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</div><h2>SL Paper 2</h2><div class="specification">
<p class="p1">An example of a homogeneous reversible reaction is the reaction between hydrogen and iodine.</p>
<p class="p1">\[{{\text{H}}_{\text{2}}}{\text{(g)}} + {{\text{I}}_{\text{2}}}{\text{(g)}} \rightleftharpoons {\text{2HI(g)}}\]</p>
</div>
<div class="specification">
<p class="p1">Propane can be formed by the hydrogenation of propene.</p>
<p class="p2">\[{\text{C}}{{\text{H}}_3}{\text{CH=C}}{{\text{H}}_2}{\text{(g)}} + {{\text{H}}_2}{\text{(g)}} \to {\text{C}}{{\text{H}}_3}{\text{C}}{{\text{H}}_2}{\text{C}}{{\text{H}}_3}{\text{(g)}}\]</p>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">Outline the characteristics of a homogeneous chemical system that is in a state of equilibrium.</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 class="p1">Deduce the expression for the equilibrium constant, \({K_{\text{c}}}\).</p>
<div class="marks">[1]</div>
<div class="question_part_label">a.ii.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">Predict what would happen to the position of equilibrium and the value of \({K_{\text{c}}}\) if the pressure is increased from 1 atm to 2 atm.</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">The value of \({K_{\text{c}}}\) at 500 K is 160 and the value of \({K_{\text{c}}}\) at 700 K is 54. Deduce what this information tells us about the enthalpy change of the forward reaction.</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 class="p1">The reaction can be catalysed by adding platinum metal. State and explain what effect the addition of platinum would have on the value of the equilibrium constant.</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">State the conditions necessary for the hydrogenation reaction to occur.</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">Enthalpy changes can be determined using average bond enthalpies. Define the term <em>average bond enthalpy</em>.</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">Determine a value for the hydrogenation of propene using information from Table 10 of the Data Booklet.</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">Explain why the enthalpy of hydrogenation of propene is an exothermic process.</p>
<div class="marks">[1]</div>
<div class="question_part_label">b.iv.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">Describe a chemical test that could be used to distinguish between propane and propene. In <strong>each </strong>case state the result of the test.</p>
<div class="marks">[2]</div>
<div class="question_part_label">c.i.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">Under certain conditions propene can polymerize to form poly(propene). State the type of polymerization taking place and draw a section of the polymer to represent the repeating unit.</p>
<div class="marks">[2]</div>
<div class="question_part_label">c.ii.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">Other than polymerization, state <strong>one </strong>reaction of alkenes which is of economic importance.</p>
<div class="marks">[1]</div>
<div class="question_part_label">c.iii.</div>
</div>
<br><hr><br><div class="specification">
<p class="p1">Factors that affect the rate of a chemical reaction include particle size, concentration of reactants and the temperature of the reaction.</p>
</div>
<div class="specification">
<p class="p1">Propan-1-ol and propan-2-ol are two structural isomers of \({{\text{C}}_{\text{3}}}{{\text{H}}_{\text{8}}}{\text{O}}\).</p>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">Define the term <em>rate of a chemical reaction</em>.</p>
<div class="marks">[1]</div>
<div class="question_part_label">a.i.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">List the <strong>three </strong>characteristic properties of reactant particles which affect the rate of reaction as described by the collision theory.</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 class="p1">On the axes below sketch <strong>two </strong>Maxwell-Boltzmann energy distribution curves for the same sample of gas, one at a temperature \(T\) and another at a higher temperature \(T'\). Label both axes. Explain why raising the temperature increases the rate of a chemical reaction.</p>
<p class="p1" style="text-align: center;"><img src="images/Schermafbeelding_2016-10-30_om_10.42.58.png" alt="M11/4/CHEMI/SP2/ENG/TZ2/07.a.iii"></p>
<div class="marks">[5]</div>
<div class="question_part_label">a.iii.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">Explain why coal dust burns much faster than a large piece of coal with the same mass.</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 class="p1">State the equation for the complete combustion of \({{\text{C}}_{\text{3}}}{{\text{H}}_{\text{8}}}{\text{O}}\).</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">Both propan-1-ol and propan-2-ol can be oxidized in aqueous solution by potassium dichromate(VI). State any necessary conditions for the oxidation to occur and describe the colour change during the oxidation process.</p>
<div class="marks">[3]</div>
<div class="question_part_label">b.ii.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">State the name(s) and structure(s) of the organic product(s) that can be formed when each of the alcohols is oxidized and suggest why one of the alcohols gives two organic products and the other only gives one organic product.</p>
<div class="marks">[5]</div>
<div class="question_part_label">b.iii.</div>
</div>
<br><hr><br><div class="specification">
<p class="p1">Consider the following reaction taking place at 375 °C in a \({\text{1.00 d}}{{\text{m}}^{\text{3}}}\) closed container.</p>
<p class="p1">\[\begin{array}{*{20}{l}} {{\text{C}}{{\text{l}}_{\text{2}}}{\text{(g)}} + {\text{S}}{{\text{O}}_{\text{2}}}{\text{(g)}} \rightleftharpoons {\text{S}}{{\text{O}}_{\text{2}}}{\text{C}}{{\text{l}}_{\text{2}}}{\text{(g)}}}&{\Delta {H^\Theta } = - 84.5{\text{ kJ}}} \end{array}\]</p>
</div>
<div class="specification">
<p class="p1">A solution of hydrogen peroxide, \({{\text{H}}_{\text{2}}}{{\text{O}}_{\text{2}}}\), is added to a solution of sodium iodide, NaI, acidified with hydrochloric acid, HCl. The yellow colour of the iodine, \({{\text{I}}_{\text{2}}}\), can be used to determine the rate of reaction.</p>
<p class="p1">\[{{\text{H}}_2}{{\text{O}}_2}{\text{(aq)}} + {\text{2NaI(aq)}} + {\text{2HCl(aq)}} \to {\text{2NaCl(aq)}} + {{\text{I}}_2}{\text{(aq)}} + {\text{2}}{{\text{H}}_2}{\text{O(l)}}\]</p>
<p class="p1">The experiment is repeated with some changes to the reaction conditions. For each of the changes that follow, predict, stating a reason, its effect on the rate of reaction.</p>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">Deduce the equilibrium constant expression, \({K_{\text{c}}}\), for the reaction.</p>
<div class="marks">[1]</div>
<div class="question_part_label">a.i.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">If the temperature of the reaction is changed to 300 °C, predict, stating a reason in each case, whether the equilibrium concentration of \({\text{S}}{{\text{O}}_{\text{2}}}{\text{C}}{{\text{l}}_{\text{2}}}\) and the value of \({K_{\text{c}}}\) will increase or decrease.</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 class="p1">If the volume of the container is changed to \({\text{1.50 d}}{{\text{m}}^{\text{3}}}\), predict, stating a reason in each case, how this will affect the equilibrium concentration of \({\text{S}}{{\text{O}}_{\text{2}}}{\text{C}}{{\text{l}}_{\text{2}}}\) and the value of \({K_{\text{c}}}\).</p>
<div class="marks">[3]</div>
<div class="question_part_label">a.iii.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">Suggest, stating a reason, how the addition of a catalyst at constant pressure and temperature will affect the equilibrium concentration of \({\text{S}}{{\text{O}}_{\text{2}}}{\text{C}}{{\text{l}}_{\text{2}}}\).</p>
<div class="marks">[2]</div>
<div class="question_part_label">a.iv.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">Graphing is an important method in the study of the rates of chemical reaction. Sketch a graph to show how the reactant concentration changes with time in a typical chemical reaction taking place in solution. Show how the rate of the reaction at a particular time can be determined.</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 class="p1">The concentration of \({{\text{H}}_{\text{2}}}{{\text{O}}_{\text{2}}}\) is increased at constant temperature.</p>
<div class="marks">[2]</div>
<div class="question_part_label">c.i.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">The solution of NaI is prepared from a fine powder instead of large crystals.</p>
<div class="marks">[2]</div>
<div class="question_part_label">c.ii.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">Explain why the rate of a reaction increases when the temperature of the system increases.</p>
<div class="marks">[3]</div>
<div class="question_part_label">d.</div>
</div>
<br><hr><br><div class="specification">
<p class="p1">Ethene belongs to the homologous series of the alkenes.</p>
</div>
<div class="specification">
<p class="p1">A bromoalkane, \({{\text{C}}_{\text{4}}}{{\text{H}}_{\text{9}}}{\text{Br}}\), reacts with a warm, aqueous sodium hydroxide solution, NaOH.</p>
</div>
<div class="specification">
<p class="p1">The time taken to produce a certain amount of product using different initial concentrations of \({{\text{C}}_{\text{4}}}{{\text{H}}_{\text{9}}}{\text{Br}}\) and NaOH is measured. The results are shown in the following table.</p>
<p class="p1" style="text-align: center;"><img src="images/Schermafbeelding_2016-09-14_om_16.46.57.png" alt="M13/4/CHEMI/SP2/ENG/TZ1/08.c"></p>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">Outline <strong>three </strong>features of a homologous series.</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">Describe a test to distinguish ethene from ethane, including what is observed in <strong>each </strong>case.</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">Bromoethane can be produced either from ethene or from ethane. State an equation for <strong>each </strong>reaction.</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">State the equation for the reaction of \({{\text{C}}_{\text{4}}}{{\text{H}}_{\text{9}}}{\text{Br}}\) with NaOH.</p>
<div class="marks">[1]</div>
<div class="question_part_label">b.i.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">Suggest what would happen to the pH of the solution as the reaction proceeds.</p>
<div class="marks">[1]</div>
<div class="question_part_label">b.ii.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">Deduce the effect of the concentration of \({{\text{C}}_{\text{4}}}{{\text{H}}_{\text{9}}}{\text{Br}}\) and NaOH on the rate of reaction.</p>
<p class="p2"> </p>
<p class="p1">C<sub><span class="s1">4</span></sub>H<sub><span class="s1">9</span></sub>Br:</p>
<p class="p2"> </p>
<p class="p2"> </p>
<p class="p1">NaOH:</p>
<div class="marks">[2]</div>
<div class="question_part_label">c.i.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">Suggest why <strong>warm </strong>sodium hydroxide solution is used.</p>
<div class="marks">[1]</div>
<div class="question_part_label">c.ii.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">Deduce whether C<sub><span class="s1">4</span></sub>H<sub><span class="s1">9</span></sub>Br is a primary or tertiary halogenoalkane.</p>
<div class="marks">[2]</div>
<div class="question_part_label">c.iii.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">Determine the structural formula of C<sub><span class="s1">4</span></sub>H<sub><span class="s1">9</span></sub>Br.</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 class="p1">Describe, using an equation, how \({{\text{C}}_{\text{4}}}{{\text{H}}_{\text{9}}}{\text{Br}}\) can be converted into \({{\text{C}}_{\text{4}}}{{\text{H}}_{\text{8}}}{\text{B}}{{\text{r}}_{\text{2}}}\).</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 class="p1">Explain the mechanism for the reaction in (c) of \({{\text{C}}_{\text{4}}}{{\text{H}}_{\text{9}}}{\text{Br}}\) with NaOH, using curly arrows to represent the movement of electron pairs.</p>
<div class="marks">[4]</div>
<div class="question_part_label">d.</div>
</div>
<br><hr><br><div class="specification">
<p>A class studied the equilibrium established when ethanoic acid and ethanol react together in the presence of a strong acid, using propanone as an inert solvent. The equation is given below.</p>
<p>\[{\text{C}}{{\text{H}}_{\text{3}}}{\text{COOH}} + {{\text{C}}_{\text{2}}}{{\text{H}}_{\text{5}}}{\text{OH}} \rightleftharpoons {\text{C}}{{\text{H}}_{\text{3}}}{\text{COO}}{{\text{C}}_{\text{2}}}{{\text{H}}_{\text{5}}} + {{\text{H}}_{\text{2}}}{\text{O}}\]</p>
<p>One group made the following <strong>initial mixture</strong>:</p>
<p style="text-align: center;"><img src="images/Schermafbeelding_2016-08-17_om_07.42.39.png" alt="M14/4/CHEMI/SP2/ENG/TZ2/01"></p>
</div>
<div class="specification">
<p>After one week, a \(5.00 \pm 0.05{\text{ c}}{{\text{m}}^{\text{3}}}\) sample of the final equilibrium mixture was pipetted out and titrated with \({\text{0.200 mol}}\,{\text{d}}{{\text{m}}^{ - 2}}\) aqueous sodium hydroxide to determine the amount of ethanoic acid remaining. The following titration results were obtained:</p>
<p style="text-align: center;"><img src="images/Schermafbeelding_2016-08-17_om_07.59.45.png" alt="M14/4/CHEMI/SP2/ENG/TZ2/01.d"></p>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>The density of ethanoic acid is \({\text{1.05 g}}\,{\text{c}}{{\text{m}}^{ - 3}}\). Determine the amount, in mol, of ethanoic acid present in the initial mixture.</p>
<div class="marks">[3]</div>
<div class="question_part_label">a.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>The hydrochloric acid does not appear in the balanced equation for the reaction. State its function.</p>
<div class="marks">[1]</div>
<div class="question_part_label">b.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Identify the liquid whose volume has the greatest percentage uncertainty.</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) Calculate the absolute uncertainty of the titre for Titration 1 (\({\text{27.60 c}}{{\text{m}}^{\text{3}}}\)).</p>
<p> </p>
<p>(ii) Suggest the average volume of alkali, required to neutralize the \({\text{5.00 c}}{{\text{m}}^{\text{3}}}\) sample, that the student should use.</p>
<p> </p>
<p> </p>
<p>(iii) \({\text{23.00 c}}{{\text{m}}^{\text{3}}}\) of this \({\text{0.200 mol}}\,{\text{d}}{{\text{m}}^{ - 3}}\) aqueous sodium hydroxide reacted with the ethanoic acid in the \({\text{5.00 c}}{{\text{m}}^{\text{3}}}\) sample. Determine the amount, in mol, of ethanoic acid present in the \({\text{50.0 c}}{{\text{m}}^{\text{3}}}\) of final equilibrium mixture.</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>Referring back to your answer for part (a), calculate the percentage of ethanoic acid converted to ethyl ethanoate.</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>Deduce the equilibrium constant expression for the reaction.</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>Outline how you could establish that the system had reached equilibrium at the end of one week.</p>
<div class="marks">[1]</div>
<div class="question_part_label">g.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Outline why changing the temperature has only a very small effect on the value of the equilibrium constant for this equilibrium.</p>
<div class="marks">[1]</div>
<div class="question_part_label">h.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Outline how adding some ethyl ethanoate to the initial mixture would affect the amount of ethanoic acid converted to product.</p>
<div class="marks">[2]</div>
<div class="question_part_label">i.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Propanone is used as the solvent because one compound involved in the equilibrium is insoluble in water. Identify this compound and explain why it is insoluble in water.</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>Suggest <strong>one</strong> other reason why using water as a solvent would make the experiment less successful.</p>
<div class="marks">[1]</div>
<div class="question_part_label">k.</div>
</div>
<br><hr><br><div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>The standard enthalpy change of three combustion reactions are given below.</p>
<p>\[\begin{array}{*{20}{l}} {{{\text{H}}_2}{\text{(g)}} + \frac{1}{2}{{\text{O}}_2}{\text{(g)}} \to {{\text{H}}_2}{\text{O(l)}}}&{\Delta H = - 286{\text{ kJ}}\,{\text{mo}}{{\text{l}}^{ - 1}}} \\ {{{\text{C}}_3}{{\text{H}}_8}{\text{(g)}} + {\text{5}}{{\text{O}}_2}{\text{(g)}} \to {\text{3C}}{{\text{O}}_2}{\text{(g)}} + {\text{4}}{{\text{H}}_2}{\text{O(l)}}}&{\Delta H = - 2219{\text{ kJ}}\,{\text{mo}}{{\text{l}}^{ - 1}}} \\ {{\text{C(s)}} + {{\text{O}}_2}{\text{(g)}} \to {\text{C}}{{\text{O}}_2}{\text{(g)}}}&{\Delta H = - 394{\text{ kJ}}\,{\text{mo}}{{\text{l}}^{ - 1}}} \end{array}\]</p>
<p>Determine the change in enthalpy, \(\Delta H\), in \({\text{kJ}}\,{\text{mo}}{{\text{l}}^{ - 1}}\), for the formation of propane in the following reaction.</p>
<p>\({\text{3C(s)}} + {\text{4}}{{\text{H}}_2}{\text{(g)}} \to {{\text{C}}_3}{{\text{H}}_8}{\text{(g)}}\)</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 class="p1">A catalyst provides an alternative pathway for a reaction, lowering the activation energy, \({E_{\text{a}}}\). Define the term <em>activation energy</em>, \({E_{\text{a}}}\).</p>
<div class="marks">[1]</div>
<div class="question_part_label">b.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">Sketch <strong>two </strong>Maxwell–Boltzmann energy distribution curves for a fixed amount of gas at two different temperatures, \({T_{\text{1}}}\) and \({T_2}{\text{ }}({T_2} > {T_1})\) and label <strong>both </strong>axes.</p>
<p class="p1" style="text-align: center;"><img src="images/Schermafbeelding_2016-09-19_om_05.17.47.png" alt="M13/4/CHEMI/SP2/ENG/TZ2/02.c"></p>
<div class="marks">[3]</div>
<div class="question_part_label">c.</div>
</div>
<br><hr><br><div class="specification">
<p>A group of students investigated the rate of the reaction between aqueous sodium thiosulfate and hydrochloric acid according to the equation below.</p>
<p>\[{\text{N}}{{\text{a}}_2}{{\text{S}}_2}{{\text{O}}_3}{\text{(aq)}} + {\text{2HCl(aq)}} \to {\text{2NaCl(aq)}} + {\text{S}}{{\text{O}}_2}{\text{(g)}} + {\text{S(s)}} + {{\text{H}}_2}{\text{O(l)}}\]</p>
<p>The two reagents were rapidly mixed together in a beaker and placed over a mark on a piece of paper. The time taken for the precipitate of sulfur to obscure the mark when viewed through the reaction mixture was recorded.</p>
<p style="text-align: center;"><img src="images/Schermafbeelding_2016-08-17_om_14.58.16.png" alt="M14/4/CHEMI/SP2/ENG/TZ2/05"></p>
<p>Initially they measured out \({\text{10.0 c}}{{\text{m}}^{\text{3}}}\) of \({\text{0.500 mol}}\,{\text{d}}{{\text{m}}^{ - 3}}\) hydrochloric acid and then added \({\text{40.0 c}}{{\text{m}}^{\text{3}}}\) of \({\text{0.0200 mol}}\,{\text{d}}{{\text{m}}^{ - 3}}\) aqueous sodium thiosulfate. The mark on the paper was obscured 47 seconds after the solutions were mixed.</p>
</div>
<div class="specification">
<p>The teacher asked the students to measure the effect of halving the concentration of sodium thiosulfate on the rate of reaction.</p>
</div>
<div class="specification">
<p>The teacher asked the students to devise another technique to measure the rate of this reaction.</p>
</div>
<div class="specification">
<p>Another group suggested collecting the sulfur dioxide and drawing a graph of the volume of gas against time.</p>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>The teacher made up \({\text{2.50 d}}{{\text{m}}^{\text{3}}}\) of the sodium thiosulfate solution using sodium thiosulfate pentahydrate crystals, \({\text{N}}{{\text{a}}_2}{{\text{S}}_{\text{2}}}{{\text{O}}_{\text{3}}} \bullet {\text{5}}{{\text{H}}_{\text{2}}}{\text{O}}\). Calculate the required mass of these crystals.</p>
<div class="marks">[3]</div>
<div class="question_part_label">a.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>(i) State the volumes of the liquids that should be mixed.</p>
<p><img src="images/Schermafbeelding_2016-08-17_om_15.16.17.png" alt="M14/4/CHEMI/SP2/ENG/TZ2/05.b.i"></p>
<p>(ii) State why it is important that the students use a similar beaker for both reactions.</p>
<p> </p>
<p> </p>
<p>(iii) Explain, in terms of the collision theory, how decreasing the concentration of sodium thiosulfate would affect the time taken for the mark to be obscured.</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) Sketch and label, indicating an approximate activation energy, the Maxwell–Boltzmann energy distribution curves for two temperatures, \({T_1}\) and \({T_2}{\text{ }}({T_2} > {T_1})\), at which the rate of reaction would be significantly different.</p>
<p style="text-align: center;"><img src="images/Schermafbeelding_2016-08-17_om_15.24.40.png" alt="M14/4/CHEMI/SP2/ENG/TZ2/05.c.i"></p>
<p>(ii) Explain why increasing the temperature of the reaction mixture would significantly increase the rate of the reaction.</p>
<div class="marks">[6]</div>
<div class="question_part_label">c.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>(i) One group suggested recording how long it takes for the pH of the solution to change by one unit. Calculate the initial pH of the original reaction mixture.</p>
<p> </p>
<p> </p>
<p> </p>
<p> </p>
<p>(ii) Deduce the percentage of hydrochloric acid that would have to be used up for the pH to change by one unit.</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>(i) Calculate the volume of sulfur dioxide, in \({\text{c}}{{\text{m}}^{\text{3}}}\), that the original reaction mixture would produce if it were collected at \(1.00 \times {10^5}{\text{ Pa}}\) and 300 K.</p>
<p> </p>
<p> </p>
<p> </p>
<p> </p>
<p> </p>
<p> </p>
<p>(ii) Suggest why it is better to use a gas syringe rather than collecting the gas in a measuring cylinder over water.</p>
<div class="marks">[4]</div>
<div class="question_part_label">e.</div>
</div>
<br><hr><br><div class="specification">
<p class="p1">Water is an important substance that is abundant on the Earth’s surface. Water dissociates according to the following equation.</p>
<p class="p1">\[{{\text{H}}_{\text{2}}}{\text{O(l)}} \rightleftharpoons {{\text{H}}^ + }{\text{(aq)}} + {\text{O}}{{\text{H}}^ - }{\text{(aq)}}\]</p>
</div>
<div class="specification">
<p class="p1">The graph below shows how the volume of carbon dioxide formed varies with time when a hydrochloric acid solution is added to <strong>excess </strong>calcium carbonate in a flask.</p>
<p class="p1" style="text-align: center;"><img src="images/Schermafbeelding_2016-10-12_om_11.58.17.png" alt="M10/4/CHEMI/SP2/ENG/TZ2/06.c"></p>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">(i) <span class="Apple-converted-space"> </span>State the equilibrium constant expression for the dissociation of water.</p>
<p class="p1">(ii) <span class="Apple-converted-space"> </span>Explain why even a very acidic aqueous solution still has some \({\text{O}}{{\text{H}}^ - }\) ions present in it.</p>
<p class="p1">(iii) <span class="Apple-converted-space"> </span>State and explain the effect of increasing temperature on the equilibrium constant above given that the dissociation of water is an endothermic process.</p>
<p class="p1">(iv) <span class="Apple-converted-space"> </span>The pH of a solution is 2. If its pH is increased to 6, deduce how the hydrogen ion concentration changes.</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 class="p1">In carbonated drinks containing dissolved carbon dioxide under high pressure, the</p>
<p class="p1">following dynamic equilibrium exists.</p>
<p class="p1">\[{\text{C}}{{\text{O}}_2}({\text{aq)}} \rightleftharpoons {\text{C}}{{\text{O}}_2}({\text{g)}}\]</p>
<p class="p1">Describe the effect of opening a carbonated drink container and outline how this</p>
<p class="p1">equilibrium is affected.</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">(i) Explain the shape of the curve.</p>
<p class="p1">(ii) Copy the above graph on your answer sheet and sketch the curve you would obtain if <strong>double </strong>the volume of hydrochloric acid solution of <strong>half </strong>the concentration as in the example above is used instead, with all other variables kept constant from the original. Explain why the shape of the curve is different.</p>
<p class="p1">(iii) Outline <strong>one </strong>other way in which the rate of this reaction can be studied in a school laboratory. Sketch a graph to illustrate how the selected variable would change with time.</p>
<p class="p1">(iv) Define the term <em>activation energy </em>and state <strong>one </strong>reason why the reaction between calcium carbonate and hydrochloric acid takes place at a reasonably fast rate at room temperature.</p>
<div class="marks">[11]</div>
<div class="question_part_label">c.</div>
</div>
<br><hr><br><div class="specification">
<p class="p1">Alex and Hannah were asked to investigate the kinetics involved in the iodination of propanone. They were given the following equation by their teacher.</p>
<p class="p1">\[{\text{C}}{{\text{H}}_3}{\text{COC}}{{\text{H}}_3}{\text{(aq)}} + {{\text{I}}_2}{\text{(aq)}}\xrightarrow{{{{\text{H}}^ + }{\text{(aq)}}}}{\text{C}}{{\text{H}}_2}{\text{ICOC}}{{\text{H}}_3}{\text{(aq)}} + {\text{HI(aq)}}\]</p>
<p class="p1">Alex’s hypothesis was that the rate will be affected by changing the concentrations of the propanone and the iodine, as the reaction can happen without a catalyst. Hannah’s hypothesis was that as the catalyst is involved in the reaction, the concentrations of the propanone, iodine and the hydrogen ions will all affect the rate.</p>
<p class="p1">They carried out several experiments varying the concentration of one of the reactants or the catalyst whilst keeping other concentrations and conditions the same. Their results are shown graphically below.</p>
<p class="p1" style="text-align: right;"><img src="images/Schermafbeelding_2016-10-07_om_09.24.10.png" alt="M10/4/CHEMI/SP2/ENG/TZ1/02"></p>
</div>
<div class="question">
<p class="p1">(a) Discuss whether either Alex’s or Hannah’s hypothesis is correct.</p>
<p class="p1">(b) Explain why the reaction rate will increase with increasing temperature.</p>
<p class="p1">(c) (i) This reaction uses a catalyst. Sketch and annotate the Maxwell-Boltzmann energy distribution curve for a reaction with and without a catalyst on labelled axes below.</p>
<p class="p1">(ii) Describe how a catalyst works.</p>
</div>
<br><hr><br><div class="specification">
<p>Calcium carbonate reacts with hydrochloric acid.</p>
<p style="text-align: center;">CaCO<sub>3</sub>(s) + 2HCl(aq) → CaCl<sub>2</sub>(aq) + H<sub>2</sub>O(l) + CO<sub>2</sub>(g)</p>
</div>
<div class="specification">
<p>The results of a series of experiments in which the concentration of HCl was varied are shown below.</p>
<p style="text-align: center;"><img src="images/Schermafbeelding_2018-08-09_om_13.37.39.png" alt="M18/4/CHEMI/SP2/ENG/TZ1/04.b"></p>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Outline <strong>two </strong>ways in which the progress of the reaction can be monitored. No practical details are required.</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>Suggest why point D is so far out of line assuming human error is not the cause.</p>
<div class="marks">[1]</div>
<div class="question_part_label">b.i.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Suggest the relationship that points A, B and C show between the concentration of the acid and the rate of reaction.</p>
<div class="marks">[1]</div>
<div class="question_part_label">b.ii.</div>
</div>
<br><hr><br><div class="specification">
<p class="p1">Airbags are an important safety feature in vehicles. Sodium azide, potassium nitrate and silicon dioxide have been used in one design of airbag.</p>
<p class="p1" style="text-align: center;"><img src="images/Schermafbeelding_2016-11-03_om_14.35.39.png" alt="N11/4/CHEMI/SP2/ENG/TZ0/01"></p>
<p class="p1">Sodium azide, a toxic compound, undergoes the following decomposition reaction under certain conditions.</p>
<p class="p1">\[{\text{2Na}}{{\text{N}}_{\text{3}}}{\text{(s)}} \to {\text{2Na(s)}} + {\text{3}}{{\text{N}}_{\text{2}}}{\text{(g)}}\]</p>
<p class="p1">Two students looked at data in a simulated computer-based experiment to determine the volume of nitrogen generated in an airbag.</p>
</div>
<div class="specification">
<p class="p1">Using the simulation programme, the students entered the following data into the computer.</p>
<p class="p1" style="text-align: center;"><img src="images/Schermafbeelding_2016-11-03_om_15.10.05.png" alt="N11/4/CHEMI/SP2/ENG/TZ0/01.b"></p>
</div>
<div class="specification">
<p class="p1">The chemistry of the airbag was found to involve three reactions. The first reaction involves the decomposition of sodium azide to form sodium and nitrogen. In the second reaction, potassium nitrate reacts with sodium.</p>
<p class="p1">\[{\text{2KN}}{{\text{O}}_3}{\text{(s)}} + {\text{10Na(s)}} \to {{\text{K}}_2}{\text{O(s)}} + {\text{5N}}{{\text{a}}_2}{\text{O(s)}} + {{\text{N}}_2}{\text{(g)}}\]</p>
</div>
<div class="specification">
<p class="p1">An airbag inflates very quickly.</p>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">Sodium azide involves ionic bonding, and metallic bonding is present in sodium. Describe ionic and metallic bonding.</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 class="p1">State the number of significant figures for the temperature, mass and pressure data.</p>
<p class="p1"><em>T</em>:</p>
<p class="p1"><em>m</em>:</p>
<p class="p1"><em>p</em>:</p>
<div class="marks">[1]</div>
<div class="question_part_label">b.i.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">Calculate the amount, in mol, of sodium azide present.</p>
<div class="marks">[1]</div>
<div class="question_part_label">b.ii.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">Determine the volume of nitrogen gas, in \({\text{d}}{{\text{m}}^{\text{3}}}\), produced under these conditions based on this reaction.</p>
<div class="marks">[4]</div>
<div class="question_part_label">b.iii.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">Suggest why it is necessary for sodium to be removed by this reaction.</p>
<div class="marks">[1]</div>
<div class="question_part_label">c.i.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">The metal oxides from the second reaction then react with silicon dioxide to form a silicate in the third reaction.</p>
<p class="p1">\[{{\text{K}}_2}{\text{O(s)}} + {\text{N}}{{\text{a}}_2}{\text{O(s)}} + {\text{Si}}{{\text{O}}_2}{\text{(s)}} \to {\text{N}}{{\text{a}}_2}{{\text{K}}_2}{\text{Si}}{{\text{O}}_4}{\text{(s)}}\]</p>
<p class="p1">Draw the structure of silicon dioxide and state the type of bonding present.</p>
<p class="p1">Structure:</p>
<p class="p1">Bonding:</p>
<div class="marks">[2]</div>
<div class="question_part_label">c.ii.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">It takes just 0.0400 seconds to produce nitrogen gas in the simulation. Calculate the average rate of formation of nitrogen in (b) (iii) and state its units.</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 class="p1">The students also discovered that a small increase in temperature (<em>e.g. </em>10 °C) causes a large increase (<em>e.g. </em>doubling) in the rate of this reaction. State <strong>one </strong>reason for this.</p>
<div class="marks">[1]</div>
<div class="question_part_label">d.ii.</div>
</div>
<br><hr><br><div class="specification">
<p class="p1">Hydrogen peroxide, \({{\text{H}}_{\text{2}}}{{\text{O}}_{\text{2}}}{\text{(aq)}}\), releases oxygen gas, \({{\text{O}}_{\text{2}}}{\text{(g)}}\), as it decomposes according to the equation below.</p>
<p class="p1">\[{\text{2}}{{\text{H}}_{\text{2}}}{{\text{O}}_{\text{2}}}{\text{(aq)}} \to {\text{2}}{{\text{H}}_{\text{2}}}{\text{O(l)}} + {{\text{O}}_{\text{2}}}{\text{(g)}}\]</p>
<p class="p1">\({\text{50.0 c}}{{\text{m}}^{\text{3}}}\) of hydrogen peroxide solution was placed in a boiling tube, and a drop of liquid detergent was added to create a layer of bubbles on the top of the hydrogen peroxide solution as oxygen gas was released. The tube was placed in a water bath at 75 °C and the height of the bubble layer was measured every thirty seconds. A graph was plotted of the height of the bubble layer against time.</p>
<p class="p1" style="text-align: center;"><img src="images/Schermafbeelding_2016-11-01_om_17.56.17.png" alt="M12/4/CHEMI/SP2/ENG/TZ2/01"></p>
</div>
<div class="specification">
<p class="p1">The experiment was repeated using solid manganese(IV) oxide, \({\text{Mn}}{{\text{O}}_{\text{2}}}{\text{(s)}}\), as a catalyst.</p>
</div>
<div class="specification">
<p class="p1">The decomposition of hydrogen peroxide to form water and oxygen is a redox reaction.</p>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">Explain why the curve reaches a maximum.</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">Use the graph to calculate the rate of decomposition of hydrogen peroxide at 120 s.</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 class="p1">(i) Draw a curve on the graph opposite to show how the height of the bubble layer changes with time when manganese(IV) oxide is present.</p>
<p class="p1">(ii) Explain the effect of the catalyst on the rate of decomposition of hydrogen peroxide.</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 class="p1">(i) Deduce the oxidation numbers of oxygen present in each of the species below.</p>
<p class="p1" style="text-align: center;"><img src="images/Schermafbeelding_2016-11-02_om_05.19.14.png" alt="M12/4/CHEMI/SP2/ENG/TZ2/01.d"></p>
<p class="p1">(ii) State two half-equations for the decomposition of hydrogen peroxide.</p>
<p class="p1">Oxidation:</p>
<p class="p1">Reduction:</p>
<div class="marks">[4]</div>
<div class="question_part_label">d.</div>
</div>
<br><hr><br><div class="specification">
<p class="p1">Methanol may be produced by the exothermic reaction of carbon monoxide gas and hydrogen gas.</p>
<p class="p1">\[\begin{array}{*{20}{l}} {{\text{CO(g)}} + {\text{2}}{{\text{H}}_{\text{2}}}{\text{(g)}} \rightleftharpoons {\text{C}}{{\text{H}}_{\text{3}}}{\text{OH(g)}}}&{\Delta {H^\Theta } = - 103{\text{ kJ}}} \end{array}\]</p>
</div>
<div class="specification">
<p class="p1">State and explain the effect of changing the following conditions on the amount of methanol present at equilibrium:</p>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">State the equilibrium constant expression, \({K_{\text{c}}}\), for the production of methanol.</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">increasing the temperature of the reaction at constant pressure.</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">increasing the pressure of the reaction at constant temperature.</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">The conditions used in industry during the production of methanol are a temperature of 450 °C and pressure of up to 220 atm. Explain why these conditions are used rather than those that could give an even greater amount of methanol.</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 class="p1">A catalyst of copper mixed with zinc oxide and alumina is used in industry for this production of methanol. Explain the function of the catalyst.</p>
<div class="marks">[1]</div>
<div class="question_part_label">d.</div>
</div>
<br><hr><br><div class="specification">
<p class="p1">Consider the following equilibrium:</p>
<p class="p1">\[\begin{array}{*{20}{l}} {{\text{4N}}{{\text{H}}_3}{\text{(g)}} + {\text{5}}{{\text{O}}_2}{\text{(g)}} \rightleftharpoons {\text{4NO(g)}} + {\text{6}}{{\text{H}}_2}{\text{O(g)}}}&{\Delta {H^\Theta } = - 909{\text{ kJ}}} \end{array}\]</p>
</div>
<div class="specification">
<p class="p1">Nitrogen reacts with hydrogen to form ammonia in the Haber process, according to the following equilibrium.</p>
<p class="p1">\[\begin{array}{*{20}{l}} {{{\text{N}}_{\text{2}}}{\text{(g)}} + {\text{3}}{{\text{H}}_{\text{2}}}{\text{(g)}} \rightleftharpoons {\text{2N}}{{\text{H}}_{\text{3}}}{\text{(g)}}}&{\Delta {H^\Theta } = - 92.6{\text{ kJ}}} \end{array}\]</p>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">Deduce the equilibrium constant expression, \({K_{\text{c}}}\), for the reaction.</p>
<div class="marks">[1]</div>
<div class="question_part_label">a.i.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">Predict the direction in which the equilibrium will shift when the following changes occur.</p>
<p class="p1">The volume increases.</p>
<p class="p1">The temperature decreases.</p>
<p class="p1">\({{\text{H}}_{\text{2}}}{\text{O(g)}}\) is removed from the system.</p>
<p class="p1">A catalyst is added to the reaction mixture.</p>
<div class="marks">[4]</div>
<div class="question_part_label">a.ii.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">Define the term <em>activation energy</em>, \({E_{\text{a}}}\).</p>
<div class="marks">[1]</div>
<div class="question_part_label">b.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">Nitrogen monoxide, NO, is involved in the decomposition of ozone according to the following mechanism.</p>
<p class="p2">\[\begin{array}{*{20}{l}} {}&{{{\text{O}}_{\text{3}}} \to {{\text{O}}_{\text{2}}} + {\text{O}} \bullet } \\ {}&{{{\text{O}}_3} + {\text{NO}} \to {\text{N}}{{\text{O}}_2} + {{\text{O}}_2}} \\ {}&{{\text{N}}{{\text{O}}_2} + {\text{O}} \bullet \to {\text{NO}} + {{\text{O}}_2}} \\ {{\text{Overall:}}}&{{\text{2}}{{\text{O}}_3} \to {\text{3}}{{\text{O}}_2}} \end{array}\]</p>
<p class="p1">State and explain whether or not NO is acting as a catalyst.</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 class="p1">Define the term <em>endothermic reaction</em>.</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 class="p1">Sketch the Maxwell-Boltzmann energy distribution curve for a reaction with and without a catalyst, and label both axes.</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 class="p1">Define the term <em>rate of reaction</em>.</p>
<div class="marks">[1]</div>
<div class="question_part_label">e.i.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">Iron, used as the catalyst in the Haber process, has a specific heat capacity of \({\text{0.4490 J}}\,{{\text{g}}^{ - 1}}{{\text{K}}^{ - 1}}\). If 245.0 kJ of heat is supplied to 8.500 kg of iron, initially at a temperature of 15.25 °C, determine its final temperature in K.</p>
<div class="marks">[3]</div>
<div class="question_part_label">f.</div>
</div>
<br><hr><br><div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">Define the term <em>activation energy</em>, \({E_{\text{a}}}\).</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 <strong>two </strong>conditions necessary for a reaction to take place between two reactant particles.</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">Sketch an enthalpy level diagram to describe the effect of a catalyst on an <em>exothermic </em>reaction.</p>
<div class="marks">[3]</div>
<div class="question_part_label">c.</div>
</div>
<br><hr><br><div class="specification">
<p class="p1">Consider the following equilibrium.</p>
<p class="p1">\[\begin{array}{*{20}{l}} {{\text{2S}}{{\text{O}}_2}{\text{(g)}} + {{\text{O}}_2}{\text{(g)}} \rightleftharpoons {\text{2S}}{{\text{O}}_3}{\text{(g)}}}&{\Delta {H^\Theta } = - 198{\text{ kJ}}\,{\text{mo}}{{\text{l}}^{ - 1}}} \end{array}\]</p>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">Deduce the equilibrium constant expression, \({K_{\text{c}}}\), for the reaction.</p>
<div class="marks">[1]</div>
<div class="question_part_label">a.i.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">State and explain the effect of increasing the temperature on the yield of sulfur trioxide.</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">State the effect of a catalyst on the value of \({K_{\text{c}}}\).</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">State and explain the effect of a catalyst on the position of equilibrium.</p>
<div class="marks">[2]</div>
<div class="question_part_label">a.iv.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">Define <em>oxidation </em>in terms of oxidation numbers.</p>
<div class="marks">[1]</div>
<div class="question_part_label">b.i.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">Describe using a labelled diagram, the essential components of an electrolytic cell.</p>
<div class="marks">[3]</div>
<div class="question_part_label">b.ii.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">Explain why solid sodium chloride does not conduct electricity but <strong>molten </strong>sodium chloride does.</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">Molten sodium chloride undergoes electrolysis in an electrolytic cell. For each electrode deduce the half-equation and state whether oxidation or reduction takes place. Deduce the equation of the overall cell reaction including state symbols.</p>
<div class="marks">[5]</div>
<div class="question_part_label">b.iv.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">Electrolysis has made it possible to obtain reactive metals such as aluminium from their ores, which has resulted in significant developments in engineering and technology. State <strong>one </strong>reason why aluminium is preferred to iron in many uses.</p>
<div class="marks">[1]</div>
<div class="question_part_label">b.v.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">Outline <strong>two </strong>differences between an electrolytic cell and a voltaic cell.</p>
<div class="marks">[2]</div>
<div class="question_part_label">b.vi.</div>
</div>
<br><hr><br><div class="specification">
<p class="p1">Biodiesel makes use of plants’ ability to fix atmospheric carbon by photosynthesis. Many companies and individuals are now using biodiesel as a fuel in order to reduce their carbon footprint. Biodiesel can be synthesized from vegetable oil according to the following reaction.</p>
<p class="p1" style="text-align: center;"><img src="images/Schermafbeelding_2016-10-16_om_07.10.38.png" alt="M09/4/CHEMI/SP2/ENG/TZ1/01"></p>
</div>
<div class="specification">
<p class="p1">The reversible arrows in the equation indicate that the production of biodiesel is an equilibrium process.</p>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">Identify the organic functional group present in both vegetable oil and biodiesel.</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">For part of her extended essay investigation into the efficiency of the process, a student reacted a pure sample of a vegetable oil (where \({\text{R}} = {{\text{C}}_{{\text{17}}}}{{\text{H}}_{{\text{33}}}}\)) with methanol. The raw data recorded for the reaction is below.</p>
<p class="p2">\[\begin{array}{*{20}{l}} {{\text{Mass of oil}}}&{ = 1013.0{\text{ g}}} \\ {{\text{Mass of methanol}}}&{ = 200.0{\text{ g}}} \\ {{\text{Mass of sodium hydroxide}}}&{ = 3.5{\text{ g}}} \\ {{\text{Mass of biodiesel produced}}}&{ = 811.0{\text{ g}}} \end{array}\]</p>
<p class="p1">The relative molecular mass of the oil used by the student is 885.6. Calculate the amount (in moles) of the oil and the methanol used, and hence the amount (in moles) of excess methanol.</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 class="p1">State what is meant by the term <em>dynamic equilibrium</em>.</p>
<div class="marks">[1]</div>
<div class="question_part_label">c.i.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">Using the abbreviations [vegetable oil], [methanol], [glycerol] and [biodiesel] deduce the equilibrium constant expression \({\text{(}}{K_{\text{c}}}{\text{)}}\) for this reaction.</p>
<div class="marks">[1]</div>
<div class="question_part_label">c.ii.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">Suggest a reason why excess methanol is used in this process.</p>
<div class="marks">[1]</div>
<div class="question_part_label">c.iii.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">State and explain the effect that the addition of the sodium hydroxide catalyst will have on the position of equilibrium.</p>
<div class="marks">[2]</div>
<div class="question_part_label">c.iv.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">The reactants had to be stirred vigorously because they formed two distinct layers in the reaction vessel. Explain why they form two distinct layers and why stirring increases the rate of reaction.</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">Calculate the percentage yield of biodiesel obtained in this process.</p>
<div class="marks">[2]</div>
<div class="question_part_label">e.</div>
</div>
<br><hr><br><div class="specification">
<p class="p1">The Haber process enables the large-scale production of ammonia needed to make fertilizers.</p>
</div>
<div class="specification">
<p class="p1">The equation for the Haber process is given below.</p>
<p class="p2">\[{{\text{N}}_2}({\text{g)}} + 3{{\text{H}}_2}({\text{g)}} \rightleftharpoons {\text{2N}}{{\text{H}}_3}({\text{g)}}\]</p>
<p class="p1">The percentage of ammonia in the equilibrium mixture varies with temperature.</p>
<p class="p1" style="text-align: center;"><img src="images/Schermafbeelding_2016-09-30_om_06.30.09.png" alt="N10/4/CHEMI/SP2/ENG/TZ0/06.a"></p>
</div>
<div class="specification">
<p class="p1">Fertilizers may cause health problems for babies because nitrates can change into nitrites in water used for drinking.</p>
</div>
<div class="specification">
<p class="p1">A student decided to investigate the reactions of the two acids with separate samples of \({\text{0.20 mol}}\,{\text{d}}{{\text{m}}^{ - 3}}\) sodium hydroxide solution.</p>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">(i) <span class="Apple-converted-space"> </span>Use the graph to deduce whether the forward reaction is exothermic or endothermic and explain your choice.</p>
<p class="p1">(ii) <span class="Apple-converted-space"> </span>State and explain the effect of increasing the pressure on the yield of ammonia.</p>
<p class="p1">(iii) <span class="Apple-converted-space"> </span>Explain the effect of increasing the temperature on the rate of reaction.</p>
<div class="marks">[6]</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>Define <em>oxidation </em>in terms of oxidation numbers.</p>
<p class="p1">(ii) <span class="Apple-converted-space"> </span>Deduce the oxidation states of nitrogen in the nitrate, \({\text{NO}}_{\text{3}}^ - \), and nitrite, \({\text{NO}}_{\text{2}}^ - \), ions.</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">The nitrite ion is present in nitrous acid, HNO<sub><span class="s1">2</span></sub>, which is a weak acid. The nitrate ion is present in nitric acid, HNO<sub><span class="s1">3</span></sub>, which is a strong acid. Distinguish between the terms <em>strong </em>and <em>weak acid </em>and state the equations used to show the dissociation of each acid in aqueous solution.</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 class="p1">A small piece of magnesium ribbon is added to solutions of nitric and nitrous acid of the same concentration at the same temperature. Describe <strong>two </strong>observations that would allow you to distinguish between the two acids.</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">(i) <span class="Apple-converted-space"> </span>Calculate the volume of the sodium hydroxide solution required to react exactly with a \({\text{15.0 c}}{{\text{m}}^{\text{3}}}\) solution of \({\text{0.10 mol}}\,{\text{d}}{{\text{m}}^{ - 3}}\) nitric acid.</p>
<p class="p1">(ii) <span class="Apple-converted-space"> </span>The following hypothesis was suggested by the student: “Since nitrous acid is a weak acid it will react with a smaller volume of the \({\text{0.20 mol}}\,{\text{d}}{{\text{m}}^{ - 3}}\) sodium hydroxide solution.” Comment on whether or not this is a valid hypothesis.</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 class="p1">The graph below shows how the conductivity of the two acids changes with concentration.</p>
<p class="p2" style="text-align: center;"><img src="images/Schermafbeelding_2016-09-30_om_08.07.40.png" alt="N10/4/CHEMI/SP2/ENG/TZ0/06.f"></p>
<p class="p1">Identify <strong>Acid 1 </strong>and explain your choice.</p>
<div class="marks">[2]</div>
<div class="question_part_label">f.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">Nitric acid reacts with silver in a redox reaction.</p>
<p class="p2" style="text-align: center;">__ \({\text{Ag(s)}} + \) __ \({\text{NO}}_3^ - {\text{(aq)}} + \) ___ \( \to \) ___\({\text{A}}{{\text{g}}^ + }{\text{(aq)}} + \) __ \({\text{NO(g)}} + \) ____</p>
<p class="p1">Using oxidation numbers, deduce the complete balanced equation for the reaction showing all the reactants and products.</p>
<div class="marks">[3]</div>
<div class="question_part_label">g.</div>
</div>
<br><hr><br><div class="specification">
<p class="p1">Reaction kinetics can be investigated using the iodine clock reaction. The equations for two reactions that occur are given below.</p>
<p class="p1"><span class="Apple-converted-space"> </span>Reaction A: \({{\text{H}}_2}{{\text{O}}_2}{\text{(aq)}} + {\text{2}}{{\text{I}}^ - }{\text{(aq)}} + {\text{2}}{{\text{H}}^ + }{\text{(aq)}} \to {{\text{I}}_2}{\text{(aq)}} + {\text{2}}{{\text{H}}_2}{\text{O(l)}}\)</p>
<p class="p1"><span class="Apple-converted-space"> </span>Reaction B: \({{\text{I}}_2}{\text{(aq)}} + {\text{2}}{{\text{S}}_2}{\text{O}}_3^{2 - }{\text{(aq)}} \to {\text{2}}{{\text{I}}^ - }{\text{(aq)}} + {{\text{S}}_4}{\text{O}}_6^{2 - }{\text{(aq)}}\)</p>
<p class="p1">Reaction B is much faster than reaction A, so the iodine, \({{\text{I}}_{\text{2}}}\), formed in reaction A immediately reacts with thiosulfate ions, \({{\text{S}}_{\text{2}}}{\text{O}}_3^{2 - }\), in reaction B, before it can react with starch to form the familiar blue-black, starch-iodine complex.</p>
<p class="p1">In one experiment the reaction mixture contained:</p>
<p class="p1">\(5.0 \pm 0.1{\text{ c}}{{\text{m}}^{\text{3}}}\) of \({\text{2.00 mol}}\,{\text{d}}{{\text{m}}^{ - 3}}\) hydrogen peroxide \({\text{(}}{{\text{H}}_{\text{2}}}{{\text{O}}_{\text{2}}}{\text{)}}\)</p>
<p class="p1">\(5.0 \pm 0.1{\text{ c}}{{\text{m}}^{\text{3}}}\) of 1% aqueous starch</p>
<p class="p1">\(20.0 \pm 0.1{\text{ c}}{{\text{m}}^{\text{3}}}\) of \({\text{1.00 mol}}\,{\text{d}}{{\text{m}}^{ - 3}}\) sulfuric acid (\({{\text{H}}_{\text{2}}}{\text{S}}{{\text{O}}_{\text{4}}}\))</p>
<p class="p1">\(20.0 \pm 0.1{\text{ c}}{{\text{m}}^{\text{3}}}\) of \({\text{0.0100 mol}}\,{\text{d}}{{\text{m}}^{ - 3}}\) sodium thiosulfate (\({\text{N}}{{\text{a}}_{\text{2}}}{{\text{S}}_{\text{2}}}{{\text{O}}_{\text{3}}}\))</p>
<p class="p1">\(50.0 \pm 0.1{\text{ c}}{{\text{m}}^{\text{3}}}\) of water with 0.0200 ± 0.0001 g of potassium iodide (KI) dissolved in it.</p>
<p class="p1">After 45 seconds this mixture suddenly changed from colourless to blue-black.</p>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">Calculate the amount, in mol, of KI in the reaction mixture.</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">Calculate the amount, in mol, of \({{\text{H}}_{\text{2}}}{{\text{O}}_{\text{2}}}\) in the reaction mixture.</p>
<div class="marks">[1]</div>
<div class="question_part_label">b.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">The concentration of iodide ions, \({{\text{I}}^ - }\), is assumed to be constant. Outline why this is a valid assumption.</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 class="p1">For this mixture the concentration of hydrogen peroxide, \({{\text{H}}_{\text{2}}}{{\text{O}}_{\text{2}}}\), can also be assumed to be constant. Explain why this is a valid assumption.</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 why the solution suddenly changes colour.</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 class="p1">Apart from the precision uncertainties given, state <strong>one </strong>source of error that could affect this investigation and identify whether this is a random error or a systematic error.</p>
<div class="marks">[2]</div>
<div class="question_part_label">f.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">Calculate the total uncertainty, in \({\text{c}}{{\text{m}}^{\text{3}}}\), of the volume of the reaction mixture.</p>
<div class="marks">[1]</div>
<div class="question_part_label">g.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">The colour change occurs when \(1.00 \times {10^{ - 4}}{\text{ mol}}\) of iodine has been formed. Use the total volume of the solution and the time taken, to calculate the rate of the reaction, including appropriate units.</p>
<div class="marks">[4]</div>
<div class="question_part_label">h.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">In a second experiment, the concentration of the hydrogen peroxide was decreased to \({\text{1.00 mol}}\,{\text{d}}{{\text{m}}^{ - 3}}\) while all other concentrations and volumes remained unchanged. The colour change now occurred after 100 seconds. Explain why the reaction in this experiment is slower than in the original experiment.</p>
<div class="marks">[2]</div>
<div class="question_part_label">i.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">In a third experiment, 0.100 g of a black powder was also added while all other concentrations and volumes remained unchanged. The time taken for the solution to change colour was now 20 seconds. Outline why you think the colour change occurred more rapidly and how you could confirm your hypothesis.</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 class="p1">Explain why increasing the temperature also decreases the time required for the colour to change.</p>
<div class="marks">[2]</div>
<div class="question_part_label">k.</div>
</div>
<br><hr><br><div class="specification">
<p>Graphing is an important tool in the study of rates of chemical reactions.</p>
</div>
<div class="specification">
<p>Excess hydrochloric acid is added to lumps of calcium carbonate. The graph shows the volume of carbon dioxide gas produced over time.</p>
<p><img 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"></p>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Sketch a Maxwell–Boltzmann distribution curve for a chemical reaction showing the activation energies with and without a catalyst.</p>
<p><img src="data:image/png;base64,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"></p>
<div class="marks">[3]</div>
<div class="question_part_label">a.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Sketch a curve on the graph to show the volume of gas produced over time if the same mass of crushed calcium carbonate is used instead of lumps. All other conditions remain constant.</p>
<div class="marks">[1]</div>
<div class="question_part_label">b.i.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>State and explain the effect on the rate of reaction if ethanoic acid of the same concentration is used in place of hydrochloric acid.</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>Outline why pH is more widely used than [H<sup>+</sup>] for measuring relative acidity.</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>Outline why H<sub>3</sub>PO<sub>4</sub>/HPO<sub>4</sub><sup>2−</sup> is not a conjugate acid-base pair.</p>
<div class="marks">[1]</div>
<div class="question_part_label">d.</div>
</div>
<br><hr><br><div class="specification">
<p>The rate of reaction is an important factor in industrial processes such as the Contact process to make sulfur trioxide, \({\text{S}}{{\text{O}}_{\text{3}}}{\text{(g)}}\).</p>
<p style="text-align: center;">\({\text{2S}}{{\text{O}}_{\text{2}}}{\text{(g)}} + {{\text{O}}_{\text{2}}}{\text{(g)}} \rightleftharpoons {\text{2S}}{{\text{O}}_{\text{3}}}{\text{(g)}}\) \(\Delta {H^\Theta } = - 198{\text{ kJ}}\)</p>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Define the term <em>rate of reaction</em>.</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 the collision theory.</p>
<div class="marks">[3]</div>
<div class="question_part_label">b.</div>
</div>
<br><hr><br><div class="specification">
<p>The Contact process involves an exothermic reversible reaction.</p>
<p style="text-align: center;">\({\text{2S}}{{\text{O}}_{\text{2}}}{\text{(g)}} + {{\text{O}}_{\text{2}}}{\text{(g)}} \rightleftharpoons {\text{2S}}{{\text{O}}_{\text{3}}}{\text{(g)}}\) \({K_{\text{c}}} \gg 1\) at 200 °C and 1 atm</p>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Deduce the extent of the reaction at 200 °C and 1 atm.</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>The Contact process operates at a temperature of 450 °C and a pressure of 2 atm as optimum conditions for the production of \({\text{S}}{{\text{O}}_{\text{3}}}\). Outline the reasons for choosing these conditions.</p>
<p> </p>
<p>Temperature:</p>
<p> </p>
<p> </p>
<p> </p>
<p> </p>
<p>Pressure:</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>An engineer at a Contact process plant hypothesized that using pure oxygen, instead of air, would increase the profits. Comment on whether or not her hypothesis is valid, giving your reasons.</p>
<div class="marks">[2]</div>
<div class="question_part_label">c.</div>
</div>
<br><hr><br><div class="specification">
<p class="p1">Chemical equilibrium and kinetics are important concepts in chemistry.</p>
</div>
<div class="specification">
<p>The oxidation of sulfur dioxide is an important reaction in the Contact process used to manufacture sulfuric acid.</p>
<p>\[\begin{array}{*{20}{l}} {{\text{2S}}{{\text{O}}_2}{\text{(g)}} + {{\text{O}}_{\text{2}}}{\text{(g)}} \rightleftharpoons {\text{2S}}{{\text{O}}_{\text{3}}}{\text{(g)}}}&{\Delta H = - 198.2{\text{ kJ}}} \end{array}\]</p>
</div>
<div class="specification">
<p class="p1">Vanadium(V) oxide, \({{\text{V}}_{\text{2}}}{{\text{O}}_{\text{5}}}\), is a catalyst that can be used in the Contact process. It provides an alternative pathway for the reaction, lowering the activation energy, \({E_{\text{a}}}\).</p>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p class="p1">A glass container is half-filled with liquid bromine and then sealed. The system eventually reaches a dynamic equilibrium. State <strong>one </strong>characteristic of a system in equilibrium.</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">(i) <span class="Apple-converted-space"> </span>Deduce the equilibrium constant expression, \({K_{\text{c}}}\).</p>
<p class="p1">(ii) <span class="Apple-converted-space"> </span>Predict how each of the following changes affects the position of equilibrium and</p>
<p class="p1">the value of \({K_{\text{c}}}\).</p>
<p class="p1"><img src="images/Schermafbeelding_2016-09-23_om_08.44.42.png" alt="N12/4/CHEMI/SP2/ENG/TZ0/03.b"></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 class="p1">(i) <span class="Apple-converted-space"> </span>Define the term <em>activation energy</em>, \({E_{\text{a}}}\).</p>
<p class="p1">(ii) <span class="Apple-converted-space"> </span>Sketch the <strong>two </strong>Maxwell–Boltzmann energy distribution curves for a fixed amount of gas at two different temperatures, \({T_1}\) and \({T_2}{\text{ }}({T_2} > {T_1})\). Label <strong>both </strong>axes.</p>
<p class="p1" style="text-align: center;"><img src="images/Schermafbeelding_2016-09-23_om_08.54.15.png" alt="N12/4/CHEMI/SP2/ENG/TZ0/03.c"></p>
<div class="marks">[4]</div>
<div class="question_part_label">c.</div>
</div>
<br><hr><br><div class="specification">
<p>The rate of the acid-catalysed iodination of propanone can be followed by measuring how the concentration of iodine changes with time.</p>
<p style="text-align: center;">I<sub>2</sub>(aq) + CH<sub>3</sub>COCH<sub>3</sub>(aq) → CH<sub>3</sub>COCH<sub>2</sub>I(aq) + H<sup>+</sup>(aq) + I<sup>−</sup>(aq)</p>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Suggest how the change of iodine concentration could be followed.</p>
<div class="marks">[1]</div>
<div class="question_part_label">a.i.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>A student produced these results with [H<sup>+</sup>] = 0.15 mol\(\,\)dm<sup>−3</sup>. Propanone and acid were in excess and iodine was the limiting reagent.</p>
<p>Determine the relative rate of reaction when [H<sup>+</sup>] = 0.15 mol\(\,\)dm<sup>−3</sup>.</p>
<p><img src="images/Schermafbeelding_2017-09-22_om_15.59.41.png" alt="M17/4/CHEMI/SP2/ENG/TZ1/01.a.ii"></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>The student then carried out the experiment at other acid concentrations with all other conditions remaining unchanged.</p>
<p style="text-align: center;"><img 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9GO+XBsfxALp95gsS1Ndrf/EIvtss2N+VMN5Vu+g2VFNwJpWaUampNrVarYEUsZ4qo5YnopGIAx31n5F3+CPxoxItNQuuk1+Ftfh0t/GV4qkkNSbrT6X8Om0sgQTmb18illB9oP1OsXBl2Cox4H/t+BqxiSy6yRZ0eHgG3GN/BjffhWXkt/gGf04dupmOvchfZWN2rkBV3/zYfD9Tu0714bWbCWxjwpa/v+vfEy5TVo9P4TXn1iCWDMW8rnxaJleLbeER361XAHQsi0lCg+8mFa/BLTPzxbY8WTd2x34f7tbjTW6OM1cqUdahr34c1X/4e+GCW26Mc2C8uefTrmD7hjEmQl8ueuxe72Vrhj5QFN+kr7LjijC4GSVerH+QuxaX87Wn/tisuUut2t8O/fOPQNblqhisT8+XDu9qDVXYPYYLTmgOuAB7udkUWFVtsS+Qvx1Gv74XEZ7SkvLw64PPvx2val0cWF6Vil+y5TLq5VijqPQPJ1+l9V5Mvaj8O+6heA/MKQYg7n6niPho6rs5Clr10C8uMCcp6RPxIggbEloPJFPnnuXaV/rSfyYfjcNNIVn/ww/BciwTk3IimFBEiABEjgGiLA4HkNNQZNIQESIAESGB8ErtNh2/HROLTy+iWgGiq6fomw5iQwNgRUvsgnz7FpD2olARIgARIYxwQYPMdx49F0EiABEiCBsSHA4Dk23KmVBEiABEhgHBNg8BzHjUfTSYAESIAExoYAg+fYcKdWEiABEiCBcUyAwXMcNx5NJwESIAESGBsCKZ8alsty+SMBEhh7AvTFsW8DWkACKgIpwZOfBFOhYjoJjB4B1btlo2cBNZEACUgCqptYDtuyf5AACZAACZBAlgQYPLMExuwkQAIkQAIkwODJPkACJEACJEACWRJg8MwSGLOTAAmQAAmQAIMn+wAJkAAJkAAJZEmAwTNLYMxOAiRAAiRAAgye7AMkQAIkQAIkkCUBBs8sgTE7CZAACZAACTB4sg+QAAmQAAmQQJYEGDyzBMbsJEACJEACJMDgOU76QDh4FHtqq/RPRcnPReVV1KLhLR+C4cwVsFQufBwNVfa4bClf/1uDhq6LmRXwLAlMGAKXEPQ1obbC8AU7KmpfwVu+IDK7mbVylnxxoAttDbWoiPlgCarrWtA1YLbgIroa1qTxVzuqGo4PYeuEaawxrwiD55g3gQUDwiewb9t30YiH4A0MQohBBHbeiUOPbsCL7WfUAqyWGwjA33Ev3P4LkN82jv+9AeecG9XyeYYEJhCB8Mm3sW3Fq8C6fQiEBETIh50Fh/Hoip+h/bw5eCVW2lI5K74YPoHmjavw0KE7sVP3c4FQ4OdY0LEJ5Rv34WTMhAH0+k+i0t2JUIK/BtDinAte1BPbZ8SOhOkHyOsmf9cagZDfLSqxWrj9F0ymXRB+92qh1bSKPlOqeddauZDoa90iNG2LaO0LmYtzfwwJ0BdHG37En1DpFn6zG4Q6hbvyHlHTelphkLVyVnwxkqc0RVdKel+rqNFS8ykMZPJVElD5Im9SRuy2JFeCwxjo7UaHVoTCgskmoZNRUFgENL0Db9q7YqvlLuFUTzeCJUWYmc/uYALM3euKgHya+xjagkIUmN3ANh2FCwbR1PIBzqflYaWcNV+0zXGiRXixc9H0NJoCONZzRh+SDZ/qwbHgLBTPzE+Tj0mjRcDcTUZLJ/VkRSAa3FRlgt3oOXUpzVmr5aLOX/AJmh8uic6jyHmWZviC6eSmUcUkEhjvBMJn0HMsoKxF8FgPTsWGTU3ZLJWz6osmuSm79+KBewthgxGI/wD/2bwB9ujcqL26Ds1Dzs2mCGXCVRBg8LwKeKNTNBLcstdlsZzu/OdQPOMeVP+yIzrf+R6enuXFpgd3w5ewUCF7K1iCBMYFAX3eP5i9qZbKWfTFdNrlXOnOXehw/jWqiuT6g2ggLp6FhdWvIKDPeYbQ9fQsHNn0XdT7zqWTwrQRIMDgOQJQx5VI21w4W7rx7o6l0GK9YSrmLFmChX4Xtr7RxdV746pBaezEIXAexxt/jMc//hZe3f4NzND980bMcb4B8e4PsEgzpnFsyJ/z56ha+Ak2b21GV7on5IkD5ZqpSexyec1YREOSCORjZvGspDQrh8MtF5Wdb0dxCdDhD2DAijrmIYHxTEDv71r2NbBUbji+eB7HG57Eom3A9r9/0hQoVSZGdXR0o5ejRSpIOU2/IafSKGwECEQWBindOmUhkWHCcMsZ5bklgeuIgL4wyK6scMpCIiOnpXKTgcIiWPbhcBBHX/o+7nfdgO1tu+CcO9XQxu01RIBPntdQY6Q3xYb8mUUoSVkYFJ37UK6StVYu3NWAqrwy1LYlvS+qz+XYsbbqy6Drpm8Zpk4kApEnt5SFQdE1ASXFdqRf22qlnDVflDTDwYPYurgUd/9mBl5uTxM4ox80sde2Ja3+jS78W7sEZVN5WR+Vnml+BUb1Pos5D/fHgECoR3ic84XmaBSd/fIltEEROPKycAz1rpelcp8Kr2u5SbasX5/odDvFbKdH9JrfeRuDql+vKumLo9/yoV6PcGrzhcPdIfql+lBAHKl3DPkOtKVyVnyx/4hwlWsC2mPC0zuoABAS/d56Ua45hbvTeMM7JPo7G4VjdqZyCnFMHpKAyhcTvoqgyjSkdGYYYQIh0e9vFe6aSiHbSP/THMLl8YpALLhFX9aG+eVpK+UiFwmvxyUcWlQ2KkWNu1X49UA9wlWj+LQE6ItpsYxwYp/wt7pFjQxgUT/THC7h8QZEzM30jybIAGf+qIiFcmIoXzT81/DB1G38gyiDIuD1CJdjftROTZTXuEWr3wimI4zpOhOv8sU8ycF4xJXfMzUdGsnckgAJjDIB+uIoA6c6ElAQUPkiB8cVwJhMAiRAAiRAAioCDJ4qMkwnARIgARIgAQUBBk8FGCaTAAmQAAmQgIoAg6eKDNNJgARIgARIQEGAwVMBhskkQAIkQAIkoCLA4Kkiw3QSIAESIAESUBBg8FSAYTIJkAAJkAAJqAgweKrIMJ0ESIAESIAEFAQYPBVgmEwCJEACJEACKgIp/1VFfk2BPxIggbEnQF8c+zagBSSgIpASPPl5PhUqppPA6BFQfRJs9CygJhIgAUlAdRPLYVv2DxIgARIgARLIkgCDZ5bAmJ0ESIAESIAEGDzZB0iABEiABEggSwIMnlkCY3YSIAESIAESYPBkHyABEiABEiCBLAkweGYJjNlJgARIgARIgMGTfYAESIAESIAEsiTA4JklMGYnARIgARIgAQZP9gESIAESIAESyJIAg2eWwJidBEiABEiABBg8x0kfCAePYk9tlf6pKPm5qLyKWjS85UMwbLUCYQz4dqHCvhVt55MKhYPw7alFhZSr/1WhtuFt+IKXrApnPhKYAAQuIehrQm2FPeoHdlTUvoK3fEEkeUxSXa2Vs+TD4eNoqDL0G/4ot2vQ0HUxSa88PAdf3Tdgr23D+TRnmTRyBBg8R45t7iSHT2Dftu+iEQ/BGxiEEIMI7LwThx7dgBfbz1jQE8bA8dfx7NZ/RHtK7ks4ue8nWNEIrPMGEBICocAzKDi0BStePEyHTOHFhIlKIHzybWxb8Sqwbh8CIQER8mFnwWE8uuJnaE++4TRBsFTOqg8PBODvuBdu/wXI74zH/96Ac86NJq1y9zyO73kOW//p/aR0Ho4GAQbP0aB8lTrC3a34RcMsrF2/GqXaZACToS1cj6e3z0JTyweZA5z+VLkNj71tx5oHZqVaEv4YLb/4HUrWPoy1pRpkh7BpX8fGp59ESdM78Ga4aKQKYwoJjFcCF9Hd8joaSh7A+rULoUUcAQs3bsH2kkNo8Z5VVMxaOWs+HMZ57ztoQhEKC6Sfq3+Rp9iteHvefXggX52PZ0aOAIPnyLHNkeQwBnq70aElO9RkFBQWARkD3EV0NW7CJn8Fnn/qTzElnUX6ne40LCicrgdOI4utoBALcCDDRcPIyS0JTAQCA+j1fwxtQSEKzFdF23QULhjMcJNqpZxVH76EUz3dCJYUYWa+2YgkvuHjaFz3Y/irtuCpstuSTvJwtAhkaKHRMoF6MhOIOpQqU7AbPadUc5OTYV+2C/t3LI3cSaeRET7Vg2PBNCf0pACO9ZwZYr5HVZbpJDCOCITPoOdYQGlw8FgPTqWb+LRUzqoPRwNxwSdofrgkOu9aguq65sT1B7aZWNb4OnYsmpFww6s0nidGhACD54hgzaXQiEMNT6IN+dqXoB7Vid4RD084S5HAxCGgj8Ao7yLV9bRUzqIP64H4HIpn3IPqX3ZE5zvfw9OzvNj04G74BozonQ9NU3u12lieySUBBs9c0qQsEiABEhguAdtcOFu68W7CSNFUzFmyBAv9Lmx9o4ujQMNlOwLlGDxHAGpuReZjZnGahT45UWJD/swilOREFoWQwDgmkG9HcYmWfQUslbtKH9Z1AB3+AAayt5AlRojADSMkl2JzRiCyMEjp1ikLibJTrC8MUgq3pywkyk46c5PAOCGgLwyyK41NWUhk5LRUbjJQWASlm12lDxumcDu6BPjkObq8h6Et+nSYsjDI4sq8oTTqd7XnUhYGRRYSzULxTM6tDIWQ5ycCgcjTYcrCoOg8ZEmxXbF2wEo5az4c7mpAVV4ZatuS3t3W51XtWFv1ZUydCKgnSh2E6QfIOWr+rjkCoR7hcc4XmqNRdPaHhBCDInDkZeHQSkVN62mL5l4QfvdqAW2LaO2TMozfoOj1PCY0zSncnX16YihwWNQ75gutplVEUoy83I4WAfriaJGO6wn1eoRTmy8c7g7RL5NDAXGk3iG0FJ+Jl9GzWSlnyYc/FV7XcpOfS+l9otPtFLOdHtFrdlvDhFCncFdq9FWDxwhsVb7IJ8/xcBdkuwOVtS9he8FrmDdlEvLyvgj7/UdR8vIv8L3y6dEaXERXwxrkpbtzzVjHyZhR+d/x6vbpaJp3i748fpL9ERwr+RH2f+9e3ulmZMeTE4mAbcYS1L76JAqaKjFFfqZykh33HyvBy/ufQPnU6KXS+Hye6TOXlspZ8uFpKH3qFez/5mk8N0f6ufws32r8Et/GP790P2bwan1Ndbc8GagNi2RjmQ6NZG5JgARGmQB9cZSBUx0JKAiofJH3MgpgTCYBEiABEiABFQEGTxUZppMACZAACZCAggCDpwIMk0mABEiABEhARYDBU0WG6SRAAiRAAiSgIMDgqQDDZBIgARIgARJQEWDwVJFhOgmQAAmQAAkoCDB4KsAwmQRIgARIgARUBBg8VWSYTgIkQAIkQAIKAgyeCjBMJgESIAESIAEVgZT/qiK/psAfCZDA2BOgL459G9ACElARSAme/DyfChXTSWD0CKg+CTZ6FlATCZCAJKC6ieWwLfsHCZAACZAACWRJgMEzS2DMTgIkQAIkQAIMnuwDJEACJEACJJAlAQbPLIExOwmQAAmQAAkweLIPkAAJkAAJkECWBBg8swTG7CRAAiRAAiTA4Mk+QAIkQAIkQAJZEmDwzBIYs5MACZAACZAAgyf7AAmQAAmQAAlkSYDBM0tgzE4CJEACJEACDJ7jpA+Eg0exp7ZK/1SU/FxUXkUtGt7yIRjOVIEwBrra0GAuZ69G3cEuDJiLhYPw7alFhZSr/1WhtuFt+IKXzLm4TwITnMAlBH1NqK2wR/3AjoraV/CWL4iMboZsy4Ux4NuFCvtWtJ1PkmzJF7PVN8GbbYyqx+A5RuCzUhs+gX3bvotGPARvYBBCDCKw804cenQDXmw/oxQVPrkPG8s34lDBMwiERKTcvoXoqF6Fjc0noheESzi57ydY0Qis8wYQEgKhwDMoOLQFK148jPNK6TxBAhOLQPjk29i24lVg3b6Iv4R82FlwGI+u+Bnak4OcqerZlQtj4PjreHbrP6LdJCOya80Xs9OXooQJuSIgTD8ApiPuXisEQn63qMRq4fZfMJl0Qfjdq4VW0yr6TKnx3ch5aFtEa18oniyS0kOdwl05W1S6O4U5l64zpaxJDHdHlAB9cUTxptAt1x8AAASWSURBVBEe9YtKt/AnOIL0j3tETevpNGVkUhblQgHhbdwiHK53hde9WqT4piVfzEKfwmImZ0dA5Yt88szVXciIyQljoLcbHVoRCgsmm7RMRkFhEdD0Drxp74pvxBznGxCBHVg0NU0zB7vRc+oSMBCAv2MaFhROhzmXraAQC3AALd6zJp3cJYGJSmAAvf6PoS0oREGCI0xH4YJBNLV8oBiFsVruIroaN2GTvwLPP/WnmJIOoyVftKovnQKm5ZKAuZvkUi5l5YzAJZzq6UZQJc8IgqrzqvTKv8S9RTcifKoHx5TCAzjWc2aI+R6VAqaTwDgiED6DnmMBpcHBYz04lTQ9qWe2XG4y7Mt2Yf+OpdAUV11LvmhZn7IqPJEjAopmzJF0iskBgcidZg4E6SLCJ/8ZO7d1wrlhMYps0afaXAmnHBIYrwT0pz7lXaS6VpbL2ZCvfQn5SkkWfdGyPqUinsgRgZR/hp0juRRzLRIY+BCNW3fg43X1eO3+u2DjM+W12Eq0iQRIYBwQ4JPnNd9I+ZhZPOvqrRz4EA2P/Q224Qn8/dbF0aEjG/JnFqHk6qVTAgmMbwL5dhSXaNnXYbjlUjRZ9MWc6UsxgAlZEuCTZ5bARj97ZGGQ0q1TFhKlWhgOvoeXvv8IXNiEtt1rMTc/fs+kLwxSCrenLCRKlc4UEpgABGxyYZBdWZGUhURGzuGWM8qbtpZ80Ybh2WnSw93cEIhfRXMjj1JyTiB6R5qyMCi6kKikCDNNwTBR/SUE236ExfbV+E3Bj9CeFDj1vPqd7LmUhUGRxQuzUDxTPUuTqItHJDCeCURGeFIWBukLdM6hpNiumK8cbrk0rCz5Yg71pTGBSVkQML/xonqfxZyH+2NAINQjPM75QnM0is5++RLaoAgceVk4tNIM75+FRL+3XpQDQnN6RK/53bWEKgyKXs9jQtOcwt0ZeWM0FDgs6h3zM7xDmiCAByNAgL44AlCHEBnq9QinNl843B2iX+YNBcSReofQhnjfOftySe9ax+yy5ovZ64sp4M4wCKh8MeGrCKpMw9DHIjklEBL9/lbhrqkUso30P80hXB6vCMSCYtQhEQ2o+gvXWjy/US62NQXefr9oddfogTYif75wuDzCGxjMaS0ozDoB+qJ1VrnL2Sf8rW5RUx73G83hEh5vIP4BEcOvEgKqhXIJRqqCpxDCki9mqy9BOQ+yJKDyxTwpx3hQld81NR0aydySAAmMMgH64igDpzoSUBBQ+SLnPBXAmEwCJEACJEACKgIMnioyTCcBEiABEiABBQEGTwUYJpMACZAACZCAigCDp4oM00mABEiABEhAQYDBUwGGySRAAiRAAiSgIsDgqSLDdBIgARIgARJQEGDwVIBhMgmQAAmQAAmoCDB4qsgwnQRIgARIgAQUBBg8FWCYTAIkQAIkQAIqAin/VUV+TYE/EiCBsSdAXxz7NqAFJKAikBA8+Wk+FSamkwAJkAAJkECcAIdt4yy4RwIkQAIkQAKWCDB4WsLETCRAAiRAAiQQJ8DgGWfBPRIgARIgARKwRIDB0xImZiIBEiABEiCBOIH/D/qXE1lTbKSeAAAAAElFTkSuQmCC"></p>
<p>State and explain the relationship between the rate of reaction and the concentration of acid.</p>
<div class="marks">[2]</div>
<div class="question_part_label">b.</div>
</div>
<br><hr><br><div class="specification">
<p>0.100 g of magnesium ribbon is added to \({\text{50.0 c}}{{\text{m}}^{\text{3}}}\) of \({\text{1.00 mol}}\,{\text{d}}{{\text{m}}^{ - 3}}\) sulfuric acid to produce hydrogen gas and magnesium sulfate.</p>
<p>\[{\text{Mg(s)}} + {{\text{H}}_2}{\text{S}}{{\text{O}}_4}{\text{(aq)}} \to {{\text{H}}_2}{\text{(g)}} + {\text{MgS}}{{\text{O}}_4}{\text{(aq)}}\]</p>
</div>
<div class="specification">
<p>Magnesium sulfate can exist in either the hydrated form or in the anhydrous form. Two students wished to determine the enthalpy of hydration of anhydrous magnesium sulfate. They measured the initial and the highest temperature reached when anhydrous magnesium sulfate, \({\text{MgS}}{{\text{O}}_{\text{4}}}{\text{(s)}}\), was dissolved in water. They presented their results in the following table.</p>
<p style="text-align: center;"><img src="images/Schermafbeelding_2016-08-16_om_10.27.16.png" alt="M14/4/CHEMI/SP2/ENG/TZ1/01.0b"></p>
</div>
<div class="specification">
<p>The students repeated the experiment using 6.16 g of solid hydrated magnesium sulfate, \({\text{MgS}}{{\text{O}}_{\text{4}}} \bullet {\text{7}}{{\text{H}}_{\text{2}}}{\text{O(s)}}\), and \({\text{50.0 c}}{{\text{m}}^{\text{3}}}\) of water. They found the enthalpy change, \(\Delta {H_2}\), to be \( + 18{\text{ kJ}}\,{\text{mo}}{{\text{l}}^{ - 1}}\).</p>
<p>The enthalpy of hydration of solid anhydrous magnesium sulfate is difficult to determine experimentally, but can be determined using the diagram below.</p>
<p style="text-align: center;"><img src="images/Schermafbeelding_2016-08-16_om_11.08.23.png" alt="M14/4/CHEMI/SP2/ENG/TZ1/01.c"></p>
</div>
<div class="specification">
<p>Magnesium sulfate is one of the products formed when acid rain reacts with dolomitic limestone. This limestone is a mixture of magnesium carbonate and calcium carbonate.</p>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>(i) The graph shows the volume of hydrogen produced against time under these experimental conditions.</p>
<p style="text-align: center;"><img src="images/Schermafbeelding_2016-08-16_om_10.18.50.png" alt="M14/4/CHEMI/SP2/ENG/TZ1/01.a"></p>
<p>Sketch two curves, labelled <strong>I</strong> and <strong>II</strong>, to show how the volume of hydrogen produced (under the same temperature and pressure) changes with time when:</p>
<p>I. using the same mass of magnesium powder instead of a piece of magnesium ribbon;</p>
<p>II. 0.100 g of magnesium ribbon is added to \({\text{50 c}}{{\text{m}}^{\text{3}}}\) of \({\text{0.500 mol}}\,{\text{d}}{{\text{m}}^{ - 3}}\) sulfuric acid.</p>
<p>(ii) Outline why it is better to measure the volume of hydrogen produced against time rather than the loss of mass of reactants against time.</p>
<div class="marks">[3]</div>
<div class="question_part_label">a.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>(i) Calculate the amount, in mol, of anhydrous magnesium sulfate.</p>
<p> </p>
<p> </p>
<p>(ii) Calculate the enthalpy change, \(\Delta {H_1}\), for anhydrous magnesium sulfate dissolving in water, in \({\text{kJ}}\,{\text{mo}}{{\text{l}}^{ - 1}}\). State your answer to the correct number of significant figures.</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) Determine the enthalpy change, \(\Delta H\), in \({\text{kJ}}\,{\text{mo}}{{\text{l}}^{ - 1}}\), for the hydration of solid anhydrous magnesium sulfate, \({\text{MgS}}{{\text{O}}_{\text{4}}}\).</p>
<p> </p>
<p> </p>
<p>(ii) The literature value for the enthalpy of hydration of anhydrous magnesium sulfate is \( - 103{\text{ kJ}}\,{\text{mo}}{{\text{l}}^{ - 1}}\). Calculate the percentage difference between the literature value and the value determined from experimental results, giving your answer to <strong>one</strong> decimal place. (If you did not obtain an answer for the experimental value in (c)(i) then use the value of \( - 100{\text{ kJ}}\,{\text{mo}}{{\text{l}}^{ - 1}}\), but this is <strong>not</strong> the correct value.)</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>Another group of students experimentally determined an enthalpy of hydration of \( - 95{\text{ kJ}}\,{\text{mo}}{{\text{l}}^{ - 1}}\). Outline two reasons which may explain the variation between the experimental and literature values.</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>(i) State the equation for the reaction of sulfuric acid with magnesium carbonate.</p>
<p> </p>
<p> </p>
<p>(ii) Deduce the Lewis (electron dot) structure of the carbonate ion, giving the shape and the oxygen-carbon-oxygen bond angle.</p>
<p> </p>
<p>Lewis (electron dot) structure:</p>
<p> </p>
<p>Shape:</p>
<p> </p>
<p>Bond angle:</p>
<div class="marks">[[N/A]]</div>
<div class="question_part_label">e.</div>
</div>
<br><hr><br><div class="specification">
<p>Iron rusts in the presence of oxygen and water. Rusting is a redox process involving several steps that produces hydrated iron(III) oxide, \({\text{F}}{{\text{e}}_{\text{2}}}{{\text{O}}_{\text{3}}} \bullet {\text{n}}{{\text{H}}_{\text{2}}}{\text{O}}\), as the final product.</p>
<p>The half-equations involved for the first step of rusting are given below.</p>
<p> Half-equation 1: \({\text{Fe(s)}} \to {\text{F}}{{\text{e}}^{2 + }}{\text{(aq)}} + {\text{2}}{{\text{e}}^ - }\)</p>
<p> Half-equation 2: \({{\text{O}}_{\text{2}}}{\text{(aq)}} + {\text{4}}{{\text{e}}^ - } + {\text{2}}{{\text{H}}_{\text{2}}}{\text{O(l)}} \to {\text{4O}}{{\text{H}}^ - }{\text{(aq)}}\)</p>
</div>
<div class="specification">
<p>A voltaic cell is made from a half-cell containing a magnesium electrode in a solution of magnesium nitrate and a half-cell containing a silver electrode in a solution of silver(I) nitrate.</p>
<p style="text-align: center;"><img src="images/Schermafbeelding_2016-08-23_om_10.08.47.png" alt="N14/4/CHEMI/SP2/ENG/TZ0/08.c"></p>
</div>
<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_2016-08-23_om_10.25.17.png" alt="N14/4/CHEMI/SP2/ENG/TZ0/08.e"></p>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>(i) Identify whether half-equation 1 represents oxidation or reduction, giving a reason for your answer.</p>
<p> </p>
<p> </p>
<p>(ii) Identify the oxidation number of each atom in the three species in half-equation 2.</p>
<p style="text-align: center;"><img src="images/Schermafbeelding_2016-08-23_om_09.41.52.png" alt="N14/4/CHEMI/SP2/ENG/TZ0/08.a.ii"></p>
<p> </p>
<p>(iii) Deduce the overall redox equation for the first step of rusting by combining half-equations 1 and 2.</p>
<p> </p>
<p> </p>
<p>(iv) Identify the reducing agent in the redox equation in part (iii).</p>
<div class="marks">[5]</div>
<div class="question_part_label">a.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>The oxygen in half-equation 2 is atmospheric oxygen that is found dissolved in water in very small concentrations. Explain, in terms of intermolecular forces, why oxygen is not very soluble in water.</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>(i) Given that magnesium is more reactive than silver, deduce the half-equations for the reactions occurring at each electrode, including state symbols.</p>
<p> </p>
<p>Negative electrode (anode):</p>
<p> </p>
<p>Positive electrode (cathode):</p>
<p> </p>
<p>(ii) Outline <strong>one </strong>function of the salt bridge.</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>(i) State the property that determines the order in which elements are arranged in the periodic table.</p>
<p> </p>
<p> </p>
<p>(ii) State the relationship between the electron arrangement of an element and its group and period in the periodic table.</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>(i) The experiment is repeated with the same amount of a more effective catalyst, \({\text{Mn}}{{\text{O}}_{\text{2}}}\), under the same conditions and using the same concentration and volume of hydrogen peroxide. On the graph above, sketch the curve you would expect.</p>
<p>(ii) Outline how the initial rate of reaction can be found from the graph.</p>
<p> </p>
<p> </p>
<p> </p>
<p>(iii) Outline a different experimental procedure that can be used to monitor the decomposition rate of hydrogen peroxide.</p>
<p> </p>
<p> </p>
<p>(iv) 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_2016-08-23_om_10.32.00.png" alt="N14/4/CHEMI/SP2/ENG/TZ0/08.e.iv"></p>
<div class="marks">[7]</div>
<div class="question_part_label">e.</div>
</div>
<br><hr><br><div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>A hydrocarbon has the empirical formula \({{\text{C}}_{\text{3}}}{{\text{H}}_{\text{7}}}\). When 1.17 g of the compound is heated to 85 °C at a pressure of 101 kPa it occupies a volume of \({\text{400 c}}{{\text{m}}^{\text{3}}}\).</p>
<p>(i) Calculate the molar mass of the compound, showing your working.</p>
<p> </p>
<p> </p>
<p> </p>
<p> </p>
<p> </p>
<p>(ii) Deduce the molecular formula of the compound.</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>\({{\text{C}}_{\text{5}}}{{\text{H}}_{{\text{12}}}}\) exists as three isomers. Identify the structure of the isomer with the <strong>lowest</strong> boiling point and explain your choice.</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>Ethanol is a primary alcohol that can be oxidized by acidified potassium dichromate(VI). Distinguish between the reaction conditions needed to produce ethanal and ethanoic acid.</p>
<p> </p>
<p>Ethanal:</p>
<p> </p>
<p> </p>
<p>Ethanoic acid:</p>
<div class="marks">[2]</div>
<div class="question_part_label">c.i.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Determine the oxidation number of carbon in ethanol and ethanal.</p>
<p> </p>
<p>Ethanol:</p>
<p> </p>
<p>Ethanal:</p>
<div class="marks">[2]</div>
<div class="question_part_label">c.ii.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Deduce the half-equation for the oxidation of ethanol to ethanal.</p>
<div class="marks">[1]</div>
<div class="question_part_label">c.iii.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Deduce the overall redox equation for the reaction of ethanol to ethanal with acidified potassium dichromate(VI) by combining your answer to part (c) (iii) with the following half-equation:</p>
<p>\[{\text{C}}{{\text{r}}_{\text{2}}}{\text{O}}_{\text{7}}^{2 - }{\text{(aq)}} + {\text{14}}{{\text{H}}^ + }{\text{(aq)}} + {\text{6}}{{\text{e}}^ - } \to {\text{2C}}{{\text{r}}^{3 + }}{\text{(aq)}} + {\text{7}}{{\text{H}}_{\text{2}}}{\text{O(l)}}\]</p>
<div class="marks">[2]</div>
<div class="question_part_label">c.iv.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Describe <strong>two </strong>characteristics of a reaction at equilibrium.</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>Describe how a catalyst increases the rate of a reaction.</p>
<div class="marks">[2]</div>
<div class="question_part_label">d.ii.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>State and explain the effect of a catalyst on the position of equilibrium.</p>
<div class="marks">[2]</div>
<div class="question_part_label">d.iii.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Ethanoic acid reacts with ethanol to form the ester ethyl ethanoate.</p>
<p>\[{\text{C}}{{\text{H}}_{\text{3}}}{\text{COOH(l)}} + {\text{C}}{{\text{H}}_{\text{3}}}{\text{C}}{{\text{H}}_{\text{2}}}{\text{OH(l)?????C}}{{\text{H}}_{\text{3}}}{\text{COOC}}{{\text{H}}_{\text{2}}}{\text{C}}{{\text{H}}_{\text{3}}}{\text{(l)}} + {{\text{H}}_{\text{2}}}{\text{O(l)}}\]</p>
<p>The esterification reaction is exothermic. State the effect of increasing temperature on the value of the equilibrium constant (\({K_{\text{c}}}\)) for this reaction.</p>
<div class="marks">[1]</div>
<div class="question_part_label">e.</div>
</div>
<br><hr><br><div class="specification">
<p>When nitrogen gas and hydrogen gas are allowed to react in a closed container, the following equilibrium is established.</p>
<p>\[{{\text{N}}_{\text{2}}}{\text{(g)}} + {\text{3}}{{\text{H}}_{\text{2}}}{\text{(g)}} \rightleftharpoons {\text{2N}}{{\text{H}}_{\text{3}}}{\text{(g)}}\;\;\;\;\;\Delta H = - 92.6{\text{ kJ}}\]</p>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Outline <strong>two </strong>characteristics of a reversible reaction in a state of dynamic equilibrium.</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>Deduce the equilibrium constant expression, \({K_{\text{c}}}\), for the reaction.</p>
<div class="marks">[1]</div>
<div class="question_part_label">b.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Predict, with a reason, how each of the following changes affects the position of equilibrium.</p>
<p> </p>
<p>The volume of the container is increased.</p>
<p> </p>
<p> </p>
<p>Ammonia is removed from the equilibrium mixture.</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>Define the term <em>activation energy</em>, \({E_{\text{a}}}\).</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>Ammonia is manufactured by the Haber process in which iron is used as a catalyst. Explain the effect of a catalyst on the rate of reaction.</p>
<div class="marks">[2]</div>
<div class="question_part_label">d.ii.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Sketch the Maxwell–Boltzmann energy distribution curve for a reaction, labelling both axes and showing the activation energy with and without a catalyst.</p>
<div class="marks">[2]</div>
<div class="question_part_label">d.iii.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Typical conditions used in the Haber process are 500 °C and 200 atm, resulting in approximately 15% yield of ammonia.</p>
<p>(i) Explain why a temperature lower than 500 °C is <strong>not </strong>used.</p>
<p> </p>
<p> </p>
<p> </p>
<p>(ii) Outline why a pressure higher than 200 atm is <strong>not </strong>often used.</p>
<div class="marks">[3]</div>
<div class="question_part_label">e.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Define the term <em>base </em>according to the Lewis theory.</p>
<div class="marks">[1]</div>
<div class="question_part_label">f.i.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Define the term <em>weak base </em>according to the Brønsted-Lowry theory.</p>
<div class="marks">[1]</div>
<div class="question_part_label">f.ii.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Deduce the formulas of conjugate acid-base pairs in the reaction below.</p>
<p>\[{\text{C}}{{\text{H}}_{\text{3}}}{\text{N}}{{\text{H}}_{\text{2}}}{\text{(aq)}} + {{\text{H}}_{\text{2}}}{\text{O(l)}} \rightleftharpoons {\text{C}}{{\text{H}}_{\text{3}}}{\text{NH}}_{\text{3}}^ + {\text{(aq)}} + {\text{O}}{{\text{H}}^ - }{\text{(aq)}}\]</p>
<p><img src="images/Schermafbeelding_2016-08-10_om_07.23.57.png" alt="M15/4/CHEMI/SP2/ENG/TZ2/05.f.iii"></p>
<div class="marks">[2]</div>
<div class="question_part_label">f.iii.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Outline an experiment and its results which could be used to distinguish between a strong base and a weak base.</p>
<div class="marks">[3]</div>
<div class="question_part_label">f.iv.</div>
</div>
<br><hr><br><div class="specification">
<p>Magnesium reacts with sulfuric acid:</p>
<p style="text-align: center;">Mg(s) + H<sub>2</sub>SO<sub>4</sub>(aq) → MgSO<sub>4</sub>(aq) + H<sub>2</sub>(g)</p>
<p>The graph shows the results of an experiment using excess magnesium ribbon and dilute sulfuric acid.</p>
<p style="text-align: center;"><img src="images/Schermafbeelding_2017-09-25_om_09.45.43.png" alt="M17/4/CHEMI/SP2/ENG/TZ2/05.a.i"></p>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Outline why the rate of the reaction decreases with time.</p>
<div class="marks">[1]</div>
<div class="question_part_label">a.i.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Sketch, on the same graph, the expected results if the experiment were repeated using powdered magnesium, keeping its mass and all other variables unchanged.</p>
<div class="marks">[1]</div>
<div class="question_part_label">a.ii.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Nitrogen dioxide and carbon monoxide react according to the following equation:</p>
<p style="text-align: center;">NO<sub>2</sub>(g) + CO(g) \( \rightleftharpoons \) NO(g) + CO<sub>2</sub>(g) Δ<em>H</em> = –226 kJ</p>
<p style="text-align: center;"><img src="data:image/png;base64,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"></p>
<p style="text-align: left;">Calculate the activation energy for the reverse reaction.</p>
<div class="marks">[1]</div>
<div class="question_part_label">b.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>State the equation for the reaction of NO<sub>2</sub> in the atmosphere to produce acid deposition.</p>
<div class="marks">[1]</div>
<div class="question_part_label">c.</div>
</div>
<br><hr><br><div class="specification">
<p>Sodium thiosulfate solution reacts with dilute hydrochloric acid to form a precipitate of sulfur at room temperature.</p>
<p style="text-align: center;">Na<sub>2</sub>S<sub>2</sub>O<sub>3</sub> (aq) + 2HCl (aq) → S (s) + SO<sub>2 </sub>(g) + 2NaCl (aq) + X</p>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Identify the formula and state symbol of X.</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>Suggest why the experiment should be carried out in a fume hood or in a well-ventilated laboratory.</p>
<div class="marks">[1]</div>
<div class="question_part_label">b.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>The precipitate of sulfur makes the mixture cloudy, so a mark underneath the reaction mixture becomes invisible with time.</p>
<p style="text-align: center;"><img src="data:image/png;base64,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" alt></p>
<p style="text-align: left;">10.0 cm<sup>3</sup> of 2.00 mol dm<sup>-3</sup> hydrochloric acid was added to a 50.0 cm<sup>3</sup> solution of sodium thiosulfate at temperature, T1. Students measured the time taken for the mark to be no longer visible to the naked eye. The experiment was repeated at different concentrations of sodium thiosulfate.</p>
<p style="text-align: left;"><img 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" alt></p>
<p style="text-align: left;">Show that the hydrochloric acid added to the flask in experiment 1 is in excess.</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>Draw the best fit line of \(\frac{1}{{\rm{t}}}\) against concentration of sodium thiosulfate on the axes provided.</p>
<p><img 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" alt></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>A student decided to carry out another experiment using 0.075 mol dm<sup>-3</sup> solution of sodium thiosulfate under the same conditions. Determine the time taken for the mark to be no longer visible.</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>An additional experiment was carried out at a higher temperature, T<sub>2</sub>.</p>
<p>(i) On the same axes, sketch Maxwell–Boltzmann energy distribution curves at the two temperatures T<sub>1</sub> and T<sub>2</sub>, where T<sub>2 </sub>> T<sub>1</sub>.</p>
<p><img src="data:image/png;base64,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" alt></p>
<p>(ii) Explain why a higher temperature causes the rate of reaction to increase.</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>Suggest one reason why the values of rates of reactions obtained at higher temperatures may be less accurate.</p>
<div class="marks">[1]</div>
<div class="question_part_label">g.</div>
</div>
<br><hr><br><div class="specification">
<p>Phosgene, COCl<sub>2</sub>, is usually produced by the reaction between carbon monoxide and chlorine according to the equation:</p>
<p><img src="data:image/png;base64,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" alt></p>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>(i) Deduce the equilibrium constant expression, <em>K</em><sub>c</sub>, for this reaction.</p>
<p>(ii) State the effect of an increase in the total pressure on the equilibrium constant, <em>K</em><sub>c</sub>.</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) Sketch the potential energy profile for the synthesis of phosgene, using the axes given, indicating both the enthalpy of reaction and activation energy.</p>
<p><img 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" alt></p>
<p>(ii) This reaction is normally carried out using a catalyst. Draw a dotted line labelled “Catalysed” on the diagram above to indicate the effect of the catalyst.</p>
<p>(iii) Sketch and label a second Maxwell–Boltzmann energy distribution curve representing the same system but at a higher temperature, T<sub>higher</sub>.</p>
<p><img 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" alt></p>
<p>(iv) Explain why an increase in temperature increases the rate of this reaction.</p>
<div class="marks">[6]</div>
<div class="question_part_label">b.</div>
</div>
<br><hr><br><div class="specification">
<p>A student titrated an ethanoic acid solution, CH<sub>3</sub>COOH (aq), against 50.0 cm<sup>3</sup> of 0.995 mol dm<sup>–3</sup> sodium hydroxide, NaOH (aq), to determine its concentration.</p>
<p>The temperature of the reaction mixture was measured after each acid addition and plotted against the volume of acid.</p>
<p><img 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"></p>
</div>
<div class="specification">
<p>Curves <strong>X</strong> and <strong>Y</strong> were obtained when a metal carbonate reacted with the same volume of ethanoic acid under two different conditions.</p>
<p style="text-align: center;"><img src="data:image/png;base64,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"></p>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Using the graph, estimate the initial temperature of the solution.</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>Determine the maximum temperature reached in the experiment by analysing the graph.</p>
<div class="marks">[1]</div>
<div class="question_part_label">b.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Calculate the concentration of ethanoic acid, CH<sub>3</sub>COOH, in mol dm<sup>–3</sup>.</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>Determine the heat change, <em>q</em>, in kJ, for the neutralization reaction between ethanoic acid and sodium hydroxide.</p>
<p>Assume the specific heat capacities of the solutions and their densities are those of water.</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>Calculate the enthalpy change, Δ<em>H</em>, in kJ mol<sup>–1</sup>, for the reaction between ethanoic acid and sodium hydroxide.</p>
<div class="marks">[2]</div>
<div class="question_part_label">d.ii.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Explain the shape of curve <strong>X</strong> in terms of the collision theory.</p>
<div class="marks">[2]</div>
<div class="question_part_label">e.i.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Suggest <strong>one</strong> possible reason for the differences between curves <strong>X</strong> and <strong>Y</strong>.</p>
<div class="marks">[1]</div>
<div class="question_part_label">e.ii.</div>
</div>
<br><hr><br>