Chemistry and chemical reactivity 8e by kotz, terichel and townsend 1 pdf

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Periodic Table of the Elements Hydrogen H MAIN GROUP METALS 1.0079 1A (1) 2A (2) Lithium Beryllium Li TRANSITION METALS Uranium 92 U METALLOIDS Be 6.941 9.0122 Sodium Magnesium 12 11 Na Mg 3B (3) 4B (4) 5B (5) 6B (6) 7B (7) 22.9898 24.3050 Potassium 19 Calcium 20 Scandium Titanium Vanadium Chromium Manganese 22 23 24 25 21 39.0983 40.078 44.9559 K Ca Rubidium Strontium 37 38 Rb Sr Sc Yttrium 39 Ti 47.867 V 50.9415 Cr 51.9961 Mn 54.9380 Y Zr Nb Hf Ta Tc W Re 132.9055 Francium 87 137.327 138.9055 178.49 180.9479 183.84 186.207 Radium Actinium Rutherfordium Dubnium Seaborgium Bohrium 105 107 104 106 88 89 Fr Ra 88.9059 91.224 92.9064 Lanthanum Hafnium Tantalum 57 72 73 Mo 87.62 Barium 56 Ba La Ac (223.02) (226.0254) (227.0278) Note: Atomic masses are 2007 IUPAC values (up to four decimal places) Numbers in parentheses are atomic masses or mass numbers of the most stable isotope of an element kotz_48288_00a_ EP2-3_SE.indd Atomic weight 8B (8) (9) (10) 1B (11) Iron 26 Cobalt 27 Nickel 28 Copper 29 55.845 58.9332 58.6934 63.546 Fe Co Ni Zirconium Niobium Molybdenum Technetium Ruthenium Rhodium Palladium 45 41 42 43 40 44 46 85.4678 Cesium 55 Cs Symbol 238.0289 NONMETALS Atomic number Rf (267) Lanthanides Actinides Db (268) 95.96 (97.907) Tungsten Rhenium 75 74 Sg (271) Bh (272) Ru 101.07 Osmium 76 Os Rh Pd Ir Pt Cu Silver 47 Ag 102.9055 106.42 107.8682 Iridium Platinum Gold 77 79 78 Au 190.23 192.22 195.084 196.9666 Hassium Meitnerium Darmstadtium Roentgenium 109 110 111 108 Hs (270) Mt (276) Ds (281) Rg (280) Cerium 58 Praseodymium Neodymium Promethium Samarium Europium Gadolinium 59 60 61 64 63 62 140.116 140.9076 Ce Pr Nd 144.242 Pm (144.91) Sm 150.36 Eu 151.964 Thorium Protactinium Uranium Neptunium Plutonium Americium 92 94 91 90 93 95 Th Pa U Np Pu Am Gd 157.25 Curium 96 Cm 232.0381 231.0359 238.0289 (237.0482) (244.664) (243.061) (247.07) 11/22/10 1:37 PM 8A (18) Helium He 3A (13) 4A (14) 5A (15) 6A (16) 7A (17) 4.0026 Boron Carbon Nitrogen Oxygen Fluorine Neon 10 10.811 Aluminum 13 12.011 Silicon 14 14.0067 15.9994 Phosphorus Sulfur 15 16 18.9984 Chlorine 17 20.1797 Argon 18 2B (12) 26.9815 28.0855 30.9738 32.066 35.4527 39.948 Zinc 30 Gallium 31 Germanium 32 Arsenic 33 Selenium 34 Bromine 35 Krypton 36 65.38 69.723 72.61 74.9216 78.96 79.904 83.80 Cadmium 48 Indium 49 Tin 50 Iodine 53 Xenon 54 112.411 Mercury 80 114.818 Thallium 81 118.710 Lead 82 200.59 204.3833 207.2 B Zn Cd Hg Copernicium 112 Cn (285) Al Ga In Tl C Si Ge Sn Pb Tb P As O S Se Antimony Tellurium 51 52 Sb 121.760 Bismuth 83 Bi Te F Cl Br I 127.60 126.9045 Polonium Astatine 84 85 Po At 208.9804 (208.98) (209.99) Ne Ar Kr Xe 131.29 Radon 86 Rn (222.02) Ununtrium Ununquadium Ununpentium Ununhexium Ununseptium Ununoctium 113 114 115 116 117 118 Uut Discovered 2004 Uuq Discovered 1999 Terbium Dysprosium Holmium 66 67 65 158.9254 N Dy 162.50 Ho 164.9303 Uup Uuh Uus Uuo Discovered 2004 Discovered 1999 Discovered 2010 Erbium 68 Thulium 69 Ytterbium Lutetium 71 70 167.26 168.9342 173.054 174.9668 Er Tm Yb Discovered 2002 Lu Standard Colors for Atoms in Molecular Models carbon atoms hydrogen atoms oxygen atoms Berkelium Californium Einsteinium Fermium Mendelevium Nobelium Lawrencium 97 100 102 98 99 101 103 nitrogen atoms (247.07) chlorine atoms Bk kotz_48288_00a_ EP2-3_SE.indd Cf Es (251.08) (252.08) Fm Md (257.10) (258.10) No Lr (259.10) (262.11) 11/22/10 1:37 PM Get a Better Grade in Chemistry! Log in now to the #1 online homework and tutorial system for chemistry Score better on exams, get homework help, and more! • Master chemistry and improve your grade using OWL’s step-by-step tutorials, interactive simulations, and homework questions that provide instant answer-specific feedback Available 24/7 • Learn at your own pace with OWL, a study smart system that ensures you’ve mastered each concept before you move on • Access an e-version of your textbook enhanced with videos and animations, highlighting, the ability to add notes, and more To get started, use the access code that may have been packaged with your text or purchase access online Check with your instructor to verify that OWL is required for your course before purchasing www.cengage.com/OWL kotz_48288_00a_ EP4_SE.indd 11/22/10 1:40 PM This page intentionally left blank eighth edition chemistry & Chemical Reactivity John C Kotz State University of New York College at Oneonta Paul M Treichel University of Wisconsin–Madison John R Townsend West Chester University of Pennsylvania Australia • Brazil • Japan • Korea • Mexico • Singapore • Spain • United Kingdom • United States kotz_48288_00c_FM_i-xxxiii.indd 11/23/10 1:25 PM This is an electronic version of the print textbook Due to electronic rights restrictions, some third party content may be suppressed Editorial review has deemed that any suppressed content does not materially affect the overall learning experience The publisher reserves the right to remove content from this title at any time if subsequent rights restrictions require it For valuable information on pricing, previous editions, changes to current editions, and alternate formats, please visit www.cengage.com/highered to search by ISBN#, author, title, or keyword for materials in your areas of interest Copyright 2011 Cengage Learning All Rights Reserved May not be copied, scanned, or duplicated, in whole or in part Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s) Editorial review has deemed that any suppressed content does not materially affect the overall learning experience Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it Chemistry & Chemical Reactivity, Eighth Edition John C Kotz, Paul M Treichel, John R Townsend Publisher: Mary Finch Executive Editor: Lisa Lockwood Senior Developmental Editor: Peter McGahey Assistant Editor: Elizabeth Woods Editorial Assistant: Krista Mastroianni Senior Media Editor: Lisa Weber Media Editor: Stephanie Van Camp Senior Marketing Manager: Nicole Hamm Marketing Coordinator: Julie Stefani Marketing Communications Manager: Linda Yip © 2012, 2009 Brooks/Cole, Cengage Learning ALL RIGHTS RESERVED No part of this work covered by the copyright herein may be reproduced, transmitted, stored, or used in any form or by any means, graphic, electronic, or mechanical, including but not limited to photocopying, recording, scanning, digitizing, taping, Web distribution, information networks, or information storage and retrieval systems, except as permitted under Section 107 or 108 of the 1976 United States Copyright Act, without the prior written permission of the publisher For product information and technology assistance, contact us at Cengage Learning Customer & Sales Support, 1-800-354-9706 For permission to use material from this text or product, submit all requests online at www.cengage.com/permissions Further permissions questions can be emailed to permissionrequest@cengage.com Content Project Manager: Teresa L Trego Design Director: Rob Hugel Art Director: John Walker Print Buyer: Rebecca Cross Rights Acquisitions Specialist: Dean Dauphinais Production Service: Graphic World Inc Text Designer: Jeanne Calabrese Art Editor: Patrick Harman Photo Researcher: Scott Rosen Text Researcher: Sue Howard Library of Congress Control Number: 2010938984 ISBN-13: 978-0-8400-4828-8 ISBN-10: 0-8400-4828-9 Brooks/Cole 20 Davis Drive Belmont, CA 94002-3098 USA Copy Editor: Graphic World Inc Illustrator: Patrick Harman/Graphic World Inc OWL producers: Stephen Battisti, Cindy Stein, David Hart (Center for Educational Software Development, University of Massachusetts, Amherst) Cover Designer: Riezebos Holzbaur/Tim Heraldo Cengage Learning is a leading provider of customized learning solutions with office locations around the globe, including Singapore, the United Kingdom, Australia, Mexico, Brazil, and Japan Locate your local office at www.cengage.com/global Cengage Learning products are represented in Canada by Nelson Education, Ltd Cover Image: Joanna Aizenberg Rights-Managed Compositor: Graphic World Inc To learn more about Brooks/Cole, visit www.cengage.com/brookscole Purchase any of our products at your local college store or at our preferred online store www.CengageBrain.com Printed in the United States of America 1  2  3  4  5  6  7  14  13  12  11  10 kotz_48288_00c_FM_i-xxxiii.indd 11/19/10 12:11 PM brief contents 18 Principles of Chemical Reactivity: Other Aspects of Aqueous Equilibria  806 Part ONE The Basic Tools of Chemistry Basic Concepts of Chemistry  Let’s Review: The Tools of Quantitative Chemistry  Atoms, Molecules, and Ions  Chemical Reactions  Stoichiometry: Quantitative Information about Chemical Reactions  156 Principles of Chemical Reactivity: Energy and Chemical Reactions  208 Interchapter: The Chemistry of Fuels and Energy Resources  252 24 19 Principles of Chemical Reactivity: Entropy and Free Energy  858 20 Principles of Chemical Reactivity: Electron Transfer Reactions  894 50 110 The Structure of Atoms  The Structure of Atoms and Periodic Trends  21 The Chemistry of the Main Group Elements  22 The Chemistry of the Transition Elements  23 Nuclear Chemistry  960 1016 1058 Appendices 266 A Using Logarithms and Solving Quadratic Equations  300 B Some Important Physical Concepts  Interchapter: Milestones in the Development of Chemistry and the Modern View of Atoms and Molecules  334 C Abbreviations and Useful Conversion Factors  D Physical Constants  Bonding and Molecular Structure  E A Brief Guide to Naming Organic Compounds  Bonding and Molecular Structure: Orbital Hybridization and Molecular Orbitals  400 F Values for the Ionization Energies and Electron Attachment Enthalpies of the Elements  A-18 G Vapor Pressure of Water at Various Temperatures  H Ionization Constants for Aqueous Weak Acids at 25 °C  A-20 I Ionization Constants for Aqueous Weak Bases at 25 °C  A-22 J Solubility Product Constants for Some Inorganic Compounds at 25 °C  A-23 K Formation Constants for Some Complex Ions in Aqueous Solution at 25 °C  A-25 L Selected Thermodynamic Values  10 Carbon: Not Just Another Element  344 438 Interchapter: The Chemistry of Life: Biochemistry  490 Part THREE States of Matter 11 Gases and Their Properties  508 12 Intermolecular Forces and Liquids  13 The Chemistry of Solids  548 582 14 Solutions and Their Behavior  616 Interchapter: The Chemistry of Modern Materials  656 15 Chemical Kinetics: The Rates of Chemical Reactions  668 720 17 Principles of Chemical Reactivity: The Chemistry of Acids and Bases  756 kotz_48288_00c_FM_i-xxxiii.indd A-2 A-6 A-9 A-13 A-15 A-19 A-26 M Standard Reduction Potentials in Aqueous Solution at 25°C  A-32 Part FOUR The Control of Chemical Reactions 16 Principles of Chemical Reactivity: Equilibria  946 Part FIVE The Chemistry of the Elements and Their Compounds Part TWO The Structure of Atoms and Molecules Interchapter: The Chemistry of the Environment  N Answers to Chapter Opening Questions and Case Study Questions  A-36 O Answers to Check Your Understanding Questions  P Answers to Review & Check Questions  Q Answers to Selected Interchapter Study Questions  A-72 R Answers to Selected Study Questions  A-47 A-63 A-75 iii 11/19/10 12:11 PM iv contents Preface  xvii Part ONE The Basic Tools of Chemistry  Basic Concepts of Chemistry  Gold!  1.1 Chemistry and Its Methods  Hypotheses, Laws, and Theories  A Closer Look: Careers in Chemistry  Goals of Science  Dilemmas and Integrity in Science  Mathematics of Chemistry  33 Exponential or Scientific Notation  33 Significant Figures  35 Problem Solving by Dimensional Analysis  39 Case Study: Out of Gas!  40 Graphs and Graphing  41 Problem Solving and Chemical Arithmetic  42 1.2 Sustainability and Green Chemistry  A Closer Look: Principles of Green Chemistry  1.3 Classifying Matter  States of Matter and Kinetic-Molecular Theory  Matter at the Macroscopic and Particulate Levels  Pure Substances  Mixtures: Homogeneous and Heterogeneous  1.4 Elements  10 A Closer Look: Element Names and Symbols  11 1.5 Compounds  12 1.6 Physical Properties  13 Extensive and Intensive Properties  14 1.7 Physical and Chemical Changes  15 1.8 Energy: Some Basic Principles  16 Case Study: CO2 in the Oceans  17 Conservation of Energy  18 Study Questions  44 Atoms, Molecules, and Ions  The Periodic Table, the Central Icon of Chemistry  50 2.1 Atomic Structure—Protons, Electrons, and Neutrons  51 2.2 Atomic Number and Atomic Mass  52 Atomic Number  52 Relative Atomic Mass and the Atomic Mass Unit  52 Mass Number  52 2.3 Isotopes  54 Isotope Abundance  54 Determining Atomic Mass and Isotope Abundance  54 2.4 Atomic Weight  55 Case Study: Using Isotopes: Ötzi, the Iceman of the Alps  58 2.5 The Periodic Table  58 Developing the Periodic Table  58 A Closer Look: The Story of the Periodic Table  59 Features of the Periodic Table  61 A Brief Overview of the Periodic Table and the Chemical Elements  62 Chapter Goals Revisited  19 Key Equation  19 Study Questions  20 50 Let’s Review: The Tools of Quantitative Chemistry  24 2.6 Molecules, Compounds, and Formulas  66 Formulas  66 Molecular Models  68 Copper  24 2.7 Units of Measurement  25 Temperature Scales  25 Length, Volume, and Mass  27 A Closer Look: Energy and Food  29 Energy Units  29 Ionic Compounds: Formulas, Names, and Properties  69 Ions  69 Formulas of Ionic Compounds  73 Names of Ions  74 Properties of Ionic Compounds  76 2.8 Molecular Compounds: Formulas and Names  78 Making Measurements: Precision, Accuracy, Experimental Error, and Standard Deviation  30 Experimental Error  31 Standard Deviation  32 2.9 Atoms, Molecules, and the Mole  80 Atoms and Molar Mass  80 A Closer Look: Amedeo Avogadro and His Number  81 Molecules, Compounds, and Molar Mass  82 iv kotz_48288_00c_FM_i-xxxiii.indd 11/19/10 12:11 PM 446 c h a p t er 10 Carbon: Not Just Another Element • Chirality in Alkanes To be chiral, a compound must have at least one C atom attached to four different groups Thus, the C7H16 isomer here is chiral Step Draw a chain of four carbon atoms Add in the two remaining carbons, again being careful not to extend the chain length Two different structures are possible: one with the remaining carbon atoms in the and positions, and another with both extra carbon atoms attached at the position Fill in the 14 hydrogens You have now drawn the fourth and fifth isomers CH3 H H C * CH2CH3 C CH2CH2CH3 C The center of chirality is often indicated with an asterisk C C C H C H H C H H H C C C C H H C H H H H H carbon atom frameworks for dimethylbutane isomers 2,3-dimethylbutane H C C C C C C • Naming Guidelines For more details on naming organic compounds, see Appendix E H H H C H H H C C C C H H H H H C H H 2,2-dimethylbutane None of the isomers of C6H14 is chiral To be chiral, a compound must have at least one C atom with four different groups attached This condition is not met in any of these isomers Think about Your Answer Should we look for structures in which the longest chain is three carbon atoms? Try it, but you will see that it is not possible to add the three remaining carbons to a three-carbon chain without creating one of the carbon chains already drawn in a previous step Thus, we have completed the analysis, with five isomers of this compound being identified Names have been given to each of these compounds See the text that follows this Example, and see Appendix E for guidelines on nomenclature Check Your Understanding (a) Draw the nine isomers having the formula C7H16 (Hint: There is one structure with a sevencarbon chain, two structures with six-carbon chains, five structures with a five-carbon chain [one is illustrated in the margin], and one structure with a four-carbon chain.) (b) Identify the isomers of C7H16 that are chiral one possible isomer of an alkane with the formula C7H16 Naming Alkanes Module 15: Naming Organic Compounds covers concepts in this section With so many possible isomers for a given alkane, chemists need a systematic way of naming them The guidelines for naming alkanes and their derivatives follow: • • • kotz_48288_10_0438-0489.indd 446 The names of alkanes end in “-ane.” The names of alkanes with chains of one to 10 carbon atoms are given in Table 10.2 After the first four compounds, the names are derived from Greek and Latin numbers—pentane, hexane, heptane, octane, nonane, decane—and this regular naming continues for higher alkanes When naming a specific alkane, the root of the name corresponds to the longest carbon chain in the compound One isomer of C5H12 has a three-carbon chain 11/19/10 9:46 AM 10.2 Hydrocarbons prOBlem SOlvInG tIp 10.1 An error students sometimes make is to suggest that the three carbon skeletons drawn here are different They are, in fact, the same All are five-carbon chains with another C atom in the position 447 Drawing Structural Formulas C C C C C C C C C C C C C C C C C C Remember that Lewis structures not indicate the geometry of molecules with two OCH3 groups on the second C atom of the chain Thus, its name is based on propane CH3 H3C C CH3 CH3 2,2-dimethylpropane • • • Substituent groups on a hydrocarbon chain are identified by a name and the position of substitution in the carbon chain; this information precedes the root of the name The position is indicated by a number that refers to the carbon atom to which the substituent is attached Numbering of the carbon atoms in a chain should begin at the end of the carbon chain that allows the first substituent encountered to have the lowest possible number (If there is no distinction at this point, then number so to give the second substituent encountered the lowest number.) Both OCH3 groups in 2,2-dimethylpropane are located at the position Names of hydrocarbon substituents, called alkyl groups, are derived from the name of the hydrocarbon The group OCH3, derived by taking a hydrogen from methane, is called the methyl group; the OC2H5 group is the ethyl group If two or more of the same substituent groups are present in the molecule, the prefixes di-, tri-, and tetra- are added When different substituent groups are present, they are generally listed in alphabetical order example 10.2 • Systematic and Common Names The IUPAC (International Union of Pure and Applied Chemistry) has formulated rules for systematic names, which are generally used in this book (See Appendix E.) However, many organic compounds are known by common names For example, 2,2-dimethylpropane is also called neopentane Naming Alkanes Problem Give the systematic name for CH3 CH2CH3 CH3CHCH2CH2CHCH2CH3 What Do You Know? You know the condensed formula and can recognize that the compound is an alkane You also know the rules for naming alkanes Strategy Identify the longest carbon chain and base the name of the compound on that alkane Identify the substituent groups on the chain and their locations When there are two or more substituents (the groups attached to the chain), number the parent chain from the end that gives the lower number to the substituent encountered first If the substituents are different, list them in alphabetical order (For more on naming compounds, see Appendix E.) Solution Here, the longest chain has seven C atoms, so the root of the name is heptane There is a methyl group (OCH3) on C-2 and an ethyl group (OC2H5) on C-5 Giving the substituents in alphabetical order and numbering the chain from the end having the methyl group, the systematic name is 5-ethyl-2-methylheptane kotz_48288_10_0438-0489.indd 447 11/19/10 9:46 AM 448 c h a p t er 10   Carbon: Not Just Another Element © Cengage Learning/Charles D Winters Think about Your Answer ​Notice that the carbon atoms in the longest chain are numbered so that the lower number is given to the substituent encountered first Check Your Understanding ​ Name the nine isomers of C7H16 in “Check Your Understanding” in Example 10.1 Properties of Alkanes Figure 10.5   Paraffin wax and mineral oil These common consumer products are mixtures of alkanes Methane, ethane, propane, and butane are gases at room temperature and pressure, whereas the higher-molar-mass compounds are liquids or solids (Table 10.2) An increase in melting point and boiling point with molar mass in a series of similar compounds is a general phenomenon (▶ Sections 12.3 and 12.4) You already know about alkanes in a nonscientific context because several are common fuels Natural gas, gasoline, kerosene, fuel oils, and lubricating oils are all mixtures of various alkanes White mineral oil is also a mixture of alkanes, as is paraffin wax (Figure 10.5) Pure alkanes are colorless The gases and liquids have noticeable but not unpleasant odors All of these substances are insoluble in water, a property typical of compounds that are nonpolar or nearly so Low polarity is expected for alkanes because the electronegativities of carbon (χ = 2.5) and hydrogen (χ = 2.2) are not greatly different (◀ Section 8.8) All alkanes burn readily in air to give CO2 and H2O in very exothermic reactions This is, of course, the reason they are widely used as fuels CH4(g) ​+ ​2 O2(g) → CO2(g) ​+ ​2 H2O(ℓ)   Δr H° ​= ​−890.3 kJ/mol-rxn Other than in combustion reactions, alkanes exhibit relatively low chemical reactivity One reaction that does occur, however, is the replacement of the hydrogen atoms of an alkane by chlorine atoms on reaction with Cl2 It is formally an oxidation because Cl2, like O2, is a strong oxidizing agent These reactions, which can be initiated by ultraviolet radiation, are free radical reactions Highly reactive Cl atoms are formed from Cl2 under ultraviolet (UV) radiation Reaction of methane with Cl2 under these conditions proceeds in a series of steps, eventually yielding CCl4, commonly known as carbon tetrachloride (HCl is the other product of these reactions.) Cl2, UV Cl2, UV Cl2, UV Cl2, UV CH4 CH3Cl CH2Cl2 CHCl3 CCl4 Systematic name: chloromethane dichloromethane trichloromethane tetrachloromethane Common name: methyl chloride methylene chloride chloroform carbon tetrachloride The last three compounds are used as solvents, albeit less frequently today because of their toxicity Cycloalkanes, CnH2n cyclopropane, C3H6 cyclobutane, C4H8 Cyclopropane and cyclobutane Cyclo­propane was at one time used as a general anesthetic in surgery However, its explosive nature when mixed with oxygen soon eliminated this application kotz_48288_10_0438-0489.indd 448 Cycloalkanes are constructed with tetrahedral carbon atoms joined together to form a ring Cyclopropane and cyclobutane are the simplest cycloalkanes, although the bond angles in these species are much less than 109.5° As a result, chemists say they are strained hydrocarbons, so named because an unfavorable geometry is imposed around carbon One of the features of strained hydrocarbons is that the COC bonds are weaker and the molecules readily undergo ring-opening reactions that relieve the bond angle strain The most common cycloalkane is cyclohexane, C6H12, which has a nonplanar ring with six OCH2 groups If the carbon atoms were in the form of a regular 11/19/10 9:46 AM 10.2 Hydrocarbons 449 hexagon with all carbon atoms in one plane, the COCOC bond angles would be 120° To have tetrahedral bond angles of 109.5° around each C atom, the ring has to pucker The C6 ring is flexible and exists in two interconverting forms (see below for A Closer Look: Flexible Molecules) C2H4 Systematic name: ethene Common name: ethylene Alkenes and Alkynes The diversity seen for alkanes is repeated with alkenes, hydrocarbons with one or more CPC double bonds The presence of a double bond adds two features missing in alkanes: the possibility of geometric isomerism and increased reactivity The general formula for alkenes with a single double bond is CnH2n The first two members of the series of alkenes are ethene, C2H4 (common name, ethylene), and propene, C3H6 (common name, propylene) Only a single structure can be drawn for these compounds As with alkanes, the occurrence of isomers begins with species containing four carbon atoms Four alkene isomers have the formula C4H8, and each has distinct chemical and physical properties (Table 10.3) There are three structural isomers, one of which (CH3CHPCHCH3) exists as two stereoisomers H C C C H H H 1-butene H CH2CH3 H3C CH3 C C C 2-methylpropene CH3 C H H CH3 H CH3 C H H3C cis-2-butene C3H6 Systematic name: propene Common name: propylene trans-2-butene Alkene names end in “-ene.” As with alkanes, the root for the name of an alkene is determined by the longest carbon chain that contains the double bond The position of the double bond is indicated with a number, and, when appropriate, the prefix cis or trans is added Three of the C4H8 isomers have four-carbon chains and so are butenes One has a three-carbon chain and is a propene Notice that the carbon chain is numbered from the end that gives the double bond the lowest number In the first isomer at the left, the double bond is between C atoms and 2, so the name is 1-butene and not 3-butene A CLOSER LOOK Flexible Molecules Most organic molecules are flexible; that is, they can twist and bend in various ways Few molecules better illustrate this behavior than cyclohexane Two structures are possible: “chair” and “boat” forms These forms can interconvert by partial rotation of several bonds around the carbon ring The other six hydrogens are positioned above and below the plane and are called axial hydrogens Flexing the ring (a rotation around the COC single bonds) moves the hydrogen atoms between axial and equatorial environments The more stable structure is the chair form, which allows the hydrogen atoms to remain as far apart as possible A side view of this form of cyclohexane reveals two sets of hydrogen atoms in this molecule Six hydrogen atoms, called the equatorial hydrogens, lie in a plane axial H atom equatorial H atom H H H H H 3H H H chair form H H H H kotz_48288_10_0438-0489.indd 449 H H H H H H H H H H boat form H H H H H H H H H H H H H H chair form 11/19/10 9:46 AM 450 c h a p t er 10   Carbon: Not Just Another Element Table 10.3  Properties of Butene Isomers Name Dipole Moment (D) ∆f H° (gas) (kJ/mol) Boiling Point Melting Point 1-Butene −6.26 °C −185.4 °C — 2-Methylpropene −6.95 °C −140.4 °C 0.503 −17.9 Cis-2-butene 3.71 °C −138.9 °C 0.253 −7.7 Trans-2-butene 0.88 °C −105.5 °C −0.63 −10.8 Example 10.3 ​Determining Isomers of Alkenes from a Formula Problem ​Draw structures for the six possible alkene isomers with the formula C5H10 Give the systematic name of each What Do You Know? ​When linking the five carbon atoms together, two will be joined with a double bond Each carbon must have four bonds, and hydrogen atoms will fill into the remaining positions Strategy ​A procedure that involved drawing the carbon skeleton and then adding hydrogen atoms served well when drawing structures of alkanes (Example 10.1), and a similar approach can be used here It will be necessary to put one double bond into the framework and to be alert for cis-trans isomerism Solution Step 1. ​A five-carbon chain with one double bond can be constructed in two ways Cis-trans isomers are possible for 2-pentene H C C C C C H C C CH2CH2CH3 H 1-pentene H H C C H3C C C C C CH2CH3 cis-2-pentene C CH2CH3 H C C H3C H trans-2-pentene Step 2. ​Draw the possible four-carbon chains containing a double bond Add the fifth carbon atom to either the or position When all the possible combinations are found, fill in the hydrogen atoms This results in three more structures: C C C H C C CH3 C C CH2CH3 H 2-methyl-1-butene C C C C H C H C H C CHCH3 CH3 3-methyl-1-butene kotz_48288_10_0438-0489.indd 450 11/19/10 9:46 AM 10.2  Hydrocarbons C C C C H C CH3 C H3C C CH3 2-methyl-2-butene H2C H2C 451 H2 C C H CH2 CH cyclohexene, C6H10 Think about Your Answer ​With questions like this, it is important to be very organized in your approach When you complete your answer, you should look carefully to see that each structure is unique, that is, that no two are the same H2C=CHCH=CH2 Check Your Understanding ​ There are 17 possible alkene isomers with the formula C6H12 Draw structures of the five isomers in which the longest chain has six carbon atoms, and give the name of each Which of these isomers is chiral? (There are also eight isomers in which the longest chain has five carbon atoms, and four isomers in which the longest chain has four carbon atoms How many can you find?) 1,3-butadiene, C4H6 Cycloalkenes and dienes Cyclohexene, C6H10 (top), and 1,3-butadiene (C4H6) (bottom) Hydrocarbons exist that have two or more double bonds Butadiene, for example, has two double bonds and is known as a diene Many natural products have numerous double bonds (Figure 10.6) There are also cyclic hydrocarbons, such as cyclohexene, with double bonds Alkynes, compounds with a carbon–carbon triple bond, have the general formula (CnH2n−2) Table 10.4 lists alkynes that have four or fewer carbon atoms The first member of this family is ethyne (common name, acetylene), a gas used as a fuel in metal cutting torches Properties of Alkenes and Alkynes © Cengage Learning/Charles D Winters Like alkanes, alkenes and alkynes are colorless Low–molar-mass compounds are gases, whereas compounds with higher molar masses are liquids or solids Alkenes and alkynes are also oxidized by O2 to give CO2 and H2O Alkenes and alkynes have an elaborate chemistry We get some insight into their chemical behavior by recognizing that they are called unsaturated compounds Carbon atoms are capable of bonding to a maximum of four other atoms, and they so in alkanes and cycloalkanes In alkenes, however, each carbon atom linked by a double bond is bonded to a total of only three atoms In alkynes, each carbon atom linked by a triple bond is bonded to a total of only two atoms It is possible to Figure 10.6  Carotene, a naturally occurring compound with 11 CPC bonds The π electrons can be excited by visible light in the blue-violet region of the spectrum As a result, carotene appears orange-yellow to the observer Carotene or carotene-like molecules are partnered with chlorophyll in nature in the role of assisting in the harvesting of sunlight Green leaves have a high concentration of carotene In autumn, green chlorophyll molecules are destroyed, and the yellows and reds of carotene and related molecules are seen The red color of tomatoes, for example, comes from a molecule very closely related to carotene As a tomato ripens, its chlorophyll disintegrates, and the green color is replaced by the red of the carotene-like molecule kotz_48288_10_0438-0489.indd 451 11/19/10 9:46 AM 452 c h a p t er 10   Carbon: Not Just Another Element Table 10.4  Some Simple Alkynes CnH2n−2 Structure Systematic Name Common Name BP (°C) HCqCH ethyne acetylene −85 CH3CqCH propyne methylacetylene −23 CH3CH2CqCH 1-butyne ethylacetylene    CH3CqCCH3 2-butyne dimethylacetylene   27 © Cengage Learning/Charles D Winters increase the number of groups attached to a carbon atom in an alkene or alkyne by addition reactions, in which molecules with the general formula XOY (such as hydrogen, halogens, hydrogen halides, and water) add across the carbon–carbon double or triple bond (Figure 10.7) For an alkene the result is a compound with four groups bonded to each carbon H H C H H Y H Y C C H H H Y = H2, Cl2, Br2; H Cl, H Br, H X An oxy-acetylene torch The reaction of ethyne (acetylene) with oxygen produces a very high temperature Oxy-acetylene torches, used in welding, take advantage of this fact +X C X OH, HO Cl The products of some addition reactions are substituted alkanes For example, the addition of bromine to ethene (ethylene) forms 1,2-dibromoethane C H Br Br H H + Br2 C H H C C H H H 1,2-dibromoethane The addition of mol of chlorine to ethyne (acetylene) gives 1,1,2,2-tetrachloroethane • Nomenclature of Substituted Alkanes  The substituent groups in substituted alkanes are identified by the name and position of the substituent on the alkane chain Cl Cl HC CH + Cl2 Cl C C Cl H H 1,1,2,2-tetrachloroethane During the 1860s, the Russian chemist Vladimir Markovnikov examined a large number of alkene addition reactions In cases in which two isomeric products were possible, he found that one was more likely to predominate Based on these results, Markovnikov formulated a rule (now called Markovnikov’s rule) stating that, when a is partially unsaturated Like other unsaturated compounds, bacon fat reacts with Br2 in an addition reaction Here, you see the color of Br2 vapor fade when a strip of bacon is introduced kotz_48288_10_0438-0489.indd 452 Photos © Cengage Learning/Charles D Winters Figure 10.7  Bacon fat and addition reactions The fat in bacon a few minutes 11/19/10 9:46 AM 10.2  Hydrocarbons 453 reagent HX adds to an unsymmetrical alkene, the hydrogen atom in the reagent becomes attached to the carbon that already has the largest number of hydrogens An example of Markovnikov’s rule is the reaction of 2-methylpropene with HCl that results in formation of 2-chloro-2-methylpropane rather than 1-chloro-2methylpropane Cl H3C C CH2 + HCl H3C H3C C H + CH3 H3C CH3 CH2Cl CH3 2-chloro-2-methylpropane sole product 2-methylpropene C 1-chloro-2-methylpropane not formed If the reagent added to a double bond is hydrogen (XOY = H2), the reaction is called hydrogenation Hydrogenation is usually a very slow reaction, but it can be speeded up by adding a catalyst, often a specially prepared form of a metal, such as platinum, palladium, and rhodium You may have heard the term hydrogenation because certain foods contain “hydrogenated” or “partially hydrogenated” ingredients One brand of crackers has a label that says, “Made with 100% pure vegetable shortening (partially hydrogenated soybean oil with hydrogenated cottonseed oil).” One reason for hydrogenating an oil is to make it less susceptible to spoilage; another is to convert it from a liquid to a solid • Catalysts  A catalyst is a substance that causes a reaction to occur at a faster rate without itself being permanently changed in the reaction We will describe catalysts in more detail in Chapter 15 Example 10.4 ​Reaction of an Alkene Problem ​Draw the structure of the compound obtained from the reaction of Br2 with propene, and name the compound What Do You Know? ​Propene is the three-carbon alkene Addition reactions are among the most common reactions of alkenes, and it is known that bromine is one of several common reagents that adds to double bonds Strategy ​Bromine adds across the CPC double bond The name of the product is based on the name of the carbon chain and indicates the positions of the Br atoms Solution H Br Br H C + Br2 C CH3 H propene H C C H H CH3 1,2-dibromopropane Check Your Understanding ​ (a) Draw the structure of the compound obtained from the reaction of HBr with ethylene, and name the compound (b) Draw the structure of the product of the reaction of Br2 with cis-2-butene, and name this compound Aromatic Compounds Benzene, C6H6, is a key molecule in chemistry It is the simplest aromatic compound, a class of compounds so named because they have significant, and usually not unpleasant, odors Other members of this class, which are all based on benzene, include toluene and naphthalene A source of many aromatic compounds is coal kotz_48288_10_0438-0489.indd 453 © Cengage Learning/Charles D Winters Think about Your Answer ​This reaction converts an unsaturated hydrocarbon to a substituted alkane It is named as an alkane (propane) with substituents (Br atoms) identified by name and position on the three-carbon chain Some products containing compounds based on benzene Examples include sodium benzoate in soft drinks, ibuprofen in Advil, and benzoyl peroxide in Oxy-10 11/19/10 9:46 AM 454 c h a p t er 10   Carbon: Not Just Another Element H H H C C C C These compounds, along with other volatile substances, are released when coal is heated to a high temperature in the absence of air (Table 10.5) O C C H C NH H S O2 H H Saccharin (C7H5NO3S) This compound, an artificial sweetener, contains an aromatic ring C C C C CH3 C C H H H H C C C C H H benzene toluene H C C H H H H C C C C H H C C C C C C H H H naphthalene Benzene occupies a pivotal place in the history and practice of chemistry Michael Faraday discovered this compound in 1825 as a by-product of illuminating gas, a fuel produced by heating coal Today, benzene is an important industrial chemical, usually ranking among the top 25 chemicals in production annually in the United States It is used as a solvent and is also the starting point for making thousands of different compounds by replacing the H atoms of the ring Toluene was originally obtained from tolu balsam, the pleasant-smelling gum of a South American tree, Toluifera balsamum This balsam has been used in cough syrups and perfumes Naphthalene is an ingredient in “moth balls,” although 1,4dichlorobenzene is now more commonly used Aspartame and another artificial sweetener, saccharin, are also benzene derivatives The Structure of Benzene • August Kekulé and the Structure of Benzene The structural question was solved by August Kekulé (1829–1896) Kekulé, one of the most prominent organic chemists in Europe in the late 19th century, argued for the ring structure with alternating double bonds based on the number of isomers possible for the structure The legend in chemistry is that Kekulé proposed the ring structure after dreaming of a snake biting its tail The formula of benzene suggested to 19th-century chemists that this compound should be unsaturated, but, if viewed this way, its chemistry was perplexing Whereas alkenes readily undergo addition reactions, benzene does not so under similar conditions We now recognize that benzene’s different reactivity relates to its structure and bonding, both of which are quite different from the structure and bonding in alkenes Benzene has equivalent carbon–carbon bonds, 139 pm in length, intermediate between a COC single bond (154 pm) and a CPC double bond (134 pm) The π bonds are formed by the continuous overlap of the p orbitals on the six carbon atoms (page 416) Using valence bond terminology, the structure is represented by two resonance structures or simply representations of benzene, C6H6 INTERFOTO/Alamy Table 10.5  Some Aromatic Compounds from Coal Tar kotz_48288_10_0438-0489.indd 454 Common Name Formula Boiling Point (°C) Melting Point (°C) Benzene C6H6 80   +6 Toluene C6H5CH3 111 −95 o-Xylene 1,2-C6H4(CH3)2 144 −25 m-Xylene 1,3-C6H4(CH3)2 139 −48 p-Xylene 1,4-C6H4(CH3)2 138 +13 Naphthalene C10H8 218 +80 11/19/10 9:46 AM 10.2  Hydrocarbons 455 Benzene Derivatives Toluene, chlorobenzene, benzoic acid, aniline, styrene, and phenol are common examples of benzene derivatives Cl CO2H chlorobenzene NH2 benzoic acid CH aniline CH2 OH styrene phenol The systematic nomenclature for benzene derivatives with two or more substituent groups involves naming these groups and identifying their positions on the ring by numbering the six carbon atoms (▶ Appendix E) Some common names, which are based on an older naming scheme, are also used This scheme identified isomers of disubstituted benzenes with the prefixes ortho (o-, substituent groups on adjacent carbons in the benzene ring), meta (m-, substituents separated by one carbon atom), and para (p-, substituent groups on carbons on opposite sides of the ring) X • Drawing Aromatic Rings  When drawing benzene rings chemists often allow the vertices of the hexagon to represent the carbon atoms and not show the H atoms attached to those carbon atoms ortho to X meta to X para to X Cl CH3 NO2 Cl CH3 NO2 Systematic name: 1,2-dichlorobenzene Common name: o-dichlorobenzene 1,3-dimethylbenzene m-xylene 1,4-dinitrobenzene p-dinitrobenzene Example 10.5 ​Isomers of Substituted Benzenes Problem ​Draw and name the isomers of C6H3Cl3 What Do You Know? ​From the formula you can infer that C6H3Cl3 is a substituted benzene with three hydrogen atoms replaced by chlorine atoms Strategy ​Begin by drawing the carbon framework of benzene, and attach a chlorine atom to one of the carbon atoms Place a second Cl atom on the ring in the ortho, meta, and para positions Add the third Cl in one of the remaining positions, being careful not to repeat a structure already drawn Solution ​The three isomers of C6H3Cl3 are shown here They are named as derivatives of benzene by specifying the number of substituent groups with the prefix “tri-,” the name of the substituent, and the positions of the three groups around the six-member ring Cl Cl Cl Cl Cl Cl 1,2,3-trichlorobenzene kotz_48288_10_0438-0489.indd 455 Cl Cl Cl 1,2,4-trichlorobenzene 1,3,5-trichlorobenzene 11/19/10 9:46 AM 456 c h a p t er 10 Carbon: Not Just Another Element Think about Your Answer Are there other possibilities? Try moving the chlorine atoms around in each isomer In every case, you will find that moving one Cl atom to a different position generates one of these three isomers For example, in the first structure, moving the Cl atom at position to either position or leads to structures identical to the second structure Check Your Understanding Aniline, C6H5NH2, is the common name for aminobenzene Draw a structure for p-diaminobenzene, a compound used in dye manufacture What is the systematic name for p-diaminobenzene? Properties of Aromatic Compounds Benzene is a colorless liquid, and simple substituted benzenes are liquids or solids under normal conditions The properties of aromatic hydrocarbons are typical of hydrocarbons in general: They are insoluble in water, soluble in nonpolar solvents, and oxidized by O2 to form CO2 and H2O One of the most important properties of benzene and other aromatic compounds is an unusual stability that is associated with the unique π bonding in this molecule Because the π bonding in benzene is typically described using resonance structures, the extra stability is termed resonance stabilization The extent of resonance stabilization in benzene is evaluated by comparing the energy evolved in the hydrogenation of benzene to form cyclohexane C6H6(ℓ) + H2(g) catalyst ∆rH° = −206.7 kJ/mol-rxn C6H12(ℓ) with the energy evolved in hydrogenation of three isolated double bonds H2CPCH2(g) + H2(g) → C2H6(g) ΔrH° = −410.8 kJ/mol-rxn The hydrogenation of benzene is about 200 kJ/mol less exothermic than the hydrogenation of three moles of ethene The difference is attributable to the added stability associated with π bonding in benzene Although aromatic compounds are unsaturated hydrocarbons, they not undergo the addition reactions typical of alkenes and alkynes Instead, substitution reactions occur, in which one or more hydrogen atoms are replaced by other groups Such reactions require higher temperatures and a strong Brønsted acid such as H2SO4 or a Lewis acid such as AlCl3 or FeBr3 • Lewis Acids and Bases G N Lewis (page 342) defined an acid as an electron-pair acceptor (such as AlCl3) and a base as an electron-pair donor (such as NH3) (See Chapter 17, Section 11.) Nitration: Alkylation: C6H6(ℓ) + HNO3(ℓ) C6H6(ℓ) + CH3Cl(ℓ) Halogenation: C6H6(ℓ) + Br2(ℓ) H2SO4 C6H5NO2(ℓ) + H2O(ℓ) AlCl3 C6H5CH3(ℓ) + HCl(g) FeBr3 C6H5Br(ℓ) + HBr(g) revIeW & cHecK FOr SectIOn 10.2 What is the systematic name for this alkane? H H H H H CH3 H C C C C H CH2 H C C H H H H CH3 (a) nonane (b) 2-ethyl-5-methylhexane kotz_48288_10_0438-0489.indd 456 (c) 2, 5-dimethylheptane (d) dimethyloctane 11/19/10 9:46 AM 10.3 Alcohols, Ethers, and Amines 457 Which statement below correctly describes the following compound? H C H H3C (a) CH3 C CH C CH3 The compound is an isomer of pentane, is chiral, and is named 2,3-dimethylbutane (b) The compound is an isomer of octane, is not chiral, and is named 2,2-dimethylbutane (c) The compound is an isomer of hexane, is not chiral, and is named 2,2-dimethylbutane (d) The compound is an isomer of hexane, is not chiral, and is named 3,3-dimethylbutane Consider the following list of compounds: C2H4 C5H10 (i) Which compound or compounds in the list can be an alkane? (a) only (ii) Which compound or compounds in the list can be an alkene? (a) only (b) and (c) (b) only (c) only C7H8 (d) and and (d) and What is the product of the following reaction? H3C CH2CH3 C + HBr C H 3C H CH3 CH2CH3 Br C C H CH3 CH2CH3 H CH3 H (a) C14H30 C C B Br CH3 H (b) How many isomers are possible for C6H4(CH3)Cl, a benzene derivative? (a) (b) (c) 10.3 Alcohols, ethers, and Amines Organic compounds often contain other elements in addition to carbon and hydrogen Two elements in particular, oxygen and nitrogen, add a rich dimension to carbon chemistry Organic chemistry organizes compounds containing elements other than carbon and hydrogen as derivatives of hydrocarbons Formulas (and structures) are represented by substituting one or more hydrogens in a hydrocarbon molecule by a functional group A functional group is an atom or group of atoms attached to a carbon atom in the hydrocarbon Formulas of hydrocarbon derivatives are then written as ROX, in which R is a hydrocarbon lacking a hydrogen atom, and X is the functional group (such as −OH, −NH2, a halogen atom, or −CO2H) that has replaced the hydrogen The chemical and physical properties of the hydrocarbon derivatives are a blend of the properties associated with hydrocarbons and the group that has been substituted for hydrogen Table 10.6 identifies some common functional groups and the families of organic compounds resulting from their attachment to a hydrocarbon kotz_48288_10_0438-0489.indd 457 11/19/10 9:46 AM 458 c h a p t er 10 Carbon: Not Just Another Element A CLOSER LOOK Petroleum Chemistry © iStockphoto.com/Olivier Lantzendörffer Much of the world’s current technology relies on petroleum Burning fuels derived from petroleum provides by far the largest amount of energy in the industrial world (◀ The Chemistry of Fuels and Energy Sources, pages 252–265) Petroleum and natural gas are also the chemical raw materials used in the manufacture of many plastics, pharmaceuticals, and a vast array of other compounds The petroleum that is pumped out of the ground is a complex mixture whose composition varies greatly, depending on its source The primary components of petroleum are always alkanes, but, to varying degrees, nitrogen- and sulfur-containing compounds are also present Aromatic compounds are present as well, but alkenes and alkynes are not An early step in the petroleum refining process is distillation, in which the crude A modern petrochemical plant mixture is separated into a series of fractions based on boiling point: first a gaseous fraction (mostly alkanes with one to four carbon atoms; this fraction is often burned off), and then gasoline, kerosene, and fuel oils After distillation, considerable material, in the form of a semi-solid, tar-like residue, remains The petrochemical industry seeks to maximize the amounts of the higher-valued fractions of petroleum produced and to make specific compounds for which a particular need exists This means carrying out chemical reactions involving the raw materials on a huge scale One process to which petroleum is subjected is known as cracking At very high temperatures, bond breaking or “cracking” can occur, and longer-chain hydrocarbons will fragment into smaller molecular units These reactions are carried out in the presence of a wide array of catalysts, materials that speed up reactions and direct them toward specific products Among the important products of cracking is ethylene, which serves as the raw material for the formation of materials such as polyethylene Cracking also produces other alkenes and gaseous hydrogen, both widely used raw materials in the chemical industry Other important reactions involving petroleum are run at elevated temperatures and in the presence of specific catalysts Such reactions include isomerization reac- tions, in which the carbon skeleton of an alkane rearranges to form a new isomeric species, and reformation processes, in which alkanes become cycloalkanes or aromatic hydrocarbons Each process is directed toward achieving a specific goal, such as increasing the proportion of branched-chain hydrocarbons in gasoline to obtain higher octane ratings A great amount of chemical research has gone into developing and understanding these highly specialized processes octane catalyst isooctane Producing gasoline Branched hydrocarbons have a higher octane rating in gasoline Therefore, an important process in producing gasoline is the isomerization of octane to a branched hydrocarbon such as isooctane, 2,2,4-trimethylpentane Alcohols and Ethers O H C H H H Methanol, CH3OH, the simplest alcohol Methanol is often called wood alcohol because it was originally produced by heating wood in the absence of air kotz_48288_10_0438-0489.indd 458 If one of the hydrogen atoms of an alkane is replaced by a hydroxyl (OOH) group, the result is an alcohol, ROH Methanol, CH3OH, and ethanol, CH3CH2OH, are the most important alcohols, but others are also commercially important (Table 10.7) Notice that several have more than one OH functional group More than × 108 kg of methanol is produced in the United States annually Most of this production is used to make formaldehyde (CH2O) and acetic acid (CH3CO2H), both important chemicals in their own right Methanol is also used as a solvent, as a de-icer in gasoline, and as a fuel in high-powered racing cars It is found in low concentration in new wine, where it contributes to the odor, or “bouquet.” Like ethanol, methanol causes intoxication, but methanol differs in being more poisonous, largely because the human body converts it to formic acid (HCO2H) and formaldehyde (CH2O) These compounds attack the cells of the retina in the eye, leading to permanent blindness Ethanol is the “alcohol” of alcoholic beverages, in which it is formed by the anaerobic (without air) fermentation of sugar On a much larger scale, ethanol for use 11/19/10 9:46 AM 10.3  Alcohols, Ethers, and Amines 459 Table 10.6  Common Functional Groups and Derivatives of Alkanes Functional Group* General Formula* Class of Compound Examples F, Cl, Br, I OH OR′ NH2† RF, RCl, RBr, RI ROH ROR′ RNH2 Haloalkane Alcohol Ether (Primary) Amine CH3CH2Cl, chloroethane CH3CH2OH, ethanol (CH3CH2)2O, diethyl ether CH3CH2NH2, ethylamine RCHO Aldehyde CH3CHO, ethanal (acetaldehyde) R′ RCOR′ Ketone CH3COCH3, propanone (acetone) OH RCO2H Carboxylic acid CH3CO2H, ethanoic acid (acetic acid) OR′ RCO2R′ Ester CH3CO2CH3, methyl acetate NH2 RCONH2 Amide CH3CONH2, acetamide O CH O C O C O C O C * R and R′ can be the same or different hydrocarbon groups † Secondary amines (R2NH) and tertiary amines (R3N) are also possible, see discussion in the text as a fuel is made by fermentation of corn and other plant materials Some ethanol (about 5%) is made from petroleum, by the reaction of ethylene and water H H H H C (g) + H2O(g) C H catalyst H H C C OH(ℓ) H H ethylene ethanol Beginning with three-carbon alcohols, structural isomers are possible For example, 1-propanol and 2-propanol (common names, propyl alcohol and isopropyl alcohol) are different compounds (Table 10.7) Ethylene glycol and glycerol are common alcohols having two and three OOH groups, respectively Ethylene glycol is used as antifreeze in automobiles Glycerol’s Condensed Formula BP (°C) Systematic Name Common Name Use CH3OH 65.0 Methanol Methyl alcohol F uel, gasoline additive, making formaldehyde CH3CH2OH 78.5 Ethanol Ethyl alcohol  everages, gasoline B additive, solvent CH3CH2CH2OH 97.4 1-Propanol Propyl alcohol Industrial solvent CH3CH(OH)CH3 82.4 2-Propanol Isopropyl alcohol Rubbing alcohol HOCH2CH2OH 198 1,2-Ethanediol Ethylene glycol Antifreeze HOCH2CH(OH)CH2OH 290 1,2,3-Propanetriol Glycerol (glycerin)  oisturizer in M consumer products kotz_48288_10_0438-0489.indd 459 © Cengage Learning/Charles D Winters Table 10.7  Some Important Alcohols Rubbing alcohol Common rubbing alcohol is 2-propanol, also called isopropyl alcohol 11/19/10 9:46 AM 460 c h a p t er 10   Carbon: Not Just Another Element Figure 10.8  Nitroglycerin (a) The Nobel Foundation © Cengage Learning/Charles D Winters (a) Concentrated nitric acid and glycerin react to form an oily, highly unstable compound called nitroglycerin, C3H5(ONO2)3 (b) Nitroglycerin is more stable if absorbed onto an inert solid, a combination called dynamite (c) The fortune of Alfred Nobel (1833–1896), built on the manufacture of dynamite, now funds the Nobel Prizes (c) (b) most common use is as a softener in soaps and lotions It is also a raw material for the preparation of nitroglycerin (Figure 10.8) H H H C H H H C H H C OH OH Systematic name: Common name: C C H OH OH OH 1,2-ethanediol ethylene glycol 1,2,3-propanetriol glycerol or glycerin Ethers have the general formula ROR′ The best-known ether is diethyl ether, CH3CH2OCH2CH3 Lacking an OOH group, the properties of ethers are in sharp contrast to those of alcohols Diethyl ether, for example, has a lower boiling point (34.5 °C) than ethanol, CH3CH2OH (78.3 °C), and is only slightly soluble in water Example 10.6 ​Structural Isomers of Alcohols Problem ​How many different alcohols are derivatives of pentane? Draw their structures, and name each alcohol What Do You Know? ​The formula for pentane is C5H12 In an alcohol an OOH group will replace one H atom Strategy ​Pentane, C5H12, has a five-carbon chain An OOH group can replace a hydrogen atom on one of the carbon atoms Alcohols are named as derivatives of the alkane (pentane) by replacing the “-e” at the end with “-ol” and indicating the position of the OOH group by a numerical prefix (Appendix E) Solution ​Three different alcohols are possible, depending on whether the OOH group is placed on the first, second, or third carbon atom in the chain (The fourth and fifth positions are identical to the second and first positions in the chain, respectively.) H HO C H H C H H C H H C H H C H 1-pentanol H H H H OH H H H C C C C C H H H H H H 2-pentanol     H H OH H H C C C C C H H H H H H 3-pentanol kotz_48288_10_0438-0489.indd 460 11/19/10 9:46 AM ... (247.07) 11 /22 /10 1: 37 PM 8A (18 ) Helium He 3A (13 ) 4A (14 ) 5A (15 ) 6A (16 ) 7A (17 ) 4.0026 Boron Carbon Nitrogen Oxygen Fluorine Neon 10 10 . 811 Aluminum 13 12 . 011 Silicon 14 14 .0067 15 .9994 Phosphorus... ISBN -10 : 1- 111 -30524-2; ISBN -13 : 978 -1- 111 -30524-6 Instant Access OWL with Cengage YouBook (24 months) ISBN -10 : 1- 111 -305 21- 8; ISBN -13 : 978 -1- 111 -305 21- 5 By Roberta Day and Beatrice Botch of the University... in the United States of America 1 2  3  4  5  6  7  14   13   12   11   10 kotz_48288_00c_FM_i-xxxiii.indd 11 /19 /10 12 :11 PM brief contents 18 Principles of Chemical Reactivity: Other Aspects of Aqueous

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  • Front Cover

  • Title Page

  • Copyright Page

  • Brief Contents

  • Contents

  • Preface

  • Acknowledgments

  • About the Authors

  • About the Cover

  • PART ONE: THE BASIC TOOLS OF CHEMISTRY

    • 1 Basic Concepts of Chemistry

      • Gold!

      • 1.1 Chemistry and Its Methods

      • 1.2 Sustainability and Green Chemistry

      • 1.3 Classifying Matter

      • 1.4 Elements

      • 1.5 Compounds

      • 1.6 Physical Properties

      • 1.7 Physical and Chemical Changes

      • 1.8 Energy: Some Basic Principles

      • CHAPTER GOALS REVISITED

      • KEY EQUATION

      • STUDY QUESTIONS

    • Let’s Review: The Tools of Quantitative Chemistry

      • Copper

      • 1 Units of Measurement

      • 2 Making Measurements: Precision, Accuracy, Experimental Error, and Standard Deviation

      • 3 Mathematics of Chemistry

      • 4 Problem Solving by Dimensional Analysis

      • 5 Graphs and Graphing

      • 6 Problem Solving and Chemical Arithmetic

      • STUDY QUESTIONS

    • 2 Atoms, Molecules, and Ions

      • The Periodic Table, the Central Icon of Chemistry

      • 2.1 Atomic Structure—Protons, Electrons, and Neutrons

      • 2.2 Atomic Number and Atomic Mass

      • 2.3 Isotopes

      • 2.4 Atomic Weight

      • 2.5 The Periodic Table

      • 2.6 Molecules, Compounds, and Formulas

      • 2.7 Ionic Compounds: Formulas, Names, and Properties

      • 2.8 Molecular Compounds: Formulas and Names

      • 2.9 Atoms, Molecules, and the Mole

      • 2.10 Describing Compound Formulas

      • 2.11 Hydrated Compounds

      • CHAPTER GOALS REVISITED

      • KEY EQUATIONS

      • STUDY QUESTIONS

      • APPLYING CHEMICAL PRINCIPLES: ARGON—AN AMAZING DISCOVERY

    • 3 Chemical Reactions

      • Black Smokers and Volcanoes

      • 3.1 Introduction to Chemical Equations

      • 3.2 Balancing Chemical Equations

      • 3.3 Introduction to Chemical Equilibrium

      • 3.4 Aqueous Solutions

      • 3.5 Precipitation Reactions

      • 3.6 Acids and Bases

      • 3.7 Gas-Forming Reactions

      • 3.8 Oxidation–Reduction Reactions

      • 3.9 Classifying Reactions in Aqueous Solution

      • CHAPTER GOALS REVISITED

      • STUDY QUESTIONS

      • APPLYING CHEMICAL PRINCIPLES: SUPERCONDUCTORS

    • 4 Stoichiometry: Quantitative Information about Chemical Reactions

      • The Chemistry of Pyrotechnics

      • 4.1 Mass Relationships in Chemical Reactions: Stoichiometry

      • 4.2 Reactions in Which One Reactant Is Present in Limited Supply

      • 4.3 Percent Yield

      • 4.4 Chemical Equations and Chemical Analysis

      • 4.5 Measuring Concentrations of Compounds in Solution

      • 4.6 pH, a Concentration Scale for Acids and Bases

      • 4.7 Stoichiometry of Reactions in Aqueous Solution

      • 4.8 Spectrophotometry

      • CHAPTER GOALS REVISITED

      • KEY EQUATIONS

      • STUDY QUESTIONS

      • APPLYING CHEMICAL PRINCIPLES: ANTACIDS

    • 5 Principles of Chemical Reactivity: Energy and Chemical Reactions

      • Energy and Your Diet

      • 5.1 Energy: Some Basic Principles

      • 5.2 Specific Heat Capacity: Heating and Cooling

      • 5.3 Energy and Changes of State

      • 5.4 The First Law of Thermodynamics

      • 5.5 Enthalpy Changes for Chemical Reactions

      • 5.6 Calorimetry

      • 5.7 Enthalpy Calculations

      • 5.8 Product- or Reactant-Favored Reactions and Thermodynamics

      • CHAPTER GOALS REVISITED

      • KEY EQUATIONS

      • STUDY QUESTIONS

      • APPLYING CHEMICAL PRINCIPLES: GUNPOWDER

    • Interchapter: The Chemistry of Fuels and Energy Resources

      • Supply and Demand: The Balance Sheet on Energy

      • Fossil Fuels

      • Energy in the Future: Choices and Alternatives

      • What Does the Future Hold for Energy?

      • SUGGESTED READINGS

      • STUDY QUESTIONS

  • PART TWO: THE STRUCTURE OF ATOMS AND MOLECULES

    • 6 The Structure of Atoms

      • Fireworks

      • 6.1 Electromagnetic Radiation

      • 6.2 Quantization: Planck, Einstein, Energy, and Photons

      • 6.3 Atomic Line Spectra and Niels Bohr

      • 6.4 Particle–Wave Duality: Prelude to Quantum Mechanics

      • 6.5 The Modern View of Electronic Structure: Wave or Quantum Mechanics

      • 6.6 The Shapes of Atomic Orbitals

      • 6.7 One More Electron Property: Electron Spin

      • CHAPTER GOALS REVISITED

      • KEY EQUATIONS

      • STUDY QUESTIONS

      • APPLYING CHEMICAL PRINCIPLES: CHEMISTRY OF THE SUN

    • 7 The Structure of Atoms and Periodic Trends

      • Rubies and Sapphires—Pretty Stones

      • 7.1 The Pauli Exclusion Principle

      • 7.2 Atomic Subshell Energies and Electron Assignments

      • 7.3 Electron Configurations of Atoms

      • 7.4 Electron Configurations of Ions

      • 7.5 Atomic Properties and Periodic Trends

      • 7.6 Periodic Trends and Chemical Properties

      • CHAPTER GOALS REVISITED

      • STUDY QUESTIONS

      • APPLYING CHEMICAL PRINCIPLES: THE NOT-SO-RARE EARTHS

    • Interchapter: Milestones in the Development of Chemistry and the Modern View of Atoms and Molecules

      • Greek Philosophers and Medieval Alchemists

      • Chemists of the 18th–19th Centuries

      • Atomic Structure: Remarkable Discoveries—1890s and Beyond

      • The Nature of the Chemical Bond

      • SUGGESTED READINGS

      • STUDY QUESTIONS

    • 8 Bonding and Molecular Structure

      • Chemical Bonding in DNA

      • 8.1 Chemical Bond Formation

      • 8.2 Covalent Bonding and Lewis Structures

      • 8.3 Atom Formal Charges in Covalent Molecules and Ions

      • 8.4 Resonance

      • 8.5 Exceptions to the Octet Rule

      • 8.6 Molecular Shapes

      • 8.7 Bond Polarity and Electronegativity

      • 8.8 Bond and Molecular Polarity

      • 8.9 Bond Properties: Order, Length, and Energy

      • 8.10 DNA, Revisited

      • CHAPTER GOALS REVISITED

      • KEY EQUATIONS

      • STUDY QUESTIONS

      • APPLYING CHEMICAL PRINCIPLES: LINUS PAULING AND ELECTRONEGATIVITY

    • 9 Bonding and Molecular Structure: Orbital Hybridization and Molecular Orbitals

      • The Noble Gases: Not So Inert

      • 9.1 Orbitals and Theories of Chemical Bonding

      • 9.2 Valence Bond Theory

      • 9.3 Molecular Orbital Theory

      • CHAPTER GOALS REVISITED

      • KEY EQUATION

      • STUDY QUESTIONS

      • APPLYING CHEMICAL PRINCIPLES: PROBING MOLECULES WITH PHOTOELECTRON SPECTROSCOPY

    • 10 Carbon: Not Just Another Element

      • The Food of the Gods

      • 10.1 Why Carbon?

      • 10.2 Hydrocarbons

      • 10.3 Alcohols, Ethers, and Amines

      • 10.4 Compounds with a Carbonyl Group

      • 10.5 Polymers

      • CHAPTER GOALS REVISITED

      • STUDY QUESTIONS

      • APPLYING CHEMICAL PRINCIPLES: BIODIESEL—AN ATTRACTIVE FUEL FOR THE FUTURE?

    • Interchapter: The Chemistry of Life: Biochemistry

      • Proteins

      • Nucleic Acids

      • Lipids and Cell Membranes

      • Metabolism

      • Concluding Remarks

      • SUGGESTED READINGS

      • STUDY QUESTIONS

  • PART THREE: STATES OF MATTER

    • 11 Gases and Their Properties

      • The Atmosphere and Altitude Sickness

      • 11.1 Gas Pressure

      • 11.2 Gas Laws: The Experimental Basis

      • 11.3 The Ideal Gas Law

      • 11.4 Gas Laws and Chemical Reactions

      • 11.5 Gas Mixtures and Partial Pressures

      • 11.6 The Kinetic-Molecular Theory of Gases

      • 11.7 Diffusion and Effusion

      • 11.8 Nonideal Behavior of Gases

      • CHAPTER GOALS REVISITED

      • KEY EQUATIONS

      • STUDY QUESTIONS

      • APPLYING CHEMICAL PRINCIPLES: THE GOODYEAR BLIMP

    • 12 Intermolecular Forces and Liquids

      • Geckos Can Climb Up der Waals

      • 12.1 States of Matter and Intermolecular Forces

      • 12.2 Interactions between Ions and Molecules with a Permanent Dipole

      • 12.3 Interactions between Molecules with a Dipole

      • 12.4 Intermolecular Forces Involving Nonpolar Molecules

      • 12.5 A Summary of van der Waals Intermolecular Forces

      • 12.6 Properties of Liquids

      • CHAPTER GOALS REVISITED

      • KEY EQUATIONS

      • STUDY QUESTIONS

      • APPLYING CHEMICAL PRINCIPLES: CHROMATOGRAPHY

    • 13 The Chemistry of Solids

      • Lithium and “Green Cars”

      • 13.1 Crystal Lattices and Unit Cells

      • 13.2 Structures and Formulas of Ionic Solids

      • 13.3 Bonding in Metals and Semiconductors

      • 13.4 Bonding in Ionic Compounds: Lattice Energy

      • 13.5 The Solid State: Other Types of Solid Materials

      • 13.6 Phase Changes Involving Solids

      • 13.7 Phase Diagrams

      • CHAPTER GOALS REVISITED

      • STUDY QUESTIONS

      • APPLYING CHEMICAL PRINCIPLES: TIN DISEASE

    • 14 Solutions and Their Behavior

      • Survival at Sea

      • 14.1 Units of Concentration

      • 14.2 The Solution Process

      • 14.3 Factors Affecting Solubility: Pressure and Temperature

      • 14.4 Colligative Properties

      • 14.5 Colloids

      • CHAPTER GOALS REVISITED

      • KEY EQUATIONS

      • STUDY QUESTIONS

      • APPLYING CHEMICAL PRINCIPLES: DISTILLATION

    • Interchapter: The Chemistry of Modern Materials

      • Alloys: Mixtures of Metals

      • Semiconductors

      • Ceramics

      • Biomaterials: Learning from Nature

      • The Future of Materials

      • SUGGESTED READINGS

      • STUDY QUESTIONS

  • PART FOUR: THE CONTROL OF CHEMICAL REACTIONS

    • 15 Chemical Kinetics: The Rates of Chemical Reactions

      • Where Did the Indicator Go?

      • 15.1 Rates of Chemical Reactions

      • 15.2 Reaction Conditions and Rate

      • 15.3 Effect of Concentration on Reaction Rate

      • 15.4 Concentration–Time Relationships: Integrated Rate Laws

      • 15.5 A Microscopic View of Reaction Rates

      • 15.6 Reaction Mechanisms

      • CHAPTER GOALS REVISITED

      • KEY EQUATIONS

      • STUDY QUESTIONS

      • APPLYING CHEMICAL PRINCIPLES: KINETICS AND MECHANISMS: A 70-YEAR-OLD MYSTERY SOLVED

    • 16 Principles of Chemical Reactivity: Equilibria

      • Dynamic and Reversible!

      • 16.1 Chemical Equilibrium: A Review

      • 16.2 The Equilibrium Constant and Reaction Quotient

      • 16.3 Determining an Equilibrium Constant

      • 16.4 Using Equilibrium Constants in Calculations

      • 16.5 More about Balanced Equations and Equilibrium Constants

      • 16.6 Disturbing a Chemical Equilibrium

      • CHAPTER GOALS REVISITED

      • KEY EQUATIONS

      • STUDY QUESTIONS

      • APPLYING CHEMICAL PRINCIPLES: TRIVALENT CARBON

    • 17 Principles of Chemical Reactivity: The Chemistry of Acids and Bases

      • Aspirin Is Over 100 Years Old!

      • 17.1 Acids and Bases: A Review

      • 17.2 The Brønsted-Lowry Concept of Acids and Bases Extended

      • 17.3 Water and the pH Scale

      • 17.4 Equilibrium Constants for Acids and Bases

      • 17.5 Acid–Base Properties of Salts

      • 17.6 Predicting the Direction of Acid–Base Reactions

      • 17.7 Types of Acid–Base Reactions

      • 17.8 Calculations with Equilibrium Constants

      • 17.9 Polyprotic Acids and Bases

      • 17.10 Molecular Structure, Bonding, and Acid–Base Behavior

      • 17.11 The Lewis Concept of Acids and Bases

      • CHAPTER GOALS REVISITED

      • KEY EQUATIONS

      • STUDY QUESTIONS

      • APPLYING CHEMICAL PRINCIPLES: THE LEVELING EFFECT, NONAQUEOUS SOLVENTS, AND SUPERACIDS

    • 18 Principles of Chemical Reactivity: Other Aspects of Aqueous Equilibria

      • Nature’s Acids

      • 18.1 The Common Ion Effect

      • 18.2 Controlling pH: Buffer Solutions

      • 18.3 Acid–Base Titrations

      • 18.4 Solubility of Salts

      • 18.5 Precipitation Reactions

      • 18.6 Equilibria Involving Complex Ions

      • 18.7 Solubility and Complex Ions

      • CHAPTER GOALS REVISITED

      • KEY EQUATIONS

      • STUDY QUESTIONS

      • APPLYING CHEMICAL PRINCIPLES: EVERYTHING THAT GLITTERS . . .

    • 19 Principles of Chemical Reactivity: Entropy and Free Energy

      • Hydrogen for the Future?

      • 19.1 Spontaneity and Energy Transfer as Heat

      • 19.2 Dispersal of Energy: Entropy

      • 19.3 Entropy: A Microscopic Understanding

      • 19.4 Entropy Measurement and Values

      • 19.5 Entropy Changes and Spontaneity

      • 19.6 Gibbs Free Energy

      • 19.7 Calculating and Using Free Energy

      • CHAPTER GOALS REVISITED

      • KEY EQUATIONS

      • STUDY QUESTIONS

      • APPLYING CHEMICAL PRINCIPLES: ARE DIAMONDS FOREVER?

    • 20 Principles of Chemical Reactivity: Electron Transfer Reactions

      • Battery Power

      • 20.1 Oxidation–Reduction Reactions

      • 20.2 Simple Voltaic Cells

      • 20.3 Commercial Voltaic Cells

      • 20.4 Standard Electrochemical Potentials

      • 20.5 Electrochemical Cells under Nonstandard Conditions

      • 20.6 Electrochemistry and Thermodynamics

      • 20.7 Electrolysis: Chemical Change Using Electrical Energy

      • 20.8 Counting Electrons

      • CHAPTER GOALS REVISITED

      • KEY EQUATIONS

      • STUDY QUESTIONS

      • APPLYING CHEMICAL PRINCIPLES: SACRIFICE!

    • Interchapter: The Chemistry of the Environment

      • The Atmosphere

      • Climate Change

      • The Aqua Sphere (Water)

      • Green Chemistry

      • SUGGESTED READINGS

      • STUDY QUESTIONS

  • PART FIVE: THE CHEMISTRY OF THE ELEMENTS AND THEIR COMPOUNDS

    • 21 The Chemistry of the Main Group Elements

      • Carbon and Silicon

      • 21.1 Element Abundances

      • 21.2 The Periodic Table: A Guide to the Elements

      • 21.3 Hydrogen

      • 21.4 The Alkali Metals, Group 1A

      • 21.5 The Alkaline Earth Elements, Group 2A

      • 21.6 Boron, Aluminum, and the Group 3A Elements

      • 21.7 Silicon and the Group 4A Elements

      • 21.8 Nitrogen, Phosphorus, and the Group 5A Elements

      • 21.9 Oxygen, Sulfur, and the Group 6A Elements

      • 21.10 The Halogens, Group 7A

      • CHAPTER GOALS REVISITED

      • STUDY QUESTIONS

      • APPLYING CHEMICAL PRINCIPLES: VAN ARKEL TRIANGLES AND BONDING

    • 22 The Chemistry of the Transition Elements

      • Memory Metal

      • 22.1 Properties of the Transition Elements

      • 22.2 Metallurgy

      • 22.3 Coordination Compounds

      • 22.4 Structures of Coordination Compounds

      • 22.5 Bonding in Coordination Compounds

      • 22.6 Colors of Coordination Compounds

      • 22.7 Organometallic Chemistry: Compounds with Metal–Carbon Bonds

      • CHAPTER GOALS REVISITED

      • STUDY QUESTIONS

      • APPLYING CHEMICAL PRINCIPLES: GREEN CATALYSTS

    • 23 Nuclear Chemistry

      • A Primordial Nuclear Reactor

      • 23.1 Natural Radioactivity

      • 23.2 Nuclear Reactions and Radioactive Decay

      • 23.3 Stability of Atomic Nuclei

      • 23.4 Rates of Nuclear Decay

      • 23.5 Artificial Nuclear Reactions

      • 23.6 Nuclear Fission

      • 23.7 Nuclear Fusion

      • 23.8 Radiation Health and Safety

      • 23.9 Applications of Nuclear Chemistry

      • CHAPTER GOALS REVISITED

      • KEY EQUATIONS

      • STUDY QUESTIONS

      • APPLYING CHEMICAL PRINCIPLES: THE AGE OF METEORITES

  • List of Appendices

    • A: Using Logarithms and Solving Quadratic Equations

    • B: Some Important Physical Concepts

    • C: Abbreviations and Useful Conversion Factors

    • D: Physical Constants

    • E: A Brief Guide to Naming Organic Compounds

    • F: Values for the Ionization Energies and Electron Attachment Enthalpies of the Elements

    • G: Vapor Pressure of Water at Various Temperatures

    • H: Ionization Constants for Aqueous Weak Acids at 25 °C

    • I: Ionization Constants for Aqueous Weak Bases at 25 °C

    • J: Solubility Product Constants for Some Inorganic Compounds at 25 °C

    • K: Formation Constants for Some Complex Ions in Aqueous Solution at 25 °C

    • L: Selected Thermodynamic Values

    • M: Standard Reduction Potentials in Aqueous Solution at 25 °C

    • N: Answers to Chapter Opening Questions and Case Study Questions

    • O: Answers to Check Your Understanding Questions

    • P: Answers to Review & Check Questions

    • Q: Answers to Selected Interchapter Study Questions

    • R: Answers to Selected Study Questions

  • Index/Glossary

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