>
</div>
<br><hr><br><div class="specification">
<p>Hydrogen peroxide decomposes according to the equation below.</p>
<p>\({\text{2}}{{\text{H}}_{\text{2}}}{{\text{O}}_{\text{2}}}{\text{(aq)}} \to {\text{2}}{{\text{H}}_{\text{2}}}{\text{O(l)}} + {{\text{O}}_{\text{2}}}{\text{(g)}}\)</p>
<p>The rate of the decomposition can be monitored by measuring the volume of oxygen gas released. The graph shows the results obtained when a solution of hydrogen peroxide decomposed in the presence of a CuO catalyst.</p>
<p style="text-align: center;"><img src="images/Schermafbeelding_2016-08-22_om_06.42.58.png" alt="N14/4/CHEMI/HP2/ENG/TZ0/11"></p>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Outline how the initial rate of reaction can be found from the graph.</p>
<div class="marks">[2]</div>
<div class="question_part_label">a.i.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Explain how and why the rate of reaction changes with time.</p>
<div class="marks">[3]</div>
<div class="question_part_label">a.ii.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>A Maxwell-Boltzmann energy distribution curve is drawn below. Label both axes and explain, by annotating the graph, how catalysts increase the rate of reaction.</p>
<p style="text-align: center;"><img src="images/Schermafbeelding_2016-08-22_om_06.52.11.png" alt="N14/4/CHEMI/HP2/ENG/TZ0/11.b"></p>
<div class="marks">[3]</div>
<div class="question_part_label">b.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>(i) In some reactions, increasing the concentration of a reactant does not increase the rate of reaction. Describe how this may occur.</p>
<p> </p>
<p> </p>
<p> </p>
<p>(ii) Consider the reaction</p>
<p>\[{\text{2A}} + {\text{B}} \to {\text{C}} + {\text{D}}\]</p>
<p>The reaction is first order with respect to <strong>A</strong>, and zero order with respect to <strong>B</strong>. Deduce the rate expression for this reaction.</p>
<div class="marks">[2]</div>
<div class="question_part_label">c.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Sketch a graph of rate constant \((k)\) versus temperature.</p>
<p style="text-align: center;"><img src="images/Schermafbeelding_2016-08-22_om_07.07.50.png" alt="N14/4/CHEMI/HP2/ENG/TZ0/11.d"></p>
<div class="marks">[1]</div>
<div class="question_part_label">d.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Hydrochloric acid neutralizes sodium hydroxide, forming sodium chloride and water.</p>
<p>\({\text{NaOH(aq)}} + {\text{HCl(aq)}} \to {\text{NaCl(aq)}} + {{\text{H}}_{\text{2}}}{\text{O(l)}}\) \(\Delta {H^\Theta } = - 57.9{\text{ kJ}}\,{\text{mo}}{{\text{l}}^{ - 1}}\)</p>
<p>(i) Define <em>standard enthalpy change of reaction</em>, \(\Delta {H^\Theta }\).</p>
<p>(ii) Determine the amount of energy released, in kJ, when \({\text{50.0 c}}{{\text{m}}^{\text{3}}}\) of \({\text{1.00 mol}}\,{\text{d}}{{\text{m}}^{ - 3}}\) sodium hydroxide solution reacts with \({\text{50.0 c}}{{\text{m}}^{\text{3}}}\) of \({\text{1.00 mol}}\,{\text{d}}{{\text{m}}^{ - 3}}\) hydrochloric acid solution.</p>
<p>(iii) In an experiment, 2.50 g of solid sodium hydroxide was dissolved in \({\text{50.0 c}}{{\text{m}}^{\text{3}}}\) of water. The temperature rose by 13.3 °C. Calculate the standard enthalpy change, in \({\text{kJ}}\,{\text{mo}}{{\text{l}}^{ - 1}}\), for dissolving one mole of solid sodium hydroxide in water.</p>
<p>\[{\text{NaOH(s)}} \to {\text{NaOH(aq)}}\]</p>
<p>(iv) Using relevant data from previous question parts, determine \(\Delta {H^\Theta }\), in \({\text{kJ}}\,{\text{mo}}{{\text{l}}^{ - 1}}\), for the reaction of solid sodium hydroxide with hydrochloric acid.</p>
<p>\[{\text{NaOH(s)}} + {\text{HCl(aq)}} \to {\text{NaCl(aq)}} + {{\text{H}}_{\text{2}}}{\text{O(l)}}\]</p>
<div class="marks">[9]</div>
<div class="question_part_label">e.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>(i) Zinc is found in the d-block of the periodic table. Explain why it is not considered a transition metal.</p>
<p> </p>
<p> </p>
<p> </p>
<p> </p>
<p>(ii) Explain why \({\text{F}}{{\text{e}}^{3 + }}\) is a more stable ion than \({\text{F}}{{\text{e}}^{2 + }}\) by reference to their electron configurations.</p>
<div class="marks">[5]</div>
<div class="question_part_label">f.</div>
</div>
<h2 style="margin-top: 1em">Markscheme</h2>
<div class="question" style="padding-left: 20px;">
<p>(draw a) tangent to the curve at origin/time = 0/start of reaction;</p>
<p>(calculate) the gradient/slope (of the tangent);</p>
<div class="question_part_label">a.i.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p>rate decreases (with time);</p>
<p>concentration/number of (reactant) molecules per unit volume decreases (with time);</p>
<p><em>Do not accept “number of molecules decreases” or “amount of reactant </em><em>decreases”.</em></p>
<p>collisions (between reactant molecules/reactant and catalyst) become less frequent;</p>
<p><em>Do not accept “fewer collisions” without reference to frequency (eg, no. </em><em>collisions per second).</em></p>
<div class="question_part_label">a.ii.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p><em>y</em>-<em>axis</em>: probability / fraction of molecules/particles / probability density</p>
<p><em>Allow “number of particles/molecules” on y-axis.</em></p>
<p><strong>and</strong></p>
<p><em>x</em>-<em>axis</em>: (kinetic) energy;</p>
<p><em>Accept “speed/velocity” on x-axis.</em></p>
<p><img src="images/Schermafbeelding_2016-08-22_om_06.55.55.png" alt="N14/4/CHEMI/HP2/ENG/TZ0/11.b/M"></p>
<p>correct relative position of \({E_{\text{a}}}\) catalysed and \({E_{\text{a}}}\) uncatalysed;</p>
<p>more/greater proportion of molecules/collisions have the lower/required/catalysed \({E_{\text{a}}}\) (and can react upon collision);</p>
<p><em>M3 can be scored by stating </em><strong><em>or </em></strong><em>shading and annotating the graph.</em></p>
<p><em>Accept “a greater number/proportion of successful collisions as catalyst reduces </em>\({E_a}\)<em>”.</em></p>
<div class="question_part_label">b.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p>(i) reactant not involved in (or before) the slowest/rate-determining step/RDS;</p>
<p>reactant is in (large) excess;</p>
<p>(ii) \({\text{(rate}} = {\text{) }}k{\text{[A]}}\);</p>
<p><em>Accept rate =</em> <em>k[A]<sup>1</sup>[B]<sup>0</sup></em><em>.</em></p>
<div class="question_part_label">c.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p>curve with a positive slope curving upwards;</p>
<p><em>Do not penalize if curve passes through the origin.</em></p>
<p><img src="images/Schermafbeelding_2016-08-22_om_07.10.15.png" alt="N14/4/CHEMI/HP2/ENG/TZ0/11.d/M"></p>
<div class="question_part_label">d.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p>(i) heat transferred/absorbed/released/enthalpy/<span style="text-decoration: underline;">potential</span> energy change when 1 mol/molar amounts of reactant(s) react (to form products) <em>/ OWTTE</em>;</p>
<p>under standard conditions / at a pressure 100 kPa/101.3 kPa/1 atm <strong>and</strong> temperature 298 K/25 °C;</p>
<p><em>Award </em><strong><em>[2] </em></strong><em>for difference between standard enthalpies of products and standard enthalpies of reactants / </em>\({H^\Theta }\) <em>(products) – </em>\({H^\Theta }\) <em>(reactants).</em></p>
<p><em>Award </em><strong><em>[2] </em></strong><em>for difference between standard enthalpies of formation of products and standard enthalpies of formation of reactants / </em>\(\Sigma \Delta H_f^\Theta \)<em> (products) – </em>\(\Sigma \Delta H_f^\Theta \) <em>(reactants).</em></p>
<p>(ii) \((1.00 \times 0.0500 = ){\text{ }}0.0500{\text{ (mol)}}\);</p>
<p>\((0.0500 \times 57.9 = ){\text{ }}2.90{\text{ (kJ)}}\);</p>
<p><em>Ignore any negative sign.</em></p>
<p><em>Award </em><strong><em>[2] </em></strong><em>for correct final answer.</em></p>
<p><em>Award </em><strong><em>[1 max] </em></strong><em>for 2900 J.</em></p>
<p>(iii) \(\left( {\frac{{2.50}}{{40.00}} = } \right){\text{ }}0.0625{\text{ (mol NaOH)}}\);</p>
<p>\(0.0500 \times 4.18 \times 13.3 = 2.78{\text{ (kJ)}}/50.0 \times 4.18 \times 13.3 = 2780{\text{ (J)}}\);</p>
<p>\(\left( {\frac{{2.78}}{{0.0625}}} \right) = - 44.5{\text{ (kJ}}\,{\text{mo}}{{\text{l}}^{ - 1}})\);</p>
<p><em>Award </em><strong><em>[3] </em></strong><em>for correct final answer.</em></p>
<p><em>Negative sign is necessary for M3.</em></p>
<p><em>Award M2 and M3 if is used to obtain an enthalpy change of –46.7 (kJ mol<sup>–1</sup>).</em></p>
<p>(iv) \( - 44.5 - 57.9\) / correct Hess’s Law cycle (as below) / correct manipulation of equations;</p>
<p><img src="images/Schermafbeelding_2016-08-22_om_07.41.59.png" alt="N14/4/CHEMI/HP2/ENG/TZ0/1.e.iv/M"></p>
<p>\( - 102.4{\text{ kJ}}\);</p>
<p><em>Award </em><strong><em>[2] </em></strong><em>for correct final answer.</em></p>
<div class="question_part_label">e.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p>(i) zinc (only) forms the ion \({\text{Z}}{{\text{n}}^{2 + }}\) / has the oxidation state \( + 2\);</p>
<p><em>Allow forms only one ion / has only one oxidation state.</em></p>
<p>has full d-subshell/orbitals / does not have a partially filled d-subshell/orbitals (needed to exhibit transition metal properties);</p>
<p>(ii) \({\text{F}}{{\text{e}}^{2 + }}{\text{: 1}}{{\text{s}}^{\text{2}}}{\text{2}}{{\text{s}}^{\text{2}}}{\text{2}}{{\text{p}}^{\text{6}}}{\text{3}}{{\text{s}}^{\text{2}}}{\text{3}}{{\text{p}}^{\text{6}}}{\text{3}}{{\text{d}}^{\text{6}}}/{\text{[Ar] 3}}{{\text{d}}^{\text{6}}}\) <strong>and</strong> \({\text{F}}{{\text{e}}^{3 + }}{\text{: 1}}{{\text{s}}^{\text{2}}}{\text{2}}{{\text{s}}^{\text{2}}}{\text{2}}{{\text{p}}^{\text{6}}}{\text{3}}{{\text{s}}^{\text{2}}}{\text{3}}{{\text{p}}^{\text{6}}}{\text{3}}{{\text{d}}^{\text{5}}}/{\text{[Ar] 3}}{{\text{d}}^{\text{5}}}\);</p>
<p>half-full sub-level/3d<sup>5</sup> has extra stability;</p>
<p>less repulsion between electrons / electrons singly occupy orbitals / electrons do not have to pair with other electrons;</p>
<p><em>Accept converse points for Fe</em><sup><em>2+</em></sup><em>.</em></p>
<div class="question_part_label">f.</div>
</div>
<h2 style="margin-top: 1em">Examiners report</h2>
<div class="question" style="padding-left: 20px;">
<p>Most candidates related the rate of reaction to the gradient of the curve, but only a few suggested drawing a tangent at \(t = 0\).</p>
<div class="question_part_label">a.i.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p>Answers were often disappointing and only a few candidates gained full marks.</p>
<p>Candidates often talked about the number of reactant molecules decreasing but neglected to relate this to a lower concentration. Also some candidates still fail to highlight frequency rather than the number of collisions.</p>
<div class="question_part_label">a.ii.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p>Well answered by more than half of the candidates. The labelling of the axes was a challenge for some candidates. The annotation of the diagram with the energy of activation with and without a catalyst was mostly correct, though some weaker students confused it with the effect of temperature and constructed a second curve. Some candidates could not offer an explanation for the third mark.</p>
<div class="question_part_label">b.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p>(i) Only a few candidates scored this mark. Many candidates stated that a reactant concentration having no effect indicated that the reaction that was zero order in that species, rather than describing the underlying mechanistic reason for the zero order dependence.</p>
<p>(ii) More than half of the candidates could construct a correct rate expression from information about the order of the reactants.</p>
<div class="question_part_label">c.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p>A number of candidates gave a linear relationship, rather than an exponential one, between reaction rate and temperature.</p>
<div class="question_part_label">d.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p>(i) Defining the standard enthalpy change of reaction was not well answered.</p>
<p>(ii) More than half of the candidates calculated the amount of energy released correctly.</p>
<p>(iii) Half of the candidates were able to gain the three marks. Many candidates lost the third mark for not quoting the negative sign for the enthalpy change. Quite a few candidates used a wrong value for the mass of water.</p>
<p>(iv) Many good answers. A Hess’s Law cycle wasn’t often seen. Quite a few candidates scored through ECF from (iii).</p>
<div class="question_part_label">e.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p>(i) Most candidates knew that zinc has a full 3d sub-shell but almost all missed out on the second mark about only having one possible oxidation state in its compounds.</p>
<p>(ii) This was a challenging question for many candidates. A large number of candidates did not give the correct electron configurations for the ions, and only few mentioned the stability of the half-full d-sub-shell. Very few scored the third mark.</p>
<div class="question_part_label">f.</div>
</div>
<br><hr><br><div class="specification">
<p>Calcium carbide, CaC<sub>2</sub>, is an ionic solid.</p>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Describe the nature of ionic bonding.</p>
<div class="marks">[1]</div>
<div class="question_part_label">a.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Describe how the relative atomic mass of a sample of calcium could be determined from its mass spectrum.</p>
<div class="marks">[2]</div>
<div class="question_part_label">b.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>When calcium compounds are introduced into a gas flame a red colour is seen; sodium compounds give a yellow flame. Outline the source of the colours and why they are different.</p>
<div class="marks">[2]</div>
<div class="question_part_label">c.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Suggest <strong>two </strong>reasons why solid calcium has a greater density than solid potassium.</p>
<div class="marks">[2]</div>
<div class="question_part_label">d.i.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Outline why solid calcium is a good conductor of electricity.</p>
<div class="marks">[1]</div>
<div class="question_part_label">d.ii.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Sketch a graph of the first six ionization energies of calcium.</p>
<p><img src="data:image/png;base64,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"></p>
<div class="marks">[2]</div>
<div class="question_part_label">e.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Calcium carbide reacts with water to form ethyne and calcium hydroxide.</p>
<p style="text-align: center;">CaC<sub>2</sub>(s) + H<sub>2</sub>O(l) → C<sub>2</sub>H<sub>2</sub>(g) + Ca(OH)<sub>2</sub>(aq)</p>
<p>Estimate the pH of the resultant solution.</p>
<div class="marks">[1]</div>
<div class="question_part_label">f.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Describe how sigma (σ) and pi (\(\pi \)) bonds are formed.</p>
<p><img src="data:image/png;base64,iVBORw0KGgoAAAANSUhEUgAAAxUAAAEGCAYAAAATwLgWAAAfeklEQVR4Ae3dDZCddX0v8C9bymCMmVAsRhBnd7IhYwLIjXIVwkBssZWWuuQ6xvJiebmI1+EihBHpS2JArpYXNRGbci0tbEZqFQUSEamivQsXhbmQFeSlE3dxt3ATghdr7nabyVDv2TtnswkhZP/PJmS7Z89+diazm/09z//5/z+/Z0+eb55zzh4wNDQ0FB8ECBAgQIAAAQIECBDYR4GWfdzPbgQIECBAgAABAgQIEBgWECqcCAQIECBAgAABAgQIvCaBA+t7t7e2vaZB7EyAAAECBAgQIECAQPML9Pb37XGRB+x4TUU9WIy20R739E0CBAgQIECAAAECBKaEQFVW8PSnKXEaWCQBAgQIECBAgACB8RMQKsbP1sgECBAgQIAAAQIEpoSAUDEl2myRBAgQIECAAAECBMZPQKgYP1sjEyBAgAABAgQIEJgSAkLFlGizRRIgQIAAAQIECBAYPwGhYvxsjUyAAAECBAgQIEBgSggIFVOizRZJgAABAgQIECBAYPwEhIrxszUyAQIECBAgQIAAgSkhIFRMiTZbJAECBAgQIECAAIHxExAqxs/WyAQIECBAgAABAgSmhIBQMSXabJEECBAgQIAAAQIExk9AqBg/WyMTIECAAAECBAgQmBICQsWUaLNFEiBAgAABAgQIEBg/AaFi/GyNTIAAAQIECBAgQGBKCAgVU6LNFkmAAAECBAgQIEBg/ASEivGzNTIBAgQIECBAgACBKSEgVEyJNlskAQIECBAgQIAAgfETECrGz9bIBAgQIECAAAECBKaEgFAxJdpskQQIECBAgAABAgTGT0CoGD9bIxMgQIAAAQIECBCYEgJCxZRos0USIECAAAECBAgQGD+BJg4V29LTeU7a561I10Bt/AT328hb0r3yiqzq3rIXI9YyuOEbWXXjfekZnAxr3Iul2ZQAAQIECBAgQGDSCDRxqDg4c867Lb1PX51FMxp9mbUMdK3MRT9dmCXHzdyLk6cl0+d+MB9f0pKvXfu1bBAs9sLOpgQIECBAgAABAvtLoNGvtvfXOht7nMH1ueW6Z3PJ5e/L4fvQkZZZ78mlp27I2Vd8K5vcsGjsXpsdAQIECBAgQKAJBfbhErZRFGoZ7OnKmmUdaW9t2/7ntGVZ09WTweEp7unpTwPp+cGXctG87dsfe+HK3NW5LL/fekqWd72YpH7HYEWObT0zq9auzaoLTxgZuyPLv/JINg/05B9WfiTHDh/vhFx040PZvMtFfG1zd9btrNeP0ZHlnV0VT016KZu+/9XcctApOXH2wfuI25IZJ5+VSzatzk0P1NdRX8qGrOmYn/aOzvTsMsd9PIDdCBAgQIAAAQIECIwqMHlDxeD6/PXHV+SH7Z/NY/196e3fkAevfF1uP+/q3NGzbQ8Lfimb1q7IBy55Ogvvejy9/c/kR1f8Zu69/m+z4VVbP5y/+PKP03bld7eP2/kf0718SU569/V56qRr8lj/M3nsuxcn//3yfPpbz2b4mn3wkdx4/tLc82sX5Hs/q8+nLz99+OP5ta9fnstuXj8SdF51oKTWl/tuvT+zF5+Q2bt2o7Y53WtX7gxAO4PTjgDVuiAXrf3fLw/YckSOWfTr+buV394eIlrm5tx1T6V33XmZs+u4L+/hKwIECBAgQIAAAQL7RWDSXm7Wnn8q9//jkVm4cHamD1MclFmL/iz39N+Wc+fs4X/8B36Um/704Zz02T/Jh+fOSFJ/PcJZ+dxf/lGmvYryrTnzykvSMae+3UGZtWBhFkyblmM++YlcfPystNT3nXN8Fs4ZyIOP/iyD9Tscj347t/zTopx13rsya0S1ZdbCnP2hednQ9VSeH+1uweDz6e15Q45uPTQvN2NLur94cZb86dOZ96XvjYSmx3PPVRfknFV/P/L37vzVGW/ZZeYH5/C29uTx7jz981/t8n1fEiBAgAABAgQIEBhfgZevY8f3OPt99JY3z88pb/txPr/mO3m06zvp6hkoHKOWge7/kXVbZ+dd8w/b5eK9JdOPaMvswp5jK7VkxqKr85OnV+SdLzyYdWvXZt3aO7Nm2Ydy2lU/LA5Re6E/T249Mu1HbI9G9Y1rPWtzzRdfzJl/+ee57LfnjISmGZn7R+fmP3x3aS7vfGoPdz5aMm3mIZmW3vRt2tOdmuI0FAkQIECAAAECBAjss8CkDRWZfnwu+8ba3PjOLVl33RW58L1vH+NrGMZi9cqL/LHskcGnsubChTnuvR/LXz36z8N3Qmaeek1uv2ph0tOXjXt8Z6ZaBjf25ZlXHGDH916fQ2fsdsel5S15z4eOz8PX355HX/U2uS2ZNmNmDnrFWP5CgAABAgQIECBAYPwFJm+oqNtMn5NFZ1yQa+59Kr0/eyi3r1qUF64/Px+49oGU7lvsf9Zt6fnmn+eaH707n//Rj3PPf7sgHWeckY5Fh2eg97nC4fZ0p2RHOPjX/GJg9zsOI7Wtj+Sx3q27jVvL1oEteWm37/orAQIECBAgQIAAgfEWmNyhYledlllZcMaHc9Z/emu2PtGfF17xGoaWzFjwnnRMey69G7e/N9T2XXfcFdh1oH35ejAb6+Fhztszb9Yu9wpqW/N/f1G+zG95U2uO3m1eBx51Us5524tZ9/UHd3uL2G3p+8n6bMlv5JA3HLjbRGvZuuWX2Zr2tB2+2x2O3bb0VwIECBAgQIAAAQL7U2DShopaT2cW19+yde2GkdcX1N9i9sH8YH3yO+f/1ivfSakuNuPEfOyzC7Luui9l3fDrL+rbfys3XPfN7P5//nsP/BtZcOqiTHv8rvztA5u2vxtUbXMe/YtrsvzezeXhpr857XP+JU/2/2L7fvWtp78jF37mv+TIe/8sH/nU2pG3pH0pmx/pzA3X/zhzzz0/v/uqt5/dlk19vcnbF2TeYbsHjvIUVAkQIECAAAECBAi8FoFJGypa5pyVm+48P4d++7wcN/w2q7NzXMc9OfSjK/Op9791lxdj7+A5KIefcXXu+MQbc09H/fUXs3Pidc/l5I+en2N2bLLPn+u/J+Jj6bzmmDxy3sIcVZ/P0cvz4FvOzi2rzt7Du0vtcqCWOVm89A/yzF0P5Zmdd1daMn3Bxfn6fauzJLfmtKNnp711bk46d33mffYr+ZsVv73zHaZ2jlTbmCe6/i1nLj19+1vI+j0VO2l8QYAAAQIECBAgML4CBwwNDQ3VD1H/PQj1360w1T7qdzw+0NGXSx9ekUUzJihjDT6SVR/8QvKZm3LZgpn70IJaBrtX58M3H5nVq8/Yp9/KvQ8HtQsBAgQIECBAgMAUEajKChN0FT0B+gNdWT7vhFy0y9ux1jY/lNXX3ZqXPnJ63jlRgaJOMf0dueDKo3LbzV27vYZijE6D63PrnYfm2hveL1CMkcxmBAgQIECAAAEC+09g6oSKGSfm4tuuzLwHLxx5ulRbjvqtW/L/Tl+Zv7n0+JHfBbH/YPdupPrTpz6azx12f25/bMte7Fp/XcjdWXXz5rzvj/8wc6dPnXbuBZJNCRAgQIAAAQIExllgyj/9aZx9DU+AAAECBAgQIEBg0gt4+tOkb6EFECBAgAABAgQIEGhsAc+Xaez+mB0BAgQIECBAgACBhhcQKhq+RSZIgAABAgQIECBAoLEFhIrG7o/ZESBAgAABAgQIEGh4AaGi4VtkggQIECBAgAABAgQaW0CoaOz+mB0BAgQIECBAgACBhhcQKhq+RSZIgAABAgQIECBAoLEFhIrG7o/ZESBAgAABAgQIEGh4AaGi4VtkggQIECBAgAABAgQaW0CoaOz+mB0BAgQIECBAgACBhhcQKhq+RSZIgAABAgQIECBAoLEFhIrG7o/ZESBAgAABAgQIEGh4AaGi4VtkggQIECBAgAABAgQaW0CoaOz+mB0BAgQIECBAgACBhhcQKhq+RSZIgAABAgQIECBAoLEFhIrG7o/ZESBAgAABAgQIEGh4AaGi4VtkggQIECBAgAABAgQaW0CoaOz+mB0BAgQIECBAgACBhhcQKhq+RSZIgAABAgQIECBAoLEFhIrG7o/ZESBAgAABAgQIEGh4AaGi4VtkggQIECBAgAABAgQaW0CoaOz+mB0BAgQIECBAgACBhhcQKhq+RSZIgAABAgQIECBAoLEFhIrG7o/ZESBAgAABAgQIEGh4AaGi4VtkggQIECBAgAABAgQaW0CoaOz+mB0BAgQIECBAgACBhhdomlBR6+nM4ta2HLusKwOjsdc2ZE3H/LTPW5GugdooW21LT+c5aW89Jcu7Xhxlm6TZjxdWSZwL9R+AZj/Xra/e5EZ8bHTuDf8D1JC98djosXHk8sj5uf3HdL9dg464TtJPBwwNDQ3V597e2pbe/r5JugzTJkCAAAECBAgQIEBgvASqskLT3KkYL0DjEiBAgAABAgQIECBQFhAqyj6qBAgQIECAAAECBAhUCAgVFUDKBAgQIECAAAECBAiUBYSKso8qAQIECBAgQIAAAQIVAkJFBZAyAQIECBAgQIAAAQJlAaGi7KNKgAABAgQIECBAgECFgFBRAaRMgAABAgQIECBAgEBZQKgo+6gSIECAAAECBAgQIFAhIFRUACkTIECAAAECBAgQIFAWECrKPqoECBAgQIAAAQIECFQICBUVQMoECBAgQIAAAQIECJQFhIqyjyoBAgQIECBAgAABAhUCQkUFkDIBAgQIECBAgAABAmUBoaLso0qAAAECBAgQIECAQIWAUFEBpEyAAAECBAgQIECAQFlAqCj7qBIgQIAAAQIECBAgUCEgVFQAKRMgQIAAAQIECBAgUBYQKso+qgQIECBAgAABAgQIVAgIFRVAygQIECBAgAABAgQIlAWEirKPKgECBAgQIECAAAECFQJCRQWQMgECBAgQIECAAAECZQGhouyjSoAAAQIECBAgQIBAhYBQUQGkTIAAAQIECBAgQIBAWUCoKPuoEiBAgAABAgQIECBQISBUVAApEyBAgAABAgQIECBQFhAqyj6qBAgQIECAAAECBAhUCAgVFUDKBAgQIECAAAECBAiUBYSKso8qAQIECBAgQIAAAQIVAkJFBZAyAQIECBAgQIAAAQJlgaYJFbWezixubcuxy7oyMNqaaxuypmN+2uetSNdAbZSttqWn85y0t56S5V0vjrJN0uzHC6skzoX6D0Czn+vWV29yIz42OveG/wFqyN54bPTYOHJ55Pzc/mO6365BR1wn6acDhoaGhupzb29tS29/3yRdhmkTIECAAAECBAgQIDBeAlVZoWnuVIwXoHEJECBAgAABAgQIECgLCBVlH1UCBAgQIECAAAECBCoEhIoKIGUCBAgQIECAAAECBMoCQkXZR5UAAQIECBAgQIAAgQoBoaICSJkAAQIECBAgQIAAgbKAUFH2USVAgAABAgQIECBAoEJAqKgAUiZAgAABAgQIECBAoCwgVJR9VAkQIECAAAECBAgQqBAQKiqAlAkQIECAAAECBAgQKAsIFWUfVQIECBAgQIAAAQIEKgSEigogZQIECBAgQIAAAQIEygJCRdlHlQABAgQIECBAgACBCgGhogJImQABAgQIECBAgACBsoBQUfZRJUCAAAECBAgQIECgQkCoqABSJkCAAAECBAgQIECgLCBUlH1UCRAgQIAAAQIECBCoEBAqKoCUCRAgQIAAAQIECBAoCwgVZR9VAgQIECBAgAABAgQqBISKCiBlAgQIECBAgAABAgTKAkJF2UeVAAECBAgQIECAAIEKAaGiAkiZAAECBAgQIECAAIGygFBR9lElQIAAAQIECBAgQKBCQKioAFImQIAAAQIECBAgQKAsIFSUfVQJECBAgAABAgQIEKgQECoqgJQJECBAgAABAgQIECgLCBVlH1UCBAgQIECAAAECBCoEhIoKIGUCBAgQIECAAAECBMoCQkXZR5UAAQIECBAgQIAAgQoBoaICSJkAAQIECBAgQIAAgbKAUFH2USVAgAABAgQIECBAoEJAqKgAUiZAgAABAgQIECBAoCwgVJR9VAkQIECAAAECBAgQqBAQKiqAlAkQIECAAAECBAgQKAsIFWUfVQIECBAgQIAAAQIEKgSEigogZQIECBAgQIAAAQIEygJCRdlHlQABAgQIECBAgACBCgGhogJImQABAgQIECBAgACBsoBQUfZRJUCAAAECBAgQIECgQkCoqABSJkCAAAECBAgQIECgLCBUlH1UCRAgQIAAAQIECBCoEBAqKoCUCRAgQIAAAQIECBAoCwgVZR9VAgQIECBAgAABAgQqBISKCiBlAgQIECBAgAABAgTKAkJF2UeVAAECBAgQIECAAIEKAaGiAkiZAAECBAgQIECAAIGygFBR9lElQIAAAQIECBAgQKBCQKioAFImQIAAAQIECBAgQKAsIFSUfVQJECBAgAABAgQIEKgQECoqgJQJECBAgAABAgQIECgLCBVlH1UCBAgQIECAAAECBCoEmjxUbEtP5zlpn7ciXQO1Coot6V55RVZ1b6nYbke5lsEN38iqG+9Lz2DV2Dv28ZkAAQIECBAgQIBA8wk0eag4OHPOuy29T1+dRTNKS61loGtlLvrpwiw5buYYu9yS6XM/mI8vacnXrv1aNggWY3SzGQECBAgQIECAQLMJlK60m22to69ncH1uue7ZXHL5+3L4Xoq0zHpPLj11Q86+4lvZ5IbF6MYqBAgQIECAAAECTSuwl5fQDeQw0JXl8+Zn8S0/yP+68SM5trUt7a3z8/vLvpruzS+NTHQsT396KZu+/9XcctApOXH2wfuwwJbMOPmsXLJpdW564MV92N8uBAgQIECAAAECBCa3wOQNFcPuW/PEp5flr3NBvvezvvQ+eWcuytez5Pwvp3usT0eq9eW+W+/P7MUnZPZOjfrrJW7LRfPqQWXPf965sju/2tH7liNyzKJfz9+t/HZ6hu9WDKZ75e+lvfX3sqp7cMdWPhMgQIAAAQIECBBoSoGdl9GTdXXTTrsyV/3XEzKrvpLpc9PxyaU585++mbse/eexLWnw+fT2vCFHtx6anRi1ntyxamPO+of1uf3ShTmz85H09v/PfP7UWTnmqr/PT/v78ujSBTlw5xEOzuFt7cnj3Xn65/WoMT0Lln4nvf3fyWULpu/cyhcECBAgQIAAAQIEmlFg53X05FzctMx+19u2B4odC5j+5rTPeTHrvv9kBnZ8r/C59kJ/ntx6ZNqP2HHxX8vAA3en70P/OYtmHZTkdTl0xsFJ7V+z5f8kvznz9S+Hj53jtmTazEMyLb3p27Rt53d9QYAAAQIECBAgQGAqCEzyUDF6i7Y+0Z8XKl84Xcvgxr4884phWjJj0Sdy1aI3JtmS555KDnnDgcOh4pfPHpQ3zdzT6y5aMm3GzNQjiA8CBAgQIECAAAECU02gaUPFtGNa86bK1bVk+hFtmT1a13/18/Stf11m1kPF8Mfrt9+1eNX2tWwd2JIdLw9/Vdk3CBAgQIAAAQIECDSxQOVld2OvfWue6X0+r3gp9PBrJN6YjlOPzowxTL7lTa05etpz6d34ilGG96z1/ST3py1HvnFHqBhtwFq2bvlltqY9bYfv6U7GaPv5PgECBAgQIECAAIHJLzDJQ0Wy9baVuWHthu3BYvCprLn8T7LulKX52Mn1py+N4WP4NRj/kif7f5FXPFuq9mzu/sKX88Q72nJ4PVO0vD6HvHVz7rv/HzOw6e5c85UNu2y/LZv6epO3L8i8w6oCyBjmZBMCBAgQIECAAAECk0hgkoeKaZl7TkcW9H0uJ9bf+vXoC/PD+Z/OHTe8f+y/xK5lThYv/YM8c9dDeWaXVPGrx+7INfcmv3P6ghxWb2hLW3536QeSLy7JSZ/amNPe2/byC7ZrG/NE17/lzKWnZ86wqLeUnUQ/A6ZKgAABAgQIECDwGgUOGBoaGqqPUf99DL39fa9xuH/H3eu//O7dF+fJT96ZO86b+/IF/r5MYfCRrPrgF5LP3JTLFszcyxFqGexenQ/ffGRWrz5j7GFmL49icwIECBAgQIAAAQITJVCVFSb5nYr9xDr9HbngyqNy281d2bTL3YoxjT64PrfeeWiu3Zu7I2Ma2EYECBAgQIAAAQIEJoeAUDHcp5bMOPmj+dxh9+f2x7aMsXO1DPbcnVU3b877/vgPM3c6yjHC2YwAAQIECBAgQKDJBCbv05+arBGWQ4AAAQIECBAgQKBRBTz9qVE7Y14ECBAgQIAAAQIEmkTAc3aapJGWQYAAAQIECBAgQGCiBISKiZJ3XAIECBAgQIAAAQJNIiBUNEkjLYMAAQIECBAgQIDARAkIFRMl77gECBAgQIAAAQIEmkRAqGiSRloGAQIECBAgQIAAgYkSEComSt5xCRAgQIAAAQIECDSJgFDRJI20DAIECBAgQIAAAQITJSBUTJS84xIgQIAAAQIECBBoEgGhokkaaRkECBAgQIAAAQIEJkpAqJgoecclQIAAAQIECBAg0CQCQkWTNNIyCBAgQIAAAQIECEyUgFAxUfKOS4AAAQIECBAgQKBJBISKJmmkZRAgQIAAAQIECBCYKAGhYqLkHZcAAQIECBAgQIBAkwgIFU3SSMsgQIAAAQIECBAgMFECQsVEyTsuAQIECBAgQIAAgSYRECqapJGWQYAAAQIECBAgQGCiBISKiZJ3XAIECBAgQIAAAQJNIiBUNEkjLYMAAQIECBAgQIDARAkIFRMl77gECBAgQIAAAQIEmkRAqGiSRloGAQIECBAgQIAAgYkSEComSt5xCRAgQIAAAQIECDSJgFDRJI20DAIECBAgQIAAAQITJSBUTJS84xIgQIAAAQIECBBoEgGhokkaaRkECBAgQIAAAQIEJkqgaUJFraczi1vbcuyyrgyMplnbkDUd89M+b0W6BmqjbLUtPZ3npL31lCzvenGUbZJmP15YJXEu1H8Amv1ct756kxvxsdG5N/wPUEP2xmOjx8aRyyPn5/Yf0/12DTriOkk/HTA0NDRUn3t7a1t6+/sm6TJMmwABAgQIECBAgACB8RKoygpNc6divACNS4AAAQIECBAgQIBAWUCoKPuoEiBAgAABAgQIECBQISBUVAApEyBAgAABAgQIECBQFhAqyj6qBAgQIECAAAECBAhUCAgVFUDKBAgQIECAAAECBAiUBYSKso8qAQIECBAgQIAAAQIVAkJFBZAyAQIECBAgQIAAAQJlAaGi7KNKgAABAgQIECBAgECFgFBRAaRMgAABAgQIECBAgEBZQKgo+6gSIECAAAECBAgQIFAhIFRUACkTIECAAAECBAgQIFAWECrKPqoECBAgQIAAAQIECFQICBUVQMoECBAgQIAAAQIECJQFhIqyjyoBAgQIECBAgAABAhUCQkUFkDIBAgQIECBAgAABAmUBoaLso0qAAAECBAgQIECAQIWAUFEBpEyAAAECBAgQIECAQFlAqCj7qBIgQIAAAQIECBAgUCEgVFQAKRMgQIAAAQIECBAgUBYQKso+qgQIECBAgAABAgQIVAgIFRVAygQIECBAgAABAgQIlAWEirKPKgECBAgQIECAAAECFQJCRQWQMgECBAgQIECAAAECZQGhouyjSoAAAQIECBAgQIBAhYBQUQGkTIAAAQIECBAgQIBAWUCoKPuoEiBAgAABAgQIECBQISBUVAApEyBAgAABAgQIECBQFhAqyj6qBAgQIECAAAECBAhUCAgVFUDKBAgQIECAAAECBAiUBZomVNR6OrO4tS3HLuvKwGhrrm3Imo75aZ+3Il0DtVG22paeznPS3npKlne9OMo2SbMfL6ySOBfqPwDNfq5bX73JjfjY6Nwb/geoIXvjsdFj48jlkfNz+4/pfrsGHXGdpJ8OGBoaGqrPvb21Lb39fZN0GaZNgAABAgQIECBAgMB4CVRlhaa5UzFegMYlQIAAAQIECBAgQKAsIFSUfVQJECBAgAABAgQIEKgQECoqgJQJECBAgAABAgQIECgLCBVlH1UCBAgQIECAAAECBCoEhIoKIGUCBAgQIECAAAECBMoCQkXZR5UAAQIECBAgQIAAgQoBoaICSJkAAQIECBAgQIAAgbKAUFH2USVAgAABAgQIECBAoEJAqKgAUiZAgAABAgQIECBAoCwgVJR9VAkQIECAAAECBAgQqBAQKiqAlAkQIECAAAECBAgQKAsIFWUfVQIECBAgQIAAAQIEKgSEigogZQIECBAgQIAAAQIEygJCRdlHlQABAgQIECBAgACBCgGhogJImQABAgQIECBAgACBsoBQUfZRJUCAAAECBAgQIECgQkCoqABSJkCAAAECBAgQIECgLCBUlH1UCRAgQIAAAQIECBCoEBAqKoCUCRAgQIAAAQIECBAoCwgVZR9VAgQIECBAgAABAgQqBISKCiBlAgQIECBAgAABAgTKAkJF2UeVAAECBAgQIECAAIEKAaGiAkiZAAECBAgQIECAAIGygFBR9lElQIAAAQIECBAgQKBCQKioAFImQIAAAQIECBAgQKAsIFSUfVQJECBAgAABAgQIEKgQECoqgJQJECBAgAABAgQIECgLCBVlH1UCBAgQIECAAAECBCoEhIoKIGUCBAgQIECAAAECBMoCQkXZR5UAAQIECBAgQIAAgQqBA4aGhobaW9sqNlMmQIAAAQIECBAgQGCqC/T29+2RYDhU7LHimwQIECBAgAABAgQIEBiDgKc/jQHJJgQIECBAgAABAgQIjC4gVIxuo0KAAAECBAgQIECAwBgEhIoxINmEAAECBAgQIECAAIHRBYSK0W1UCBAgQIAAAQIECBAYg8D/B8gWvn75M7M+AAAAAElFTkSuQmCC"></p>
<p> </p>
<div class="marks">[2]</div>
<div class="question_part_label">g.i.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Deduce the number of σ and \(\pi \) bonds in a molecule of ethyne.</p>
<p><img src="data:image/png;base64,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"></p>
<p> </p>
<div class="marks">[1]</div>
<div class="question_part_label">g.ii.</div>
</div>
<h2 style="margin-top: 1em">Markscheme</h2>
<div class="question" style="padding-left: 20px;">
<p>electrostatic attraction <strong><em>AND </em></strong>oppositely charged ions</p>
<p><em><strong>[1 mark]</strong></em></p>
<div class="question_part_label">a.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p>multiply relative intensity by <strong>«</strong><em>m</em>/<em>z</em><strong>» </strong>value of isotope</p>
<p><strong><em>OR</em></strong></p>
<p>find the frequency of each isotope</p>
<p> </p>
<p>sum of the values of products/multiplication <strong>«</strong>from each isotope<strong>»</strong></p>
<p><strong><em>OR</em></strong></p>
<p>find/calculate the weighted average</p>
<p> </p>
<p><em>Award </em><strong><em>[1 max] </em></strong><em>for stating “m/z values of </em><em>isotopes </em><strong><em>AND </em></strong><em>relative </em><em>abundance/intensity” but not stating </em><em>these need to be multiplied.</em></p>
<p><strong><em>[2 marks]</em></strong></p>
<div class="question_part_label">b.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p><strong>«</strong>promoted<strong>»</strong> electrons fall back to lower energy level</p>
<p>energy difference between levels is different</p>
<p> </p>
<p><em>Accept “Na and Ca have different </em><em>nuclear charge” for M2.</em></p>
<p><strong><em>[2 marks]</em></strong></p>
<div class="question_part_label">c.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p><em>Any two of:</em></p>
<p>stronger metallic bonding</p>
<p>smaller ionic/atomic radius</p>
<p> </p>
<p>two electrons per atom are delocalized</p>
<p><strong><em>OR</em></strong></p>
<p>greater ionic charge</p>
<p> </p>
<p>greater atomic mass</p>
<p> </p>
<p><em>Do </em><strong><em>not </em></strong><em>accept just “heavier” or “more </em><em>massive” without reference to atomic </em><em>mass.</em></p>
<p><strong><em>[2 marks]</em></strong></p>
<div class="question_part_label">d.i.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p>delocalized/mobile electrons <strong>«</strong>free to move<strong>»</strong></p>
<p> </p>
<p> </p>
<p><strong><em>[1 mark]</em></strong></p>
<div class="question_part_label">d.ii.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p><img src="images/Schermafbeelding_2018-08-07_om_13.26.19.png" alt="M18/4/CHEMI/HP2/ENG/TZ1/02.e/M"></p>
<p>general increase</p>
<p>only one discontinuity between “IE2” and “IE3”</p>
<p><em><strong>[2 marks]</strong></em></p>
<div class="question_part_label">e.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p>pH > 7</p>
<p> </p>
<p><em>Accept any specific pH value or range </em><em>of values above 7 and below 14.</em></p>
<p><strong><em>[1 mark]</em></strong></p>
<div class="question_part_label">f.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p><em>sigma (σ</em><em>)</em><em>:</em></p>
<p>overlap <strong>«</strong>of atomic orbitals<strong>» </strong>along the axial/internuclear axis</p>
<p><strong><em>OR</em></strong></p>
<p>head-on/end-to-end overlap <strong>«</strong>of atomic orbitals<strong>»</strong></p>
<p> </p>
<p><em>pi (\(\pi \))</em><em>:</em></p>
<p>overlap <strong>«</strong>of p-orbitals<strong>» </strong>above and below the internuclear axis</p>
<p><strong><em>OR</em></strong></p>
<p>sideways overlap <strong>«</strong>of p-orbitals<strong>»</strong></p>
<p> </p>
<p><em>Award marks for suitable diagrams.</em></p>
<p> </p>
<p><strong><em>[2 marks]</em></strong></p>
<div class="question_part_label">g.i.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p><em>sigma (σ</em><em>)</em><em>:</em> 3</p>
<p><strong><em>AND</em></strong></p>
<p><em>pi (</em>\(\pi \)<em>)</em><em>:</em> 2</p>
<p><strong><em>[1 mark]</em></strong></p>
<div class="question_part_label">g.ii.</div>
</div>
<h2 style="margin-top: 1em">Examiners report</h2>
<div class="question" style="padding-left: 20px;">
[N/A]
<div class="question_part_label">a.</div>
</div>
<div class="question" style="padding-left: 20px;">
[N/A]
<div class="question_part_label">b.</div>
</div>
<div class="question" style="padding-left: 20px;">
[N/A]
<div class="question_part_label">c.</div>
</div>
<div class="question" style="padding-left: 20px;">
[N/A]
<div class="question_part_label">d.i.</div>
</div>
<div class="question" style="padding-left: 20px;">
[N/A]
<div class="question_part_label">d.ii.</div>
</div>
<div class="question" style="padding-left: 20px;">
[N/A]
<div class="question_part_label">e.</div>
</div>
<div class="question" style="padding-left: 20px;">
[N/A]
<div class="question_part_label">f.</div>
</div>
<div class="question" style="padding-left: 20px;">
[N/A]
<div class="question_part_label">g.i.</div>
</div>
<div class="question" style="padding-left: 20px;">
[N/A]
<div class="question_part_label">g.ii.</div>
</div>
<br><hr><br><div class="specification">
<p class="p1">Iron has three main naturally occurring isotopes which can be investigated using a mass spectrometer.</p>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">State the full electronic configurations of a Cu atom and a \({\text{C}}{{\text{u}}^ + }\) ion.</p>
<p class="p2"> </p>
<p class="p1">Cu:</p>
<p class="p2"> </p>
<p class="p1">\({\text{C}}{{\text{u}}^ + }\):</p>
<div class="marks">[2]</div>
<div class="question_part_label">d.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">Explain the origin of colour in transition metal complexes and use your explanation to suggest why copper(II) sulfate, CuSO<sub><span class="s1">4</span></sub>(aq), is blue, but zinc sulfate, ZnSO<sub><span class="s1">4</span></sub>(aq), is colourless.</p>
<div class="marks">[4]</div>
<div class="question_part_label">e.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">\({\text{C}}{{\text{u}}^{2 + }}{\text{(aq)}}\) reacts with ammonia to form the complex ion \({{\text{[Cu(N}}{{\text{H}}_{\text{3}}}{{\text{)}}_{\text{4}}}{\text{]}}^{2 + }}\). Explain this reaction in terms of an acid-base theory, and outline how the bond is formed between \({\text{C}}{{\text{u}}^{2 + }}\) and \({\text{N}}{{\text{H}}_{\text{3}}}\).</p>
<div class="marks">[3]</div>
<div class="question_part_label">f.</div>
</div>
<h2 style="margin-top: 1em">Markscheme</h2>
<div class="question" style="padding-left: 20px;">
<p class="p1"><em>Cu</em>:</p>
<p class="p1">\({\text{1}}{{\text{s}}^{\text{2}}}{\text{2}}{{\text{s}}^{\text{2}}}{\text{2}}{{\text{p}}^{\text{6}}}{\text{3}}{{\text{s}}^{\text{2}}}{\text{3}}{{\text{p}}^{\text{6}}}{\text{3}}{{\text{d}}^{{\text{10}}}}{\text{4}}{{\text{s}}^{\text{1}}}\);</p>
<p class="p1">\({\text{C}}{{\text{u}}^ + }\):</p>
<p class="p1">\({\text{1}}{{\text{s}}^{\text{2}}}{\text{2}}{{\text{s}}^{\text{2}}}{\text{2}}{{\text{p}}^{\text{6}}}{\text{3}}{{\text{s}}^{\text{2}}}{\text{3}}{{\text{p}}^{\text{6}}}{\text{3}}{{\text{d}}^{{\text{10}}}}\);</p>
<p class="p1"><em>Ignore relative order of 3d and 4s.</em></p>
<p class="p1"><em>Penalize only once if noble gas core is given.</em></p>
<div class="question_part_label">d.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p class="p1">d orbitals are split (into two sets of different energies);</p>
<p class="p1">frequencies of (visible) light absorbed by electrons moving from lower to higher d levels;</p>
<p class="p1">colour due to remaining frequencies/complementary colour transmitted;</p>
<p class="p1">\({\text{C}}{{\text{u}}^{2 + }}\) has unpaired electrons/partially filled d sub-level;</p>
<p class="p1">\({\text{Z}}{{\text{n}}^{2 + }}\) has filled d sub-shell;</p>
<p class="p1">electronic transitions/d-d transitions possible for \({\text{C}}{{\text{u}}^{2 + }}\) / no electronic/d-d transitions possible for \({\text{Z}}{{\text{n}}^{2 + }}\);</p>
<p class="p1"><em>Allow wavelength as well as frequency.</em></p>
<div class="question_part_label">e.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p class="p1">\({\text{N}}{{\text{H}}_{\text{3}}}\): Lewis base / \({\text{C}}{{\text{u}}^{2 + }}\): Lewis acid;</p>
<p class="p1">each \({\text{N}}{{\text{H}}_{\text{3}}}\)/ligand donates an electron pair (to \({\text{C}}{{\text{u}}^{2 + }}\));</p>
<p class="p1">\({\text{N}}{{\text{H}}_{\text{3}}}\) replace \({{\text{H}}_2}{\text{O}}\) ligands around \({\text{C}}{{\text{u}}^{2 + }}\) ion/around central ion;</p>
<p class="p1">forming coordinate (covalent)/dative covalent bond;</p>
<div class="question_part_label">f.</div>
</div>
<h2 style="margin-top: 1em">Examiners report</h2>
<div class="question" style="padding-left: 20px;">
<p class="p1">Many candidates identified the electronic configuration of Cu as an exception but the 3d electron was often removed in forming the ion instead of the 4s.</p>
<div class="question_part_label">d.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p class="p1">Precision of language proved to be an issue in (e) with some candidates referring to Cu and Zn and not their ions and some students explained the colour as a result of “reflection” or “emission”.</p>
<div class="question_part_label">e.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p class="p1">In (f), many candidates mentioned proton donors and proton acceptors and made no reference to Lewis theory.</p>
<div class="question_part_label">f.</div>
</div>
<br><hr><br><div class="specification">
<p>The oxides and chlorides of period 3 elements exhibit periodicity.</p>
</div>
<div class="specification">
<p>Chlorine gas, \({\text{C}}{{\text{l}}_{\text{2}}}{\text{(g)}}\), is bubbled through separate solutions of aqueous bromine, \({\text{B}}{{\text{r}}_{\text{2}}}{\text{(aq)}}\), and potassium bromide, \({\text{KBr(aq)}}\).</p>
</div>
<div class="specification">
<p>The hydrogen halides do not show perfect periodicity. A bar chart of boiling points shows that the boiling point of hydrogen fluoride, HF, is much higher than periodic trends would indicate.</p>
<p style="text-align: left;"><img src="images/Schermafbeelding_2016-08-12_om_06.29.26.png" alt="M14/4/CHEMI/HP2/ENG/TZ1/05.c"></p>
</div>
<div class="specification">
<p>Transition metals form complex ions which are usually coloured.</p>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>(i) State the changes in the acid-base nature of the oxides across period 3 (from \({\text{N}}{{\text{a}}_2}{\text{O}}\) to \({\text{C}}{{\text{l}}_{\text{2}}}{{\text{O}}_{\text{7}}}\)), including equations for the reactions of \({\text{N}}{{\text{a}}_2}{\text{O}}\) and \({\text{S}}{{\text{O}}_{\text{3}}}\) with water.</p>
<p> </p>
<p> </p>
<p> </p>
<p> </p>
<p> </p>
<p>(ii) State whether or not molten aluminium chloride, \({\text{A}}{{\text{l}}_{\text{2}}}{\text{C}}{{\text{l}}_{\text{6}}}\), and molten aluminium oxide, \({\text{A}}{{\text{l}}_{\text{2}}}{{\text{O}}_{\text{3}}}\), conduct electricity. Explain this behaviour in terms of the structure and bonding of the two compounds.</p>
<p> </p>
<p> </p>
<p> </p>
<p> </p>
<p> </p>
<p> </p>
<p>(iii) State the equation for the reaction of \({\text{C}}{{\text{l}}_{\text{2}}}\) with water.</p>
<div class="marks">[7]</div>
<div class="question_part_label">a.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>(i) Predict any changes that may be observed in each case.</p>
<p> </p>
<p>\({\text{B}}{{\text{r}}_{\text{2}}}{\text{(aq)}}\):</p>
<p> </p>
<p> </p>
<p>\({\text{KBr(aq)}}\):</p>
<p> </p>
<p> </p>
<p>(ii) State the half-equations for the reactions that occur.</p>
<div class="marks">[4]</div>
<div class="question_part_label">b.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>(i) Explain why the boiling point of HF is much higher than the boiling points of the other hydrogen halides.</p>
<p> </p>
<p> </p>
<p>(ii) Explain the trend in the boiling points of HCl, HBr and HI.</p>
<div class="marks">[3]</div>
<div class="question_part_label">c.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>State the full electron configurations of Cr and \({\text{C}}{{\text{r}}^{3 + }}\).</p>
<p> </p>
<p>Cr:</p>
<p> </p>
<p>\({\text{C}}{{\text{r}}^{3 + }}\):</p>
<div class="marks">[2]</div>
<div class="question_part_label">d.i.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>\({\text{C}}{{\text{r}}^{3 + }}\) ions and water molecules bond together to form the complex ion \({{\text{[Cr(}}{{\text{H}}_{\text{2}}}{\text{O}}{{\text{)}}_{\text{6}}}{\text{]}}^{3 + }}\).</p>
<p>Describe how the water acts and how it forms the bond, identifying the acid-base character of the reaction.</p>
<div class="marks">[3]</div>
<div class="question_part_label">d.ii.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Explain why the \({{\text{[Cr(}}{{\text{H}}_{\text{2}}}{\text{O}}{{\text{)}}_{\text{6}}}{\text{]}}^{3 + }}\) ion is coloured.</p>
<div class="marks">[3]</div>
<div class="question_part_label">d.iii.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Outline, including a relevant equation, whether the \({{\text{[Cr(}}{{\text{H}}_{\text{2}}}{\text{O}}{{\text{)}}_{\text{6}}}{\text{]}}^{3 + }}\) ion is acidic, basic or neutral.</p>
<div class="marks">[1]</div>
<div class="question_part_label">d.iv.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Explain how the number of electrons in the outer main energy level of phosphorus, P, can be determined using the data of successive ionization energies.</p>
<div class="marks">[2]</div>
<div class="question_part_label">e.</div>
</div>
<h2 style="margin-top: 1em">Markscheme</h2>
<div class="question" style="padding-left: 20px;">
<p>(i) basic to acidic;</p>
<p>\({\text{N}}{{\text{a}}_{\text{2}}}{\text{O(s)}} + {{\text{H}}_{\text{2}}}{\text{O(l)}} \to {\text{2NaOH(aq)}}\);</p>
<p>\({\text{S}}{{\text{O}}_3}{\text{(g)}} + {{\text{H}}_2}{\text{O(l)}} \to {{\text{H}}_2}{\text{S}}{{\text{O}}_4}{\text{(aq)}}\);</p>
<p><em>Ignore state symbols.</em></p>
<p>(ii) molten \({\text{A}}{{\text{l}}_2}{\text{C}}{{\text{l}}_6}\) does not conduct electricity <strong>and </strong>molten \({\text{A}}{{\text{l}}_{\text{2}}}{{\text{O}}_{\text{3}}}\) does;</p>
<p>\({\text{A}}{{\text{l}}_2}{\text{C}}{{\text{l}}_6}\) is a covalent molecule <strong>and </strong>has no free charged particles to conduct electricity;</p>
<p>\({\text{A}}{{\text{l}}_2}{{\text{O}}_3}\) is ionic/has ions which are free to move when molten;</p>
<p>(iii) \({\text{C}}{{\text{l}}_2}{\text{(g)}} + {{\text{H}}_2}{\text{O(l)}} \rightleftharpoons {\text{HCl(aq)}} + {\text{HClO(aq)}}\);</p>
<p><em>Ignore state symbols.</em></p>
<p><em>Allow </em>\( \to \)<em>.</em></p>
<div class="question_part_label">a.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p>(i) \({\text{B}}{{\text{r}}_2}{\text{(aq)}}\): no change;</p>
<p>\({\text{KBr(aq)}}\): colour change / from colourless to red/yellow/orange/brown;</p>
<p>(ii) \({\text{2B}}{{\text{r}}^ - }{\text{(aq)}} \to {\text{B}}{{\text{r}}_2}{\text{(aq)}} + {\text{2}}{{\text{e}}^ - }\);</p>
<p>\({\text{C}}{{\text{l}}_2}{\text{(g)}} + {\text{2}}{{\text{e}}^ - } \to {\text{2C}}{{\text{l}}^ - }{\text{(aq)}}\);</p>
<p><em>Ignore state symbols.</em></p>
<p><em>Accept e instead of e</em><sup><em>–</em></sup><em>.</em></p>
<div class="question_part_label">b.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p>(i) HF has hydrogen bonds (between molecules);</p>
<p>(ii) strength of van der Waals’/London/dispersion forces increases;</p>
<p>as mass/size/number of electrons of halogen atom/molecule increases;</p>
<div class="question_part_label">c.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p><em>Cr: </em>\({\text{1}}{{\text{s}}^{\text{2}}}{\text{2}}{{\text{s}}^{\text{2}}}{\text{2}}{{\text{p}}^{\text{6}}}{\text{3}}{{\text{s}}^{\text{2}}}{\text{3}}{{\text{p}}^{\text{6}}}{\text{4}}{{\text{s}}^{\text{1}}}{\text{3}}{{\text{d}}^{\text{5}}}/{\text{1}}{{\text{s}}^{\text{2}}}{\text{2}}{{\text{s}}^{\text{2}}}{\text{2}}{{\text{p}}^{\text{6}}}{\text{3}}{{\text{s}}^{\text{2}}}{\text{3}}{{\text{p}}^{\text{6}}}{\text{3}}{{\text{d}}^{\text{5}}}{\text{4}}{{\text{s}}^{\text{1}}}\);</p>
<p><em>Cr</em><sup><em>3+</em></sup><em>:</em> \({\text{1}}{{\text{s}}^{\text{2}}}{\text{2}}{{\text{s}}^{\text{2}}}{\text{2}}{{\text{p}}^{\text{6}}}{\text{3}}{{\text{s}}^{\text{2}}}{\text{3}}{{\text{p}}^{\text{6}}}{\text{3}}{{\text{d}}^{\text{3}}}\);</p>
<div class="question_part_label">d.i.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p>\({{\text{H}}_2}{\text{O}}\) is a ligand / has lone (electron) pair;</p>
<p>forms dative (covalent)/coordinate bond / donates a lone (electron) pair ;</p>
<p>ligand is Lewis base / \({\text{C}}{{\text{r}}^{3 + }}\) is Lewis acid;</p>
<div class="question_part_label">d.ii.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p>\({\text{C}}{{\text{r}}^{3 + }}\) has partially filled d orbitals;</p>
<p>d orbitals split into two levels / three lower energy and two higher energy levels;</p>
<p>energy difference is in visible part of spectrum;</p>
<p>electrons absorb <span style="text-decoration: underline;">visible</span> light / one colour/frequency/wavelength;</p>
<p>electron transitions occur from lower to higher energy level within d sub-level;</p>
<p>complementary colour/colour not absorbed is seen;</p>
<div class="question_part_label">d.iii.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p>acidic because \({{\text{[Cr(}}{{\text{H}}_2}{\text{O}}{{\text{)}}_6}{\text{]}}^{3 + }}{\text{(aq)}} \to {{\text{[Cr(}}{{\text{H}}_2}{\text{O}}{{\text{)}}_5}{\text{(OH)]}}^{2 + }}{\text{(aq)}} + {{\text{H}}^ + }{\text{(aq)}}\);</p>
<p><em>Allow answers with further equations.</em></p>
<p><em>Accept any other valid equations.</em></p>
<p><em>Ignore state symbols.</em></p>
<div class="question_part_label">d.iv.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p>successive ionization energy values increase with removal of each electron;</p>
<p>large increase in ionization energy when sixth electron is removed;</p>
<p>as electron is one energy level/shell closer to the nucleus;</p>
<p><em>Accept a suitably annotated diagram.</em></p>
<div class="question_part_label">e.</div>
</div>
<h2 style="margin-top: 1em">Examiners report</h2>
<div class="question" style="padding-left: 20px;">
<p>There appeared to be some significant gaps in knowledge within this question, the various parts either scored very well or not at all.</p>
<p>In a(ii) there was a poor understanding of the nature of bonding in aluminium chloride and aluminium oxide. Candidates are still confusing electrical conductivity in compounds with that in metals, and often refer to the inability to conduct being down to a lack of mobile electrons in compounds.</p>
<p>Balancing equations, both full, as in parts a(i) and a(iii), and half equations as in b(ii), showed poor knowledge both of the reactants and products and in the ability to balance them in both atoms and charge. It should be expected that higher level candidates would be comfortable with these processes. The ability to deduce and predict what they would see during a reaction is a skill required of all chemists, it was missing in the attempts to answer b(ii). Parts c and d(i), (ii) and (iii) showed good knowledge, but in part d(iv) the understanding of the acid nature of some d block complex ions was lacking. Part e was rarely given credit, as many appeared to misread the question, and discussed the changes in first ionisation energies across Period 3.</p>
<div class="question_part_label">a.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p>There appeared to be some significant gaps in knowledge within this question, the various parts either scored very well or not at all.</p>
<p>In a(ii) there was a poor understanding of the nature of bonding in aluminium chloride and aluminium oxide. Candidates are still confusing electrical conductivity in compounds with that in metals, and often refer to the inability to conduct being down to a lack of mobile electrons in compounds.</p>
<p>Balancing equation,s both full, as in parts a(i) and a(iii), and half equations as in b(ii), showed poor knowledge both of the reactants and products and in the ability to balance them in both atoms and charge. It should be expected that higher level candidates would be comfortable with these processes. The ability to deduce and predict what they would see during a reaction is a skill required of all chemists, it was missing in the attempts to answer b(ii). Parts c and d(i), ii) and iii) showed good knowledge, but in part d(iv) the understanding of the acid nature of some d block complex ions was lacking. Part e was rarely given credit, as many appeared to misread the question, and discussed the changes in first ionisation energies across Period 3.</p>
<div class="question_part_label">b.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p>There appeared to be some significant gaps in knowledge within this question, the various parts either scored very well or not at all.</p>
<p>In a(ii) there was a poor understanding of the nature of bonding in aluminium chloride and aluminium oxide. Candidates are still confusing electrical conductivity in compounds with that in metals, and often refer to the inability to conduct being down to a lack of mobile electrons in compounds.</p>
<p>Balancing equations, both full, as in parts a(i) and a(iii), and half equations as in b(ii), showed poor knowledge both of the reactants and products and in the ability to balance them in both atoms and charge. It should be expected that higher level candidates would be comfortable with these processes. The ability to deduce and predict what they would see during a reaction is a skill required of all chemists, it was missing in the attempts to answer b(ii). Parts c and d(i), ii) and iii) showed good knowledge, but in part d(iv) the understanding of the acid nature of some d block complex ions was lacking. Part e was rarely given credit, as many appeared to misread the question, and discussed the changes in first ionisation energies across Period 3.</p>
<div class="question_part_label">c.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p>There appeared to be some significant gaps in knowledge within this question, the various parts either scored very well or not at all.</p>
<p>In a(ii) there was a poor understanding of the nature of bonding in aluminium chloride and aluminium oxide. Candidates are still confusing electrical conductivity in compounds with that in metals, and often refer to the inability to conduct being down to a lack of mobile electrons in compounds.</p>
<p>Balancing equations, both full, as in parts a(i) and a(iii), and half equations as in b(ii), showed poor knowledge both of the reactants and products and in the ability to balance them in both atoms and charge. It should be expected that higher level candidates would be comfortable with these processes. The ability to deduce and predict what they would see during a reaction is a skill required of all chemists, it was missing in the attempts to answer b(ii). Parts c and d(i), ii) and iii) showed good knowledge, but in part d(iv) the understanding of the acid nature of some d block complex ions was lacking. Part e was rarely given credit, as many appeared to misread the question, and discussed the changes in first ionisation energies across Period 3.</p>
<div class="question_part_label">d.i.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p>There appeared to be some significant gaps in knowledge within this question, the various parts either scored very well or not at all.</p>
<p>In a(ii) there was a poor understanding of the nature of bonding in aluminium chloride and aluminium oxide. Candidates are still confusing electrical conductivity in compounds with that in metals, and often refer to the inability to conduct being down to a lack of mobile electrons in compounds.</p>
<p>Balancing equations, both full, as in parts a(i) and a(iii), and half equations as in b(ii), showed poor knowledge both of the reactants and products and in the ability to balance them in both atoms and charge. It should be expected that higher level candidates would be comfortable with these processes. The ability to deduce and predict what they would see during a reaction is a skill required of all chemists, it was missing in the attempts to answer b(ii). Parts c and d(i), ii) and iii) showed good knowledge, but in part d(iv) the understanding of the acid nature of some d block complex ions was lacking. Part e was rarely given credit, as many appeared to misread the question, and discussed the changes in first ionisation energies across Period 3.</p>
<div class="question_part_label">d.ii.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p>There appeared to be some significant gaps in knowledge within this question, the various parts either scored very well or not at all.</p>
<p>In a(ii) there was a poor understanding of the nature of bonding in aluminium chloride and aluminium oxide. Candidates are still confusing electrical conductivity in compounds with that in metals, and often refer to the inability to conduct being down to a lack of mobile electrons in compounds.</p>
<p>Balancing equations, both full, as in parts a(i) and a(iii), and half equations as in b(ii), showed poor knowledge both of the reactants and products and in the ability to balance them in both atoms and charge. It should be expected that higher level candidates would be comfortable with these processes. The ability to deduce and predict what they would see during a reaction is a skill required of all chemists, it was missing in the attempts to answer b(ii). Parts c and d(i), ii) and iii) showed good knowledge, but in part d(iv) the understanding of the acid nature of some d block complex ions was lacking. Part e was rarely given credit, as many appeared to misread the question, and discussed the changes in first ionisation energies across Period 3.</p>
<div class="question_part_label">d.iii.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p>There appeared to be some significant gaps in knowledge within this question, the various parts either scored very well or not at all.</p>
<p>In a(ii) there was a poor understanding of the nature of bonding in aluminium chloride and aluminium oxide. Candidates are still confusing electrical conductivity in compounds with that in metals, and often refer to the inability to conduct being down to a lack of mobile electrons in compounds.</p>
<p>Balancing equations, both full, as in parts a(i) and a(iii), and half equations as in b(ii), showed poor knowledge both of the reactants and products and in the ability to balance them in both atoms and charge. It should be expected that higher level candidates would be comfortable with these processes. The ability to deduce and predict what they would see during a reaction is a skill required of all chemists, it was missing in the attempts to answer b(ii). Parts c and d(i), ii) and iii) showed good knowledge, but in part d(iv) the understanding of the acid nature of some d block complex ions was lacking. Part e was rarely given credit, as many appeared to misread the question, and discussed the changes in first ionisation energies across Period 3.</p>
<div class="question_part_label">d.iv.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p>There appeared to be some significant gaps in knowledge within this question, the various parts either scored very well or not at all.</p>
<p>In a(ii) there was a poor understanding of the nature of bonding in aluminium chloride and aluminium oxide. Candidates are still confusing electrical conductivity in compounds with that in metals, and often refer to the inability to conduct being down to a lack of mobile electrons in compounds.</p>
<p>Balancing equations, both full, as in parts a(i) and a(iii), and half equations as in b(ii) showed poor knowledge both of the reactants and products and in the ability to balance them in both atoms and charge. It should be expected that higher level candidates would be comfortable with these processes. The ability to deduce and predict what they would see during a reaction is a skill required of all chemists, it was missing in the attempts to answer b(ii). Parts c and d(i), ii) and iii) showed good knowledge, but in part d(iv) the understanding of the acid nature of some d block complex ions was lacking. Part e was rarely given credit, as many appeared to misread the question, and discussed the changes in first ionisation energies across Period 3.</p>
<div class="question_part_label">e.</div>
</div>
<br><hr><br><div class="specification">
<p class="p1">Magnesium is the eighth most abundant element in the earth’s crust. The successive ionization energies of the element are shown below.</p>
<p class="p1" style="text-align: center;"><img src="images/Schermafbeelding_2016-09-25_om_14.06.48.png" alt="N10/4/CHEMI/HP2/ENG/TZ0/04"></p>
</div>
<div class="specification">
<p class="p1">Magnesium can be produced from the electrolysis of molten magnesium chloride, MgCl<sub><span class="s1">2</span></sub>.</p>
</div>
<div class="specification">
<p class="p1">The lattice enthalpy of magnesium chloride can be calculated from the Born-Haber cycle shown below.</p>
<p class="p1" style="text-align: center;"><img src="images/Schermafbeelding_2016-09-25_om_14.10.58.png" alt="N10/4/CHEMI/HP2/ENG/TZ0/04.c"></p>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">(i) <span class="Apple-converted-space"> </span>Define the term <em>first ionization energy </em>and state the equation for the first ionization of magnesium.</p>
<p class="p1">(ii) <span class="Apple-converted-space"> </span>Explain the general increase in successive ionization energies of the element.</p>
<p class="p1">(iii) <span class="Apple-converted-space"> </span>Explain the large increase between the tenth and eleventh ionization energies.</p>
<div class="marks">[8]</div>
<div class="question_part_label">a.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">(i) <span class="Apple-converted-space"> </span>Explain how molten magnesium chloride conducts an electric current.</p>
<p class="p1">(ii) <span class="Apple-converted-space"> </span>Identify the electrode where oxidation occurs during electrolysis of molten magnesium chloride and state an equation for the half-reaction.</p>
<p class="p1">(iii) <span class="Apple-converted-space"> </span>Explain why magnesium is not formed during the electrolysis of aqueous magnesium chloride solution.</p>
<div class="marks">[5]</div>
<div class="question_part_label">b.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">(i) <span class="Apple-converted-space"> </span>Identify the enthalpy changes labelled by <strong>I </strong>and <strong>V </strong>in the cycle.</p>
<p class="p1">(ii) <span class="Apple-converted-space"> </span>Use the ionization energies given in the cycle above and further data from the Data Booklet to calculate a value for the lattice enthalpy of magnesium chloride.</p>
<p class="p1">(iii) <span class="Apple-converted-space"> </span>The theoretically calculated value for the lattice enthalpy of magnesium chloride is +2326 kJ. Explain the difference between the theoretically calculated value and the experimental value.</p>
<p class="p1">(iv) <span class="Apple-converted-space"> </span>The experimental lattice enthalpy of magnesium oxide is given in Table 13 of the Data Booklet. Explain why magnesium oxide has a higher lattice enthalpy than magnesium chloride.</p>
<div class="marks">[10]</div>
<div class="question_part_label">c.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">(i) <span class="Apple-converted-space"> </span>State whether aqueous solutions of magnesium oxide and magnesium chloride are acidic, alkaline or neutral.</p>
<p class="p1">(ii) <span class="Apple-converted-space"> </span>State an equation for the reaction between magnesium oxide and water.</p>
<div class="marks">[2]</div>
<div class="question_part_label">d.</div>
</div>
<h2 style="margin-top: 1em">Markscheme</h2>
<div class="question" style="padding-left: 20px;">
<p class="p1">(i) energy (per mole) needed to remove one/first/most loosely bound electron from a (neutral) atom;</p>
<p class="p1">in the gaseous state;</p>
<p class="p1">\({\text{Mg(g)}} \to {\text{M}}{{\text{g}}^ + }{\text{(g)}} + {{\text{e}}^ - }\);</p>
<p class="p1"><em>Gaseous state symbols needed.</em></p>
<p class="p1"><em>Accept e instead of e<sup>–</sup></em>.</p>
<p class="p1"><em>Only penalize omission of gas phase once in either the second marking point or </em><em>the third marking point.</em></p>
<p class="p1">(ii) successive electrons (are more difficult to remove because each is) taken from more positively charged ion/ <em>OWTTE</em>;</p>
<p class="p1">increased electrostatic attraction;</p>
<p class="p1">(iii) 10<sup><span class="s2">th </span></sup>electron comes from 2<sup><span class="s2">nd </span></sup>energy level/\(n = 2\) <strong>and </strong>11<sup><span class="s2">th </span></sup>electron comes from 1<sup><span class="s2">st </span></sup>first energy level/\(n = 1\) / <em>OWTTE</em>;</p>
<p class="p1">electron in 1<sup><span class="s2">st </span></sup>energy level closer to nucleus;</p>
<p class="p1">electron in 1<sup><span class="s2">st </span></sup>energy level not shielded by inner electrons / exposed to greater effective nuclear charge;</p>
<div class="question_part_label">a.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p class="p1">(i) <span class="Apple-converted-space"> </span>contains ions which are free to move (only) in molten state;</p>
<p class="p1">\({\text{M}}{{\text{g}}^{2 + }}\) move to cathode/negative electrode and \({\text{C}}{{\text{l}}^ - }\) move to anode/positive electrode <em>/ OWTTE</em>;</p>
<p class="p1">(ii) <span class="Apple-converted-space"> </span>anode/positive electrode;</p>
<p class="p1">\({\text{2C}}{{\text{l}}^ - } \to {\text{C}}{{\text{l}}_2} + {\text{2}}{{\text{e}}^ - }/{\text{C}}{{\text{l}}^ - } \to \frac{1}{2}{\text{C}}{{\text{l}}_2}+{{\text{e}}^ - }\);</p>
<p class="p1"><em>Accept e instead of e<sup>–</sup></em>.</p>
<p class="p1"><em>Do not accept </em>\(C{l^ - } \to Cl + {e^ - }\)<em>.</em></p>
<p class="p1"><em>Ignore state symbols.</em></p>
<p class="p1">(iii) <span class="Apple-converted-space"> </span>magnesium has large negative electrode potential / \({E^\Theta }\);</p>
<p class="p1">reduction of \({{\text{H}}_2}{\text{O/}}{{\text{H}}^ + }\) to \({{\text{H}}_2}\) has less negative electrode potential;</p>
<p class="p1">\({\text{M}}{{\text{g}}^{2 + }}\) not readily reduced (in comparison to \({{\text{H}}_2}{\text{O}}\));</p>
<p class="p1">if formed, magnesium would (immediately) react with water to form \({\text{M}}{{\text{g}}^{2 + }}\);</p>
<p class="p1">magnesium more reactive than hydrogen;</p>
<p class="p1"><em>Do not accept Mg too reactive.</em></p>
<div class="question_part_label">b.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p class="p1">(i) <span class="Apple-converted-space"> </span><em>I</em>:</p>
<p class="p1">atomization/sublimation (of Mg) / \(\Delta H_{{\text{atomization}}}^\Theta {\text{(Mg)}}\) / \(\Delta H_{{\text{sublimation}}}^\Theta {\text{(Mg)}}\);</p>
<p class="p1"><em>V</em>:</p>
<p class="p1">enthalpy change of formation of \({\text{(MgC}}{{\text{l}}_2}{\text{)}}\) / \(\Delta H_{{\text{formation}}}^\Theta {\text{(MgC}}{{\text{l}}_2}{\text{)}}\);</p>
<p class="p1">(ii) <span class="Apple-converted-space"> </span><em>Energy value for II</em>:</p>
<p class="p1">\( + 243\);</p>
<p class="p1"><em>Energy value for III</em>:</p>
<p class="p1">\(738 + 1451 = 2189\);</p>
<p class="p1"><em>Energy value for IV</em>:</p>
<p class="p1">\(2( - 349)\);</p>
<p class="p1">\(\Delta H_{{\text{lat}}}^\Theta {\text{(MgC}}{{\text{l}}_2}{\text{)}} = 642 + 148 + 243 + 2189 - 2(349) = ( - )2524{\text{ (kJ)}}\);</p>
<p class="p1">(iii) <span class="Apple-converted-space"> </span>theoretical value assumes ionic model;</p>
<p class="p1">experimental value greater due to (additional) covalent character;</p>
<p class="p1">(iv) <span class="Apple-converted-space"> </span>oxide greater charge;</p>
<p class="p1">oxide smaller radius;</p>
<p class="p1"><em>Accept opposite arguments</em>.</p>
<div class="question_part_label">c.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p class="p1">(i) <span class="Apple-converted-space"> </span>\({\text{MgC}}{{\text{l}}_2}\) (weakly) acidic <strong>and </strong>MgO alkaline;</p>
<p class="p1">(ii) <span class="Apple-converted-space"> </span>\({\text{MgO}} + {{\text{H}}_2}{\text{O}} \to {\text{Mg(OH}}{{\text{)}}_2}\);</p>
<p class="p1"><em>Ignore state symbols.</em></p>
<div class="question_part_label">d.</div>
</div>
<h2 style="margin-top: 1em">Examiners report</h2>
<div class="question" style="padding-left: 20px;">
<p class="p1">In (a) several candidates failed to mention atoms in their definition of first ionization energy and others neglected to state that the gaseous state is involved. Only the strongest students mentioned the electrostatic nature of the attraction between the nucleus and the electrons in explaining trends in ionisation energies. Several candidates lost a mark in explaining the increase between the tenth and eleventh ionisation energies as their arguments were incomplete, with no reference to the change from\(n = 2\) energy level to the\(n = 1\) level.</p>
<div class="question_part_label">a.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p class="p1">In (b) many candidates stated that free electrons rather than ions were responsible for the conductivity of magnesium chloride and others did not refer to the movement of both \({\text{M}}{{\text{g}}^{2 + }}\)<span class="s1"> </span>and \({\text{C}}{{\text{l}}^ - }\)<span class="s1"> </span>ions. The anode was generally identified as the electrode where oxidation occurs but some had difficulties giving the balanced equation for the half reaction. Only the strongest candidates were able to explain why magnesium is not formed during the electrolysis of aqueous solutions.</p>
<div class="question_part_label">b.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p class="p1">In (c) most candidates were familiar with the enthalpy changes of atomization and formation but some struggled with the Born Haber Cycle. Only the strongest candidates were able to relate differences in experimental and theoretical lattice energies to the covalent character of the solid with a significant number mistakenly giving “heat loss” as the reason for the difference.</p>
<div class="question_part_label">c.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p class="p1">In (d) many were able to correctly describe the basic nature of magnesium oxide but the acidity of magnesium chloride was less well known. Some gave hydrogen gas as a product in the reaction between magnesium oxide and water.</p>
<div class="question_part_label">d.</div>
</div>
<br><hr><br><div class="specification">
<p>Magnesium is a group 2 metal which exists as a number of isotopes and forms many compounds.</p>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Magnesium ions produce no emission or absorption lines in the visible region of the electromagnetic spectrum. Suggest why most magnesium compounds tested in a school laboratory show traces of yellow in the flame.</p>
<div class="marks">[1]</div>
<div class="question_part_label">c.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>(i) Explain the convergence of lines in a hydrogen emission spectrum.</p>
<p>(ii) State what can be determined from the frequency of the convergence limit.</p>
<div class="marks">[2]</div>
<div class="question_part_label">d.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Magnesium chloride can be electrolysed.</p>
<p>(i) Deduce the half-equations for the reactions at each electrode when <strong>molten</strong> magnesium chloride is electrolysed, showing the state symbols of the products. The melting points of magnesium and magnesium chloride are 922K and 987K respectively.</p>
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" alt></p>
<p>(ii) Identify the type of reaction occurring at the cathode (negative electrode).</p>
<p>(iii) State the products when a very <strong>dilute</strong> aqueous solution of magnesium chloride is electrolysed.</p>
<p><img 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" alt></p>
<div class="marks">[5]</div>
<div class="question_part_label">i.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Standard electrode potentials are measured relative to the standard hydrogen electrode. Describe a standard hydrogen electrode.</p>
<div class="marks">[2]</div>
<div class="question_part_label">j.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>A magnesium half-cell, Mg(s)/Mg<sup>2+</sup>(aq), can be connected to a copper half-cell, Cu(s)/Cu<sup>2+</sup>(aq).</p>
<p>(i) Formulate an equation for the spontaneous reaction that occurs when the circuit is completed.</p>
<p>(ii) Determine the standard cell potential, in V, for the cell. Refer to section 24 of the data booklet.</p>
<p>(iii) Predict, giving a reason, the change in cell potential when the concentration of copper ions increases.</p>
<div class="marks">[4]</div>
<div class="question_part_label">k.</div>
</div>
<h2 style="margin-top: 1em">Markscheme</h2>
<div class="question" style="padding-left: 20px;">
<p>contamination with sodium/other «compounds»</p>
<div class="question_part_label">c.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p>i<br>energy levels are closer together <span style="text-decoration: underline;">at high energy / high frequency / short wavelength</span></p>
<p> </p>
<p>ii<br>ionisation energy</p>
<div class="question_part_label">d.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p>i)</p>
<p><em>Anode (positive electrode):</em></p>
<p>2Cl<sup>–</sup> → Cl<sub>2</sub> (g) + 2e<sup>–</sup></p>
<p><em>Cathode (negative electrode):</em></p>
<p>Mg<sup>2+</sup> + 2e<sup>–</sup> → Mg (l)</p>
<p><em>Penalize missing/incorrect state symbols at Cl<sub>2</sub> and Mg once only.</em></p>
<p><em>Award <strong>[1 max]</strong> if equations are at wrong electrodes. </em></p>
<p><em>Accept Mg (g).</em></p>
<p> </p>
<p>ii)</p>
<p>reduction</p>
<p> </p>
<p>iii)</p>
<p><em>Anode (positive electrode):</em><br>oxygen/O<sub>2</sub><br><em><strong>OR</strong></em><br>hydogen ion/proton/H<sup>+</sup> <em><strong>AND</strong></em> oxygen/O<sub>2</sub><br><em>Cathode (negative electrode):</em><br>hydrogen/H<sub>2</sub><br><em><strong>OR</strong></em><br>hydroxide «ion»/OH<sup>–</sup> <em><strong>AND</strong></em> hydrogen/H<sub>2</sub></p>
<p><em>Award <strong>[1 max]</strong> if correct products given at wrong electrodes.</em></p>
<p> </p>
<div class="question_part_label">i.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p><em>Any two of:</em></p>
<p>«inert» Pt electrode<br><em><strong>OR</strong></em><br>platinum black conductor</p>
<p>1 mol dm<sup>–3</sup> H<sup>+ </sup>(aq)</p>
<p>H<sub>2</sub> (g) at 100 kPa</p>
<p><em>Accept 1 atm H<sub>2</sub> (g).</em><br><em>Accept 1 bar H<sub>2</sub> (g)</em><br><em>Accept a labelled diagram.</em><br><em>Ignore temperature if it is specified.</em></p>
<div class="question_part_label">j.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p>i</p>
<p>Mg(s) + Cu<sup>2+</sup> (aq) → Mg<sup>2+</sup> (aq) + Cu(s)</p>
<p> </p>
<p>ii</p>
<p>«+0.34V – (–2.37V) = +»2.71 «V»</p>
<p> </p>
<p>iii</p>
<p>cell potential increases</p>
<p>reaction «in Q4(k)(i)» moves to the right<br><em><strong>OR <br></strong></em>potential of the copper half-cell increases/becomes more positive</p>
<p><em>Accept correct answers based on the Nernst equation</em></p>
<div class="question_part_label">k.</div>
</div>
<h2 style="margin-top: 1em">Examiners report</h2>
<div class="question" style="padding-left: 20px;">
[N/A]
<div class="question_part_label">c.</div>
</div>
<div class="question" style="padding-left: 20px;">
[N/A]
<div class="question_part_label">d.</div>
</div>
<div class="question" style="padding-left: 20px;">
[N/A]
<div class="question_part_label">i.</div>
</div>
<div class="question" style="padding-left: 20px;">
[N/A]
<div class="question_part_label">j.</div>
</div>
<div class="question" style="padding-left: 20px;">
[N/A]
<div class="question_part_label">k.</div>
</div>
<br><hr><br><div class="specification">
<p>Titanium and vanadium are consecutive elements in the first transition metal series.</p>
</div>
<div class="specification">
<p>\({\text{TiC}}{{\text{l}}_{\text{4}}}\) reacts with water and the resulting titanium(IV) oxide can be used as a smoke screen.</p>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Describe the bonding in metals.</p>
<div class="marks">[2]</div>
<div class="question_part_label">a.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Titanium exists as several isotopes. The mass spectrum of a sample of titanium gave the following data:</p>
<p style="text-align: center;"><img src="images/Schermafbeelding_2017-09-20_om_08.37.43.png" alt="M17/4/CHEMI/HP2/ENG/TZ1/02.b"></p>
<p style="text-align: left;">Calculate the relative atomic mass of titanium to two decimal places.</p>
<div class="marks">[2]</div>
<div class="question_part_label">b.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>State the number of protons, neutrons and electrons in the \(_{{\text{22}}}^{{\text{48}}}{\text{Ti}}\) atom.</p>
<p><img src="images/Schermafbeelding_2017-09-20_om_08.43.58.png" alt="M17/4/CHEMI/HP2/ENG/TZ1/02.c"></p>
<div class="marks">[1]</div>
<div class="question_part_label">c.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>State the full electron configuration of the \(_{{\text{22}}}^{{\text{48}}}{\text{T}}{{\text{i}}^{2 + }}\) ion.</p>
<div class="marks">[1]</div>
<div class="question_part_label">d.i.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Suggest why the melting point of vanadium is higher than that of titanium.</p>
<div class="marks">[1]</div>
<div class="question_part_label">d.ii.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Sketch a graph of the first six successive ionization energies of vanadium on the axes provided.</p>
<p style="text-align: left;"><img src="images/Schermafbeelding_2017-09-20_om_09.09.57.png" alt="M17/4/CHEMI/HP2/ENG/TZ1/02.d.iii"></p>
<div class="marks">[1]</div>
<div class="question_part_label">d.iii.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Explain why an aluminium-titanium alloy is harder than pure aluminium.</p>
<div class="marks">[2]</div>
<div class="question_part_label">d.iv.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Describe, in terms of the electrons involved, how the bond between a ligand and a central metal ion is formed.</p>
<div class="marks">[1]</div>
<div class="question_part_label">e.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Outline why transition metals form coloured compounds.</p>
<div class="marks">[4]</div>
<div class="question_part_label">f.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>State the type of bonding in potassium chloride which melts at 1043 K.</p>
<div class="marks">[1]</div>
<div class="question_part_label">g.i.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>A chloride of titanium, \({\text{TiC}}{{\text{l}}_{\text{4}}}\), melts at 248 K. Suggest why the melting point is so much lower than that of KCl.</p>
<div class="marks">[1]</div>
<div class="question_part_label">g.ii.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Formulate an equation for this reaction.</p>
<div class="marks">[2]</div>
<div class="question_part_label">h.i.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Suggest one disadvantage of using this smoke in an enclosed space.</p>
<div class="marks">[1]</div>
<div class="question_part_label">h.ii.</div>
</div>
<h2 style="margin-top: 1em">Markscheme</h2>
<div class="question" style="padding-left: 20px;">
<p>electrostatic attraction</p>
<p>between <strong>«</strong>a lattice of<strong>» </strong>metal/positive ions/cations <strong><em>AND </em></strong><strong>«</strong>a sea of<strong>» </strong>delocalized electrons</p>
<p> </p>
<p><em>Accept “mobile electrons”.</em></p>
<p><em>Do </em><strong><em>not </em></strong><em>accept “metal atoms/nuclei”.</em></p>
<p><strong><em>[2 marks]</em></strong></p>
<div class="question_part_label">a.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p>\(\frac{{(46 \times 7.98){\text{ + }}(47 \times 7.32){\text{ + }}(48 \times 73.99){\text{ + }}(49 \times 5.46){\text{ + }}(50 \times 5.25)}}{{100}} = 47.93\)</p>
<p> </p>
<p><em>Answer must have two decimal places </em><em>with a value from 47.90 to 48.00.</em></p>
<p><em>Award [2] for correct final answer.</em></p>
<p><em>Award [0] for 47.87 (data booklet value).</em></p>
<p><strong><em>[2 marks]</em></strong></p>
<div class="question_part_label">b.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p><em>Protons: </em>22 <strong><em>AND </em></strong><em>Neutrons: </em>26 <strong><em>AND </em></strong><em>Electrons: </em>22</p>
<p><em><strong>[1 mark]</strong></em></p>
<div class="question_part_label">c.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p>\({\text{1}}{{\text{s}}^{\text{2}}}{\text{2}}{{\text{s}}^{\text{2}}}{\text{2}}{{\text{p}}^{\text{6}}}{\text{3}}{{\text{s}}^{\text{2}}}{\text{3}}{{\text{p}}^{\text{6}}}{\text{3}}{{\text{d}}^{\text{2}}}\)</p>
<p><em><strong>[1 mark]</strong></em></p>
<div class="question_part_label">d.i.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p>vanadium has smaller ionic radius «leading to stronger metallic bonding»</p>
<p> </p>
<p><em>Accept vanadium has «one» more valence electron«s» «leading to stronger metallic bonding».</em></p>
<p><em>Accept “atomic” for “ionic”.</em></p>
<p><strong><em>[1 mark]</em></strong></p>
<div class="question_part_label">d.ii.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p><img src="data:image/png;base64,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"></p>
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"></p>
<p>regular increase for first five <em><strong>AND</strong> </em>sharp increase to the 6th</p>
<p> </p>
<p><em>A log graph is acceptable.</em></p>
<p><em>Accept log plot on given axes (without amendment of y-axis).</em></p>
<p><em>Award mark if gradient of 5 to 6 is greater than “best fit line” of 1 to 5.</em></p>
<p><strong><em>[1 mark]</em></strong></p>
<div class="question_part_label">d.iii.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p>titanium atoms/ions distort the regular arrangement of atoms/ions</p>
<p><strong><em>OR</em></strong></p>
<p>titanium atoms/ions are a different size to aluminium <strong>«</strong>atoms/ions<strong>»</strong></p>
<p>prevent layers sliding over each other</p>
<p> </p>
<p><em>Accept diagram showing different sizes </em><em>of atoms/ions.</em></p>
<p><strong><em>[2 marks]</em></strong></p>
<div class="question_part_label">d.iv.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p>pair of electrons provided by the ligand</p>
<p> </p>
<p><em>Do not accept “dative” or “coordinate bonding” alone.</em></p>
<p><strong><em>[1 mark]</em></strong></p>
<div class="question_part_label">e.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p>partially filled d-orbitals</p>
<p>«ligands cause» d-orbitals «to» split</p>
<p>light is absorbed as electrons transit to a higher energy level «in d–d transitions»<br><em><strong>OR</strong></em><br>light is absorbed as electrons are promoted</p>
<p>energy gap corresponds to light in the visible region of the spectrum</p>
<p>colour observed is the complementary colour</p>
<p><em><strong>[4 marks]</strong></em></p>
<div class="question_part_label">f.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p>ionic</p>
<p><strong><em>OR</em></strong></p>
<p>«electrostatic» attraction between oppositely charged ions</p>
<p><em><strong>[1 mark]</strong></em></p>
<div class="question_part_label">g.i.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p>«simple» molecular structure</p>
<p><strong><em>OR</em></strong></p>
<p>weak«er» intermolecular bonds</p>
<p><strong><em>OR</em></strong></p>
<p>weak«er» bonds between molecules</p>
<p> </p>
<p><em>Accept specific examples of weak </em><em>bonds such as London/dispersion and </em><em>van der Waals.</em></p>
<p><em>Do </em><strong><em>not </em></strong><em>accept “covalent”.</em></p>
<p><strong><em>[1 mark]</em></strong></p>
<div class="question_part_label">g.ii.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p>\({\text{TiC}}{{\text{l}}_{\text{4}}}{\text{(l)}} + {\text{2}}{{\text{H}}_{\text{2}}}{\text{O(l)}} \to {\text{Ti}}{{\text{O}}_{\text{2}}}{\text{(s)}} + {\text{4HCl(aq)}}\) correct products<br>correct balancing</p>
<p> </p>
<p><em>Accept ionic equation.</em></p>
<p><em>Award M2 if products are HCl and a </em><em>compound of Ti and O.</em></p>
<p><strong><em>[2 marks]</em></strong></p>
<div class="question_part_label">h.i.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p>HCl causes breathing/respiratory problems</p>
<p><strong><em>OR</em></strong></p>
<p>HCl is an irritant</p>
<p><strong><em>OR</em></strong></p>
<p>HCl is toxic</p>
<p><strong><em>OR</em></strong></p>
<p>HCl has acidic vapour</p>
<p><strong><em>OR</em></strong></p>
<p>HCl is corrosive</p>
<p> </p>
<p><em>Accept TiO<sub>2</sub> causes breathing</em></p>
<p><em>problems/is an irritant.</em></p>
<p><em>Accept “harmful” for both HCl and TiO<sub>2</sub></em><em>.</em></p>
<p><em>Accept “smoke is asphyxiant”.</em></p>
<p><strong><em>[1 mark]</em></strong></p>
<div class="question_part_label">h.ii.</div>
</div>
<h2 style="margin-top: 1em">Examiners report</h2>
<div class="question" style="padding-left: 20px;">
[N/A]
<div class="question_part_label">a.</div>
</div>
<div class="question" style="padding-left: 20px;">
[N/A]
<div class="question_part_label">b.</div>
</div>
<div class="question" style="padding-left: 20px;">
[N/A]
<div class="question_part_label">c.</div>
</div>
<div class="question" style="padding-left: 20px;">
[N/A]
<div class="question_part_label">d.i.</div>
</div>
<div class="question" style="padding-left: 20px;">
[N/A]
<div class="question_part_label">d.ii.</div>
</div>
<div class="question" style="padding-left: 20px;">
[N/A]
<div class="question_part_label">d.iii.</div>
</div>
<div class="question" style="padding-left: 20px;">
[N/A]
<div class="question_part_label">d.iv.</div>
</div>
<div class="question" style="padding-left: 20px;">
[N/A]
<div class="question_part_label">e.</div>
</div>
<div class="question" style="padding-left: 20px;">
[N/A]
<div class="question_part_label">f.</div>
</div>
<div class="question" style="padding-left: 20px;">
[N/A]
<div class="question_part_label">g.i.</div>
</div>
<div class="question" style="padding-left: 20px;">
[N/A]
<div class="question_part_label">g.ii.</div>
</div>
<div class="question" style="padding-left: 20px;">
[N/A]
<div class="question_part_label">h.i.</div>
</div>
<div class="question" style="padding-left: 20px;">
[N/A]
<div class="question_part_label">h.ii.</div>
</div>
<br><hr><br><div class="specification">
<p>Tin(II) chloride is a white solid that is commonly used as a reducing agent.</p>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>(i) State why you would expect tin(II) chloride to have a similar lattice enthalpy to strontium chloride, using section 9 of the data booklet.</p>
<p>(ii) Calculate the molar enthalpy change when strontium chloride is dissolved in water, using sections 18 and 20 of the data booklet.</p>
<p>(iii) Tin(II) chloride reacts with water to precipitate the insoluble basic chloride, Sn(OH)Cl.</p>
<p><img 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" alt></p>
<p>Suggest why tin(II) chloride is usually dissolved in dilute hydrochloric acid.</p>
<div class="marks">[4]</div>
<div class="question_part_label">a.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Tin can also exist in the +4 oxidation state.</p>
<p><img 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" alt></p>
<p>Vanadium can be reduced from an oxidation state of +4 to +3 according to the equation:</p>
<p><img src="data:image/png;base64,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" alt></p>
<p>(i) Calculate the cell potential, <em>E</em><sup>Θ</sup>, and the standard free energy, Δ<em>G</em><sup>Θ</sup>, change for the reaction between the VO<sup>2+</sup> and Sn<sup>2+</sup> ions, using sections 1 and 2 of the data booklet.</p>
<p><em>E</em><sup>Θ</sup>:</p>
<p>Δ<em>G</em><sup>Θ</sup>:</p>
<p>(ii) Deduce, giving your reason, whether a reaction between Sn<sup>2+</sup>(aq) and VO<sup>2+</sup>(aq) would be spontaneous.</p>
<div class="marks">[3]</div>
<div class="question_part_label">b.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Outline, giving the <strong>full</strong> electron configuration of the vanadium atom, what is meant by the term transition metal.</p>
<div class="marks">[2]</div>
<div class="question_part_label">c.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>In an aqueous solution of vanadium(III) chloride, the vanadium exists as [V (H<sub>2</sub>O)<sub>6</sub>]<sup>3+</sup>, [VCl (H<sub>2</sub>O)<sub>5</sub>]<sup>2+</sup> or [VCl<sub>2</sub>(H<sub>2</sub>O)<sub>4</sub>]<sup>+</sup> depending on the concentration of chloride ions in the solution.</p>
<p>(i) Describe how Cl<sup>−</sup> and H<sub>2</sub>O bond to the vanadium ion.</p>
<p>(ii) Outline what would happen to the wavelength at which the vanadium complex ions would absorb light as the water molecules are gradually replaced by chloride ions, using section 15 of the data booklet.</p>
<div class="marks">[3]</div>
<div class="question_part_label">d.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Eight successive ionisation energies of vanadium are shown in the graph below:</p>
<p><img src="data:image/png;base64,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" alt></p>
<p>(i) State the sub-levels from which each of the first four electrons are lost.</p>
<p>First: Second: Third: Fourth: </p>
<p>(ii) Outline why there is an increase in ionization energy from electron 3 to electron 5.</p>
<p>(iii) Explain why there is a large increase in the ionization energy between electrons 5 and 6.</p>
<p>(iv) Vanadium is comprised almost entirely of <sup>51</sup>V. State the number of neutrons an atom of <sup>51</sup>V has in its nucleus.</p>
<div class="marks">[6]</div>
<div class="question_part_label">e.</div>
</div>
<h2 style="margin-top: 1em">Markscheme</h2>
<div class="question" style="padding-left: 20px;">
<p>(i)<br>same charge <em><strong>AND</strong></em> same/similar ionic radius</p>
<p>(ii)<br>enthalpy of hydration «= −1483 + 2 (−359)» = −2201 «kJmol<sup>−1</sup>»<br>enthalpy of solution <strong>«</strong>= 2170 − 2201<strong>»</strong> = −31 <strong>«</strong>kJmol<sup>−1</sup><strong>»</strong></p>
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<p><em>Award <strong>[2]</strong> for correct final answer.</em><br><em>Award <strong>[1 max]</strong> for +31 «kJmol<sup>−1</sup>».</em><br><em>Award <strong>[1 max]</strong> for ±4371.</em></p>
<p>(iii)<br>hydrochloric acid shifts equilibrium to left<br><em><strong>OR</strong></em><br>hydrochloric acid prevents the basic chloride forming/precipitating</p>
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<p><em>Accept “hydrochloric acid reacts with «basic» chloride” <strong>OR</strong> “hydrochloric acid suppresses salt hydrolysis”.</em></p>
<p> </p>
</div>
</div>
</div>
</div>
</div>
</div>
</div>
</div>
<div class="question_part_label">a.</div>
</div>
<div class="question" style="padding-left: 20px;">
<p>(i)</p>
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<p>E<sup>Θ </sup><strong>«</strong>= 0.34 − 0.15<strong>»</strong> = 0.19«V»<br> ∆GO<sup>Θ</sup>«= − nFE<sup>Θ</sup> = −2 × 96500 × 0.19<strong>»</strong> = −36670 / −37000«J» / − 37«kJ»</p>
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<p><em>Accept −18335 «J» or −18 «kJ» as equation not specified.</em></p>
</div>
</div>
</div>
</div>
<p>(ii) </p>
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<p>yes <em><strong>AND</strong></em> ∆G<sup>Θ</sup> is negative<br> <em><strong>OR</strong></em><br> yes <em><strong>AND</strong></em> E<sup>Θ</sup> for the cell is positive<br><em><strong>OR<br></strong></em>yes <em><strong>AND</strong></em> Sn<sup>2+</sup> (aq) is a stronger reducing agent than V<sup>3+</sup>(aq)<br><em><strong>OR</strong></em><br>yes <em><strong>AND</strong></em> E<sup>Θ </sup>SN<sup>4+ </sup>(aq) is more negative that<sup> </sup>E<sup>Θ</sup> or VO<sup>2+</sup> (aq)<br><em><strong>OR</strong></em><br>yes <em><strong>AND</strong></em> VO<sup>2+</sup> (aq) is a stronger oxidizing agent than Sn<sup>4+</sup> (aq)<br><em><strong>OR</strong></em><br>yes <em><strong>AND</strong></em> E<sup>Θ</sup> for VO<sup>2+</sup> (aq) is more positive than E<sup>Θ</sup> for SN<sup>4+</sup> (aq)</p>
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<p><em>Do <strong>not</strong> accept reference to anti-clockwise rule.</em></p>
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<div class="question_part_label">b.</div>
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<p>1s<sup>2</sup>2s<sup>2</sup>2p<sup>6</sup>3s<sup>2</sup>3p<sup>6</sup>3d<sup>3</sup>4s<sup>2</sup><br><em><strong>OR</strong></em><br>1s<sup>2</sup>2s<sup>2</sup>2p<sup>6</sup>3s<sup>2</sup>3p<sup>6</sup>4s<sup>2</sup>3d<sup>3</sup> </p>
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<p>incomplete d <strong>«</strong>sub-<strong>»</strong> level/orbital/shell <strong>«</strong>in its compounds/ions<strong>»</strong></p>
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<div class="question_part_label">c.</div>
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<p>(i)<br>give/donate a lone/non-bonding electron pair</p>
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<p><em>Accept “through the formation of a dative/ coordinate bond”.</em><br><em> Accept “by acting as Lewis bases”.</em><br><em> Do not accept “act as ligands”.</em></p>
<p>(ii)<br>«more chlorido ligands» smaller energy gap between split d-orbitals<br><em><strong>OR</strong></em><br>Cl<sup>−</sup> is lower than H<sub>2</sub>O in spectrochemical series <br><em><strong>OR</strong></em><br>Cl<sup>−</sup> is a weaker ligand/has lower charge density</p>
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<p>the absorption will move to longer wavelengths<br><em><strong>OR</strong></em><br>the absorption wavelength will increase</p>
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<p><em>Do not accept answers in terms of change of frequency.</em></p>
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<p>(i)<br><em>First:</em> 4s <em><strong>AND</strong></em> <em>Second:</em> 4s <em><strong>AND</strong></em> <em>Third:</em> 3d <em><strong>AND</strong></em> <em>Fourth:</em> 3d</p>
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<p><em>Do <strong>not</strong> apply <strong>ECF</strong> from (c).</em></p>
<p>(ii)<br><strong>«</strong>in the same sub-shell and a<strong>»</strong> decrease in electron-electron repulsion<br><em><strong>OR</strong></em><br><strong>«</strong>in the same sub-shell and<strong>»</strong> as more electrons removed, the pull of of the nucleus/positive ions holds the remaining electrons more tightly</p>
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<p><em>Do <strong>not</strong> accept “greater nuclear charge/ effective nuclear charge”.</em></p>
<p>(iii)<br>electron 5 is lost from the 3d orbital<br><em><strong>OR</strong></em><br>electron 5 is lost from the valence shell</p>
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<p>electron 6 is lost from a 3p orbital<br><em><strong>OR</strong></em><br>electron 6 is lost from a <strong>«</strong>complete<strong>»</strong> inner shell</p>
<p>3p orbital/complete inner shell experiences a much larger effective nuclear charge<br> <em><strong>OR</strong></em><br> 3p orbital/complete inner shell is less well shielded<br><em><strong>OR<br></strong></em>3p orbital/complete inner shell is nearer the nucleus</p>
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<p><em>Award <strong>[1 max]</strong> (for M1/M2) (<strong>ECF</strong>) if candidate recognises electrons 5 and 6 are from different levels.</em></p>
<p>(iv)<br>28</p>
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<div class="question_part_label">e.</div>
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<h2 style="margin-top: 1em">Examiners report</h2>
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[N/A]
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[N/A]
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[N/A]
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[N/A]
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[N/A]
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