File "SL-paper2.html"
Path: /IB QUESTIONBANKS/5 Fifth Edition - PAPER/HTML/Chemistry/Topic 7/SL-paper2html
File size: 227.69 KB
MIME-type: text/html
Charset: utf-8
<!DOCTYPE html>
<html>
<meta http-equiv="content-type" content="text/html;charset=utf-8">
<head>
<meta charset="utf-8">
<title>IB Questionbank</title>
<link rel="stylesheet" media="all" href="css/application-02ef852527079acf252dc4c9b2922c93db8fde2b6bff7c3c7f657634ae024ff1.css">
<link rel="stylesheet" media="print" href="css/print-6da094505524acaa25ea39a4dd5d6130a436fc43336c0bb89199951b860e98e9.css">
<script src="js/application-9717ccaf4d6f9e8b66ebc0e8784b3061d3f70414d8c920e3eeab2c58fdb8b7c9.js"></script>
<script type="text/javascript" async src="https://cdnjs.cloudflare.com/ajax/libs/mathjax/2.7.5/MathJax.js?config=TeX-MML-AM_CHTML-full"></script>
<!--[if lt IE 9]>
<script src='https://cdnjs.cloudflare.com/ajax/libs/html5shiv/3.7.3/html5shiv.min.js'></script>
<![endif]-->
<meta name="csrf-param" content="authenticity_token">
<meta name="csrf-token" content="iHF+M3VlRFlNEehLVICYgYgqiF8jIFlzjGNjIwqOK9cFH3ZNdavBJrv/YQpz8vcspoICfQcFHW8kSsHnJsBwfg==">
<link href="favicon.ico" rel="shortcut icon">
</head>
<body class="teacher questions-show">
<div class="navbar navbar-fixed-top">
<div class="navbar-inner">
<div class="container">
<div class="brand">
<div class="inner"><a href="http://ibo.org/">ibo.org</a></div>
</div>
<ul class="nav">
<li>
<a href="../../../../../../../index.html">Home</a>
</li>
<!-- - if current_user.is_language_services? && !current_user.is_publishing? -->
<!-- %li= link_to "Language services", tolk_path -->
</ul>
<ul class="nav pull-right">
<li class="dropdown">
<a class="dropdown-toggle" data-toggle="dropdown" href="#">
Help
<b class="caret"></b>
</a>
<ul class="dropdown-menu">
<li><a href="https://questionbank.ibo.org/video_tour?locale=en">Video tour</a></li>
<li><a href="https://questionbank.ibo.org/instructions?locale=en">Detailed instructions</a></li>
<li><a target="_blank" href="https://ibanswers.ibo.org/">IB Answers</a></li>
</ul>
</li>
<li>
<a href="https://06082010.xyz">IB Documents (2) Team</a>
</li></ul>
</div>
</div>
</div>
<div class="page-content container">
<div class="row">
<div class="span24">
<div class="pull-right screen_only"><a class="btn btn-small btn-info" href="https://questionbank.ibo.org/updates?locale=en">Updates to Questionbank</a></div>
<p class="muted language_chooser">
User interface language:
<a href="https://questionbank.ibo.org/en/users/set_user_locale?new_locale=en">English</a>
|
<a href="https://questionbank.ibo.org/en/users/set_user_locale?new_locale=es">Español</a>
</p>
</div>
</div>
<div class="page-header">
<div class="row">
<div class="span16">
<p class="back-to-list">
</p>
</div>
<div class="span8" style="margin: 0 0 -19px 0;">
<img style="width: 100%;" class="qb_logo" src="https://mirror.ibdocs.top/qb.png" alt="Ib qb 46 logo">
</div>
</div>
</div>
<h2>SL Paper 2</h2><div class="specification">
<p>Ethane-1,2-diol, HOCH<sub>2</sub>CH<sub>2</sub>OH, has a wide variety of uses including the removal of ice from aircraft and heat transfer in a solar cell.</p>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Ethane-1,2-diol can be formed according to the following reaction.</p>
<p>2CO (g) + 3H<sub>2 </sub>(g) <span class="mjpage"><math xmlns="http://www.w3.org/1998/Math/MathML" alttext=" \rightleftharpoons ">
<mo stretchy="false">⇌</mo>
</math></span> HOCH<sub>2</sub>CH<sub>2</sub>OH (g)</p>
<p>(i) Deduce the equilibrium constant expression, <em>K</em><sub>c</sub>, for this reaction.</p>
<p> </p>
<p>(ii) State how increasing the pressure of the reaction mixture at constant temperature will affect the position of equilibrium and the value of <em>K</em><sub>c</sub>.</p>
<p>Position of equilibrium:</p>
<p><em>K</em><sub>c</sub>:</p>
<p> </p>
<p>(iii) Calculate the enthalpy change, Δ<em>H</em><sup>θ</sup>, in kJ, for this reaction using section 11 of the data booklet. The bond enthalpy of the carbon–oxygen bond in CO (g) is 1077kJmol<sup>-1</sup>.</p>
<p> </p>
<p>(iv) The enthalpy change, ΔH<sup>θ</sup>, for the following similar reaction is –233.8 kJ.</p>
<p>2CO(g) + 3H<sub>2</sub>(g) <span class="mjpage"><math xmlns="http://www.w3.org/1998/Math/MathML" alttext=" \rightleftharpoons ">
<mo stretchy="false">⇌</mo>
</math></span> HOCH<sub>2</sub>CH<sub>2</sub>OH (l)</p>
<p>Deduce why this value differs from your answer to (a)(iii).</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>Determine the average oxidation state of carbon in ethene and in ethane-1,2-diol.</p>
<p>Ethene:</p>
<p>Ethane-1,2-diol:</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>Explain why the boiling point of ethane-1,2-diol is significantly greater than that of ethene.</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>Ethane-1,2-diol can be oxidized first to ethanedioic acid, (COOH)<sub>2</sub>, and then to carbon dioxide and water. Suggest the reagents to oxidize ethane-1,2-diol.</p>
<div class="marks">[1]</div>
<div class="question_part_label">d.</div>
</div>
<br><hr><br><div class="specification">
<p>Many reactions are in a state of equilibrium.</p>
</div>
<div class="specification">
<p>The equations for two acid-base reactions are given below.</p>
<p style="text-align: center;">HCO<sub>3</sub><sup>–</sup> (aq) + H<sub>2</sub>O (l) <span class="mjpage"><math xmlns="http://www.w3.org/1998/Math/MathML" alttext=" \rightleftharpoons ">
<mo stretchy="false">⇌<!-- ⇌ --></mo>
</math></span> H<sub>2</sub>CO<sub>3</sub> (aq) + OH<sup>–</sup> (aq)<br>HCO<sub>3</sub><sup>–</sup> (aq) + H<sub>2</sub>O (l) <span class="mjpage"><math xmlns="http://www.w3.org/1998/Math/MathML" alttext=" \rightleftharpoons ">
<mo stretchy="false">⇌<!-- ⇌ --></mo>
</math></span> CO<sub>3</sub><sup>2–</sup> (aq) + H<sub>3</sub>O<sup>+</sup> (aq)</p>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>The following reaction was allowed to reach equilibrium at 761 K.</p>
<p>H<sub>2</sub> (g) + I<sub>2</sub> (g) <span class="mjpage"><math xmlns="http://www.w3.org/1998/Math/MathML" alttext=" \rightleftharpoons ">
<mo stretchy="false">⇌</mo>
</math></span> 2HI (g) Δ<em>H</em><sup>θ</sup> < 0</p>
<p>Outline the effect, if any, of each of the following changes on the position of equilibrium, giving a reason in each case.</p>
<p><img src="data:image/png;base64,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"></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>Identify two different amphiprotic species in the above reactions.</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 what is meant by the term conjugate base.</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>State the conjugate base of the hydroxide ion, OH<sup>–</sup>.</p>
<div class="marks">[1]</div>
<div class="question_part_label">b.iii.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>A student working in the laboratory classified HNO<sub>3</sub>, H<sub>2</sub>SO<sub>4</sub>, H<sub>3</sub>PO<sub>4</sub> and HClO<sub>4</sub> as acids based on their pH. He hypothesized that “all acids contain oxygen and hydrogen”.</p>
<p>Evaluate his hypothesis.</p>
<div class="marks">[2]</div>
<div class="question_part_label">c.</div>
</div>
<br><hr><br><div class="specification">
<p>White phosphorus is an allotrope of phosphorus and exists as P<sub>4</sub>.</p>
</div>
<div class="specification">
<p>An equilibrium exists between PCl<sub>3</sub> and PCl<sub>5</sub>.</p>
<p style="text-align: center;">PCl<sub>3 </sub>(g) + Cl<sub>2 </sub>(g) <math xmlns="http://www.w3.org/1998/Math/MathML" class="wrs_chemistry"><mo>⇌</mo></math> PCl<sub>5 </sub>(g)</p>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Sketch the Lewis (electron dot) structure of the P<sub>4</sub> molecule, containing only single bonds.</p>
<p> </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>Write an equation for the reaction of white phosphorus (P<sub>4</sub>) with chlorine gas to form phosphorus trichloride (PCl<sub>3</sub>).</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>Deduce the electron domain and molecular geometry using VSEPR theory, and estimate the Cl–P–Cl bond angle in PCl<sub>3</sub>.</p>
<p><img src="data:image/png;base64,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"></p>
<div class="marks">[3]</div>
<div class="question_part_label">b(i).</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Explain the polarity of PCl<sub>3</sub>.</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>Calculate the standard enthalpy change (<em>ΔH</em><sup>⦵</sup>) for the forward reaction in kJ mol<sup>−1</sup>.</p>
<p style="text-align:center;"><em>ΔH</em><sup>⦵</sup><sub>f</sub> PCl<sub>3 </sub>(g) = −306.4 kJ mol<sup>−1</sup></p>
<p style="text-align:center;"><em>ΔH</em><sup>⦵</sup><sub>f</sub> PCl<sub>5 </sub>(g) = −398.9 kJ mol<sup>−1</sup></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>State the equilibrium constant expression,<em> K</em><sub>c</sub>, 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>State, with a reason, the effect of an increase in temperature on the position of this equilibrium.</p>
<div class="marks">[1]</div>
<div class="question_part_label">c(iii).</div>
</div>
<br><hr><br><div class="specification">
<p>A mixture of 1.00 mol SO<sub>2</sub>(g), 2.00 mol O<sub>2</sub>(g) and 1.00 mol SO<sub>3</sub>(g) is placed in a 1.00 dm<sup>3</sup> container and allowed to reach equilibrium.</p>
<p style="text-align: center;">2SO<sub>2</sub>(g) + O<sub>2</sub>(g) <span class="mjpage"><math xmlns="http://www.w3.org/1998/Math/MathML" alttext=" \rightleftharpoons ">
<mo stretchy="false">⇌<!-- ⇌ --></mo>
</math></span> 2SO<sub>3</sub>(g)</p>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Distinguish between the terms reaction quotient, <em>Q, </em>and equilibrium constant, <em>K</em><sub>c</sub>.</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 equilibrium constant, <em>K</em><sub>c</sub>, is 0.282 at temperature T.</p>
<p>Deduce, showing your work, the direction of the initial reaction.</p>
<div class="marks">[2]</div>
<div class="question_part_label">b.</div>
</div>
<br><hr><br><div class="specification">
<p>PCl<sub>5</sub>(g) and Cl<sub>2</sub>(g) were placed in a sealed flask and allowed to reach equilibrium at 200 °C. The enthalpy change, Δ<em>H</em>, for the decomposition of PCl<sub>5</sub>(g) is positive.</p>
<p style="text-align: center;"><img src="images/Schermafbeelding_2017-09-21_om_08.14.28.png" alt="M17/4/CHEMI/SP2/ENG/TZ2/03"></p>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Deduce the equilibrium constant expression, <em>K</em><sub>c</sub>, for the decomposition of PCl<sub>5</sub>(g).</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>Deduce, giving a reason, the factor responsible for establishing the new equilibrium after 14 minutes.</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>Deduce the Lewis (electron dot) structure and molecular geometry of PCl<sub>3</sub>.</p>
<p><img src="data:image/png;base64,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"></p>
<div class="marks">[2]</div>
<div class="question_part_label">b.</div>
</div>
<br><hr><br><div class="specification">
<p>Two hydrides of nitrogen are ammonia and hydrazine, N<sub>2</sub>H<sub>4</sub>. One derivative of ammonia is methanamine whose molecular structure is shown below.</p>
<p style="text-align: center;"><img src="images/Schermafbeelding_2017-09-22_om_18.03.06.png" alt="M17/4/CHEMI/SP2/ENG/TZ1/04"></p>
</div>
<div class="specification">
<p>Hydrazine is used to remove oxygen from water used to generate steam or hot water.</p>
<p style="text-align: center;">N<sub>2</sub>H<sub>4</sub>(aq) + O<sub>2</sub>(aq) → N<sub>2</sub>(g) + 2H<sub>2</sub>O(l)</p>
<p>The concentration of dissolved oxygen in a sample of water is 8.0 × 10<sup>−3</sup> g<span class="mjpage"><math xmlns="http://www.w3.org/1998/Math/MathML" alttext="\,">
<mspace width="thinmathspace"></mspace>
</math></span>dm<sup>−3</sup>.</p>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Estimate the H−N−H bond angle in methanamine using VSEPR theory.</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>Ammonia reacts reversibly with water.</p>
<p>NH<sub>3</sub>(g) + H<sub>2</sub>O(l) <span class="mjpage"><math xmlns="http://www.w3.org/1998/Math/MathML" alttext=" \rightleftharpoons ">
<mo stretchy="false">⇌</mo>
</math></span> NH<sub>4</sub><sup>+</sup>(aq) + OH<sup>−</sup>(aq)</p>
<p>Explain the effect of adding H<sup>+</sup>(aq) ions on the position of the equilibrium.</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>Hydrazine reacts with water in a similar way to ammonia. Deduce an equation for the reaction of hydrazine with water.</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, using an ionic equation, what is observed when magnesium powder is added to a solution of ammonium chloride.</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>Hydrazine has been used as a rocket fuel. The propulsion reaction occurs in several stages but the overall reaction is:</p>
<p>N<sub>2</sub>H<sub>4</sub>(l) → N<sub>2</sub>(g) + 2H<sub>2</sub>(g)</p>
<p>Suggest why this fuel is suitable for use at high altitudes.</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>Determine the enthalpy change of reaction, Δ<em>H</em>, in kJ, when 1.00 mol of gaseous hydrazine decomposes to its elements. Use bond enthalpy values in section 11 of the data booklet.</p>
<p>N<sub>2</sub>H<sub>4</sub>(g) → N<sub>2</sub>(g) + 2H<sub>2</sub>(g)</p>
<div class="marks">[3]</div>
<div class="question_part_label">f.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>The standard enthalpy of formation of N<sub>2</sub>H<sub>4</sub>(l) is +50.6 kJ<span class="mjpage"><math xmlns="http://www.w3.org/1998/Math/MathML" alttext="\,">
<mspace width="thinmathspace"></mspace>
</math></span>mol<sup>−1</sup>. Calculate the enthalpy of vaporization, Δ<em>H</em><sub>vap</sub>, of hydrazine in kJ<span class="mjpage"><math xmlns="http://www.w3.org/1998/Math/MathML" alttext="\,">
<mspace width="thinmathspace"></mspace>
</math></span>mol<sup>−1</sup>.</p>
<p>N<sub>2</sub>H<sub>4</sub>(l) → N<sub>2</sub>H<sub>4</sub>(g)</p>
<p>(If you did not get an answer to (f), use −85 kJ but this is not the correct answer.)</p>
<div class="marks">[2]</div>
<div class="question_part_label">g.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Calculate, showing your working, the mass of hydrazine needed to remove all the dissolved oxygen from 1000 dm<sup>3</sup> of the sample.</p>
<div class="marks">[3]</div>
<div class="question_part_label">h.i.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Calculate the volume, in dm<sup>3</sup>, of nitrogen formed under SATP conditions. (The volume of 1 mol of gas = 24.8 dm<sup>3</sup> at SATP.)</p>
<div class="marks">[1]</div>
<div class="question_part_label">h.ii.</div>
</div>
<br><hr><br><div class="specification">
<p>Urea, (H<sub>2</sub>N)<sub>2</sub>CO, is excreted by mammals and can be used as a fertilizer.</p>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Calculate the percentage by mass of nitrogen in urea to two decimal places using section 6 of the data booklet.</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>Suggest how the percentage of nitrogen affects the cost of transport of fertilizers giving a reason.</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>The structural formula of urea is shown.</p>
<p><img src="images/Schermafbeelding_2018-08-09_om_13.51.02.png" alt="M18/4/CHEMI/SP2/ENG/TZ1/01.b_01"></p>
<p>Predict the electron domain and molecular geometries at the nitrogen and carbon atoms, applying the VSEPR theory.</p>
<p><img src="images/Schermafbeelding_2018-08-09_om_13.52.37.png" alt="M18/4/CHEMI/SP2/ENG/TZ1/01.b_02"></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>Urea can be made by reacting potassium cyanate, KNCO, with ammonium chloride, NH<sub>4</sub>Cl.</p>
<p> KNCO(aq) + NH<sub>4</sub>Cl(aq) → (H<sub>2</sub>N)<sub>2</sub>CO(aq) + KCl(aq)</p>
<p>Determine the maximum mass of urea that could be formed from 50.0 cm<sup>3</sup> of 0.100 mol dm<sup>−3</sup> potassium cyanate solution.</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>Urea can also be made by the direct combination of ammonia and carbon dioxide gases.</p>
<p> 2NH<sub>3</sub>(g) + CO<sub>2</sub>(g) <span class="mjpage"><math xmlns="http://www.w3.org/1998/Math/MathML" alttext=" \rightleftharpoons ">
<mo stretchy="false">⇌</mo>
</math></span> (H<sub>2</sub>N)<sub>2</sub>CO(g) + H<sub>2</sub>O(g) Δ<em>H </em>< 0</p>
<p>Predict, with a reason, the effect on the equilibrium constant, <em>K</em><sub>c</sub>, when the temperature is increased.</p>
<div class="marks">[1]</div>
<div class="question_part_label">d.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Suggest one reason why urea is a solid and ammonia a gas at room temperature.</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>Sketch <strong>two </strong>different hydrogen bonding interactions between ammonia and water.</p>
<div class="marks">[2]</div>
<div class="question_part_label">e.ii.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>The combustion of urea produces water, carbon dioxide and nitrogen.</p>
<p>Formulate a balanced equation for the reaction.</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>The mass spectrum of urea is shown below.</p>
<p><img src="images/Schermafbeelding_2018-08-09_om_14.15.23.png" alt="M18/4/CHEMI/SP2/ENG/TZ1/01.g_01"></p>
<p>Identify the species responsible for the peaks at <em>m</em>/<em>z </em>= 60 and 44.</p>
<p><img src="data:image/png;base64,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"></p>
<p> </p>
<div class="marks">[2]</div>
<div class="question_part_label">g.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>The IR spectrum of urea is shown below.</p>
<p><img src="images/Schermafbeelding_2018-08-09_om_14.21.30.png" alt="M18/4/CHEMI/SP2/ENG/TZ1/01.h_01"></p>
<p>Identify the bonds causing the absorptions at 3450 cm<sup>−1</sup> and 1700 cm<sup>−1</sup> using section 26 of the data booklet.</p>
<p><img src="data:image/png;base64,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"></p>
<p> </p>
<div class="marks">[2]</div>
<div class="question_part_label">h.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Predict the number of signals in the <sup>1</sup>H NMR spectrum of urea.</p>
<div class="marks">[1]</div>
<div class="question_part_label">i.</div>
</div>
<br><hr><br><div class="specification">
<p><span class="fontstyle0">Compound </span><strong><span class="fontstyle2">A </span></strong><span class="fontstyle0">is in equilibrium with compound </span><span class="fontstyle2"><strong>B</strong>.</span></p>
<p><span class="fontstyle2"><img style="display: block; margin-left: auto; margin-right: auto;" src="data:image/png;base64,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" width="247" height="82"></span></p>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p><span class="fontstyle0">Predict the electron domain and molecular geometries around the </span><span class="fontstyle2"><strong>oxygen</strong> </span><span class="fontstyle0">atom of molecule </span><strong><span class="fontstyle2">A </span></strong><span class="fontstyle0">using VSEPR.</span></p>
<p><span class="fontstyle0"><img src="data:image/png;base64,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" width="734" height="185"></span></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><span class="fontstyle0">The IR spectrum of one of the compounds is shown:</span></p>
<p><img src="data:image/png;base64,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" width="687" height="247"></p>
<p style="text-align: center;"><em><span class="fontstyle0">COBLENTZ SOCIETY. Collection © 2018 copyright by the U.S. Secretary of Commerce on behalf of the United States of America. All rights reserved.</span></em></p>
<p><span class="fontstyle0"><br>Deduce, giving a reason, the compound producing this spectrum.</span></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><span class="fontstyle0">Compound </span><strong><span class="fontstyle2">A </span></strong><span class="fontstyle0">and </span><strong><span class="fontstyle2">B </span></strong><span class="fontstyle0">are isomers. Draw two other structural isomers with the formula <math xmlns="http://www.w3.org/1998/Math/MathML" class="wrs_chemistry"><msub><mi mathvariant="normal">C</mi><mn>3</mn></msub><msub><mi mathvariant="normal">H</mi><mn>6</mn></msub><mi mathvariant="normal">O</mi></math></span><span class="fontstyle0">.</span></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><span class="fontstyle0">The equilibrium constant, </span><math xmlns="http://www.w3.org/1998/Math/MathML" class="wrs_chemistry"><msub><mi>K</mi><mi mathvariant="normal">c</mi></msub></math><span class="fontstyle0">, for the conversion of </span><strong><span class="fontstyle3">A </span></strong><span class="fontstyle0">to </span><strong><span class="fontstyle3">B </span></strong><span class="fontstyle0">is </span><math xmlns="http://www.w3.org/1998/Math/MathML"><mn>1</mn><mo>.</mo><mn>0</mn><mo>×</mo><msup><mn>10</mn><mn>8</mn></msup></math> <span class="fontstyle0">in water at <math xmlns="http://www.w3.org/1998/Math/MathML" class="wrs_chemistry"><mn>298</mn><mo> </mo><mi mathvariant="normal">K</mi></math>.</span></p>
<p><span class="fontstyle0">Deduce, giving a reason, which compound, </span><strong><span class="fontstyle3">A </span></strong><span class="fontstyle0">or </span><strong><span class="fontstyle3">B</span></strong><span class="fontstyle0">, is present in greater concentration when equilibrium is reached.</span></p>
<div class="marks">[1]</div>
<div class="question_part_label">d.</div>
</div>
<br><hr><br><div class="specification">
<p>The properties of elements can be predicted from their position in the periodic table.</p>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Explain why Si has a smaller atomic radius than Al.</p>
<div class="marks">[2]</div>
<div class="question_part_label">a(i).</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Explain the decrease in radius from Na to Na<sup>+</sup>.</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>State the condensed electron configurations for Cr and Cr3<sup>+</sup>.</p>
<p><img src="data:image/png;base64,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" width="768" height="190"></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>Describe metallic bonding and how it contributes to electrical conductivity.</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>Deduce the Lewis (electron dot) structure and molecular geometry of sulfur dichloride, SCl<sub>2</sub>.</p>
<p><img src="data:image/png;base64,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" width="433" height="216"></p>
<div class="marks">[2]</div>
<div class="question_part_label">c.</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Suggest, giving reasons, the relative volatilities of SCl<sub>2</sub> and H<sub>2</sub>O.</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>Consider the following equilibrium reaction:</p>
<p style="text-align:center;">2SO<sub>2 </sub>(g) + O<sub>2 </sub>(g) <math xmlns="http://www.w3.org/1998/Math/MathML" class="wrs_chemistry"><mo>⇌</mo></math> 2SO<sub>3 </sub>(g)</p>
<p>State and explain how the equilibrium would be affected by increasing the volume of the reaction container at a constant temperature.</p>
<div class="marks">[3]</div>
<div class="question_part_label">e.</div>
</div>
<br><hr><br><div class="specification">
<p>Hydrogen peroxide can react with methane and oxygen to form methanol. This reaction can occur below 50°C if a gold nanoparticle catalyst is used.</p>
</div>
<div class="specification">
<p>Methanol is usually manufactured from methane in a two-stage process.</p>
<p style="text-align: center;">CH<sub>4 </sub>(g) + H<sub>2</sub>O (g) <math xmlns="http://www.w3.org/1998/Math/MathML" class="wrs_chemistry"><mo>⇌</mo></math> CO (g) + 3H<sub>2 </sub>(g)<br>CO (g) + 2H<sub>2 </sub>(g) <math xmlns="http://www.w3.org/1998/Math/MathML" class="wrs_chemistry"><mo>⇌</mo></math> CH<sub>3</sub>OH (l)</p>
</div>
<div class="specification">
<p>Consider the first stage of the reaction.</p>
<p style="text-align: center;">CH<sub>4 </sub>(g) + H<sub>2</sub>O (g) <math xmlns="http://www.w3.org/1998/Math/MathML" class="wrs_chemistry"><mo>⇌</mo></math> CO (g) + 3H<sub>2 </sub>(g)</p>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>The diagram shows the Maxwell-Boltzmann curve for the uncatalyzed reaction.</p>
<p>Draw a distribution curve at a lower temperature (T<sub>2</sub>) <strong>and</strong> show on the diagram how the addition of a catalyst enables the reaction to take place more rapidly than at T<sub>1</sub>.</p>
<p><img style="display:block;margin-left:auto;margin-right:auto;" src="data:image/png;base64,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" width="486" height="385"></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>The hydrogen peroxide could cause further oxidation of the methanol. Suggest a possible oxidation product.</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>Determine the overall equation for the production of methanol.</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>8.00 g of methane is completely converted to methanol. Calculate, to three significant figures, the final volume of hydrogen at STP, in dm<sup>3</sup>. Use sections 2 and 6 of the data booklet.</p>
<div class="marks">[3]</div>
<div class="question_part_label">c(ii).</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>Determine the enthalpy change, Δ<em>H</em>, in kJ. Use section 11 of the data booklet.</p>
<p>Bond enthalpy of CO = 1077 kJ mol<sup>−1</sup>.</p>
<div class="marks">[3]</div>
<div class="question_part_label">d(i).</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>State the expression for <em>K</em><sub>c</sub> for this stage of the reaction.</p>
<div class="marks">[1]</div>
<div class="question_part_label">d(ii).</div>
</div>
<div class="question" style="padding-left: 20px; padding-right: 20px;">
<p>State and explain the effect of increasing temperature on the value of <em>K<sub>c</sub></em>.</p>
<div class="marks">[1]</div>
<div class="question_part_label">d(iii).</div>
</div>
<br><hr><br>