TEST BANK & STUDY GUIDE FOR Organic Chemistry Study Guide, Key Concepts, Problems and Solutions By Robert J. Ouellette and J. David Rawn
Organic
... [Show More] Chemistry Study Guide:
Key Concepts, Problems, and Solutions
Robert J. Ouellette
Professor Emeritus, Department
of Chemistry, The Ohio State University
And
J. David Rawn
Professor Emeritus,
Towson University
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ISBN: 978-0-12-801889-7
Library of Congress Cataloging-in-Publication Data
Ouellette, Robert J., 1938-
Organic chemistry study guide : key concepts, problems, and solutions / Robert J. Ouellette,
J.David Rawn.
pages cm
ISBN 978-0-12-801889-7
1. Chemistry, Organic–Problems, exercises, etc. I. Rawn, J. David, 1944- II. Title.
QD257.O94 2014
547.0076–dc23
2014027632
British Library Cataloguing in Publication Data
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1
Structure and Bonding in
Organic Compounds
1
Keys to the chapter Atomic Structure and Properties
Two periodic trends are important to understanding the physical and chemical properties of organic
compounds. They are electronegativity and atomic radius.
The electronegativity scale is an index of the attraction of an atom for an electron. It increases
from left to right in a period and from bottom to top in a group of the periodic table. The
order of electronegativities for the three most common elements in organic molecules, excluding
hydrogen, is C < N < O. Their electronegativity values differ by 0.5 between neighboring elements
in this part of the second period. There is a more pronounced difference between second and third
period elements. Thus, fluorine and chlorine differ by 1.0, as do oxygen and sulfur. The order of the
electronegativity values of the halogens is I < Br < Cl.
Ionic and Covalent Bonds
There are two main classes of bonds. Ionic bonds predominate in inorganic compounds, but covalent
bonds are much more important in organic chemistry. When positive and negative ions combine
to form an ionic compound, the charges of the cations and anions must be balanced to give a
neutral compound. For ionic compounds, the cation is named first and then the anion. Thus, ammonium
sulfide contains (NH₄)₂ and S2−. Two ammonium ions are required to balance the charge of
one sulfide ion, so the formula of ammonium sulfide is (NH₄)₂S. Parentheses enclose a polyatomic
ion when a formula unit contains two or more of that ion, and the subscript is placed outside the
parentheses.
A covalent bond forms when two nuclei are simultaneously attracted to the same pair of
electrons. Carbon usually forms covalent bonds to other elements. The stability of Lewis structures
is attributed to the octet rule that states that second row elements tend to form associations of
atoms with eight electrons (both shared and unshared) in the valence shell of all atoms of the molecule.
One or more pairs of electrons can be shared between carbon atoms. Single, double, and
triple bonds are linked one, two, and three pairs of electrons, respectively. In applying the octet rule,
the bonding electrons are counted twice. That is, each atom “owns” the bonding electrons, so they
count toward the total of eight for each atom.
With the exception of bonds to carbon and to hydrogen, carbon forms polar covalent
bonds to other elements. The degree of polarity depends on the difference in the electronegativity
values of the bonded atoms. The direction of the bond moment is indicated by an arrow with a cross
at the end opposite the arrow head. The symbols δ+ and δ− indicate the partially positive and partially
negative atoms of the bonded atoms.
Strategy for Writing Lewis Structures
When we write a Lewis structure, we first need to know how many electrons are in a molecule based
and where they are located.
Consider vinyl chloride, C₂H₃Cl, which is used to produce polymers for commercial products
such as PVC pipes. It contains a total of 18 electrons. Hydrogen forms only one bond in all
compounds. Chlorine also forms one bond to carbon. The basic skeleton of the molecule is shown
below.
C C
H
H Cl
H
Organic Chemistry Study Guide: Key Concepts, Problems, and Solutions http://dx.doi.org/10.1016/B978-0-12-801889-7.00001-7
Copyright © 2015 Elsevier Inc. All rights reserved.
2
The molecular skeleton accounts for eight electrons; two per single bond. Each carbon atom still
needs two more electrons to complete its octet, and the chlorine atom needs six. The six electrons
on chlorine form three lone pairs. Each carbon contributes one electron to the single bond. Each
carbon has four electrons, and each donates one more to form a double bond.
C C
H
H Cl
H
C C
H
H Cl
H
Formal Charge
We determine formal charges in several steps.
1. Count the total number of valence electrons for each atom in the molecule.
2. Each atom “owns” its nonbonded electron pairs.
3. Electrons in bonds are shared equally between the bonded atoms; in a single bond each atom gets
one electron, in a double bond it gets two, and so forth.
4. If an atom has more electrons in the bonded structure than it would have if neutral, it has a formal
negative charge; if it has fewer electrons than it would have as a neutral atom, it has a formal
positive charge.
A few simple rules make it easy to determine the formal charge in most cases by inspection. For example,
if nitrogen has three bonds—regardless of the combination of single, double, or triple bonds—and
a pair of electrons, then it has no formal charge. If there are four bonds to nitrogen—regardless of the
combination of single, double, or triple bonds—the nitrogen atom has a formal +1 charge. Similarly,
if oxygen has two bonds—regardless of the combination of single or double bonds—and two pairs of
electrons, then it has no formal charge. If there are three bonds to oxygen—regardless of the combination
of single or double bonds—the oxygen atom has a formal +1 charge. The structure shown below
contains an oxygen atom with a +1 formal charge; the entire species has a net +1 charge.
Resonance Theory
For most compounds, one Lewis structure describes the distribution of electrons and the types of
bonds in a molecule. However, for some species a single Lewis structure does not provide an adequate
description of bonding. Resonance structures provide a bookkeeping device to describe the delocalization
of electrons, giving structures that cannot be adequately described by a single Lewis structure.
Such bonding is described using two or more resonance contributors that differ only in the location
of the electrons. The positions of the nuclei are unchanged. The actual structure of a molecule that is
pictured by resonance structures has characteristics of all the resonance contributors.
CH3 C
− O
O
CH3 C
O
O −
structure 1 structure 2
Curved arrows are used to show the movement of electrons to transform one resonance contributor
into another. The electrons move from the position indicated by the tail of the arrow toward the position
shown by the head.
The degree to which various resonance forms contribute to the actual structure in terms of
the properties of the bonds and the location of charge is not the same for all resonance forms. The
overriding first rule is that the Lewis octet must be considered as a first priority. After that, the location
of charge on atoms of appropriate electronegativity can be considered.
C O
H
H H
3
Valence-Shell Electron-Pair Repulsion Theory
Like charges repel each other, so the electron pairs surrounding a central atom in a molecule should repel
each other and move as far apart as possible. We use valence-shell electron-pair repulsion (VSEPR)
theory to predict the shapes of molecules. VSEPR theory allows us to predict whether the geometry
around any given atom is tetrahedral, trigonal planar, or linear.
Using VSEPR theory requires that regions of electron density be considered regardless of how many
electrons are contained in the region. Thus, a single-bonded pair or two pairs of electrons in a double
bond are considered as “equal.” The following rules cover most cases.
1. Two regions containing electrons around a central atom are 180° apart, producing a linear arrangement.
2. Three regions containing electrons around a central atom are 120° apart, producing a trigonal
planar arrangement.
3. Four regions containing electrons around a central atom are 109.5° apart, producing a tetrahedral
arrangement.
The electron pairs around a central atom may be bonding electrons or nonbonding electrons, and
both kinds of valence-shell electron pairs must be considered in determining the shape of a molecule.
When all of the electron pairs are arranged to minimize repulsion, we look at the molecule to see how
the atoms are arranged in relation to each other. The geometric arrangement of the atoms determines
the bond angles.
Consider the structure of an isocyanate group in methylisocyanate.
The nitrogen atom has three regions containing electrons around it. They are a single bond, a double
bond, and a nonbonded pair of electrons. So, these features will have a trigonal planar arrangement,
and the R—NC bond angle is 120°. The isocyanate carbon atom has two groups of electrons around
it—two double bonds—so they will have a linear arrangement. The NCO bond angle is 180°.
Dipole Moments
The polarity of a molecule is given by its dipole moment. The dipole moment depends upon both the
polarity of individual bonds and the arrangement of those bonds in the molecule. In some molecules,
the dipole moments are pointed in opposite directions so that they cancel one another. As a result,
there is no net resultant dipole moment. In other molecules, the dipole moments may reinforce each
other or partially cancel, causing a net dipole moment.
Atomic and Molecular Orbitals
Atomic orbitals are mathematical equations that describe the discrete, quantized energy levels of atoms.
They are described as 1s, 2s, 2p, and so forth. Each atomic orbital can contain a maximum of two
electrons with opposite spins. The square of the equation for an atomic orbital gives the probability of
finding an electron within a given region of space.
The concepts developed for atomic orbitals can be extended to molecular orbitals that extend
across a molecule. Molecular orbitals are linear combinations of atomic orbitals, which represent the
distribution of electrons over two or more atoms. The important concepts are summarized below.
1. The number of molecular orbitals must equal the number of atomic orbitals used to generate
them.
2. Molecular orbitals, as Well as atomic orbitals, are represented by wave functions whose value may
be positive or negative and is a function of geometry.
3. There are two types of bonding molecular orbitals to hydrogen and to second row elements, called
sigma (s) and pi (π). Hydrogen forms only one s bond.
4. Molecular orbitals can be bonding or antibonding.
C N C O
H
H
H
methyl isocyanate
4
The Hydrogen Molecule
The 1s orbitals of two hydrogen atoms can combine in two ways to give molecular orbitals. One of
these is a bonding s orbital; the other is an antibonding, s* orbital. Bonding molecular orbitals have
lower energy (are more stable) than the original atomic orbitals. Antibonding molecular orbitals have
higher energy (are less stable) than the original atomic orbitals. The bonding s orbital holds two electrons,
and the antibonding s* orbital is empty.
Bonding in Carbon Compounds
The strongest bonds between carbon atoms and other atoms are s bonds that result from overlap of
atomic orbitals along the internuclear axis. Side-by-side overlap of p orbitals leads to a less stable π
bond.
Atomic orbitals are combined (mixed) to give hybridized atomic orbitals. These orbitals account
for the geometry and properties of molecules, and they follow the rules for VSEPR theory.
sp³ Hybridization of Carbon in Methane
Bonding in methane can be regarded as the formation of covalent bonds between an sp³-hybridized
carbon atom and 1s orbital of hydrogen atoms. An sp³-hybrid orbital is constructed from mixing the
2s orbital of an excited state carbon atom, which contains one electron, with three 2p orbitals, each of
which also contains one electron. The resulting sp³-hybrid orbitals point at the corners of a tetrahedron.
Each of them forms a s bond with the 1s orbital of a hydrogen atom.
The term % s character is used to describe the contribution of the atomic orbitals to a hybridized
orbital. Thus an sp³-hybrid orbital has 25% s character.
sp³ Hybridization of Carbon in Ethane
Ethane and other organic compounds containing four single bonds to carbon atoms consist of sigma
bonds to sp³-hybridized carbon atoms arranged at tetrahedral angles to one another. In ethane, two
sp³ hybrid orbitals overlap to give a s bond. The other three sp³ hybrid orbitals on each carbon make
s bonds to hydrogen atoms.
Groups of atoms can rotate about a sigma bond without breaking the bond. The resulting
conformations are different temporary arrangements of atoms that still maintain their bonding arrangement.
sp² Hybridization of Carbon in Ethene
The sp² hybrid orbitals of carbon occur in compounds such as ethene that contain a double bond. The
overlap of these orbitals with one another or with other orbitals such as an s orbital of hydrogen gives
a sigma (s) bond. The three sp² hybrid orbitals are coplanar and lie 120° to one another. They have
33% s character because they are formed from one 2s orbital and two 2p orbitals. An sp² hybridized
carbon also has a 2p orbital that can form a π bond with a neighboring carbon atom in ethene or to a
carbon atom in methanal. The s bond in ethene and other alkenes is stronger than the p bond because
there is less orbital overlap in the p bond.
sp Hybridization of Carbon in Ethyne
The sp hybrid orbitals of carbon occur in compounds such as ethyne that contain a triple bond. The
overlap of these orbitals with one another or with other orbitals such as an s orbital of hydrogen gives a
sigma bond. The sp hybrid orbitals are at 180° to one another. They have 50% s character because they
are formed from one 2s orbital and one 2p orbital. Each time there are two sp hybrid orbitals about a
carbon atom, there are also two remaining p orbitals that form two π bonds with a neighboring atom,
as in the case of another carbon atom in ethyne or a nitrogen atom in cyano compounds.
Effect of Hybridization on Bond Length and Bond Strength
With increasing % s character, the electrons within a hybrid orbital are held closer to the nucleus
of the atom. As a consequence, the bond lengths decrease as the % s character increases. And, the
strength of the bond increases as % s character increases.
1. C—H bond strengths: ethane (sp³) < ethene (sp²) < ethyne (sp).
2. C—H bonds lengths: ethyne < ethene < ethane.
5
Hybridization of Nitrogen
Hybridization is not a phenomenon restricted to carbon. It applies to other atoms as well. The only
difference is in the number of electrons that are distributed in the orbitals. Nitrogen, a Group VA element,
has five valence electrons.
An sp³-hybridized nitrogen has three half-filled orbitals that can form s bonds and one filled
sp³ orbital that is a nonbonding electron pair. The orbital containing the nonbonding electron pair
and the three half-filled orbitals the bonding are directed to the corners of a tetrahedron. However, the
geometry of such molecules is pyramidal, like ammonia, because the position of the atoms, not the
electron pairs, defines the molecular geometry.
An sp²-hybridized nitrogen atom can form three s bonds and one π bond. The geometry of
sp² hybridized nitrogen is trigonal planar, and the bond angles around the nitrogen are 120°.
An sp-hybridized nitrogen atom can form two s bonds with sp orbitals and two π bonds
with its half-filled 2p orbitals.
Hybridization of Oxygen
The difference between the hybridization of oxygen compared to nitrogen and carbon is in the number
of electrons that are distributed in the orbitals. Oxygen, a Group VIA element, has six valence
electrons.
An sp³-hybridized oxygen atom has two electrons in each of two sp³ orbitals and one electron
in each of the remaining two sp³ orbitals. The bonded and nonbonded electron pairs are directed to
the corners of a tetrahedron. However, the shape of molecules like water is angular.
An sp²-hybridized oxygen atom has two electrons in two filled sp² orbitals and one half-filled
sp²-orbital. The sixth electron is in a 2p orbital, which can form a π bond. Note that the bond angle
for s bonds to sp²-hybridized orbitals is 120°.
6
1.1 How many valence shell electrons are in each of the following elements?
(a) N (b) F (c) C (d) O
(e) Cl (f ) Br (g) S (h) P
Answers: (a) 5 (b) 7 (c) 4 (d) 6 (e) 7 (f ) 7 (g) 6 (h) 5
1.2 Which of the following atoms has the higher electronegativity? Which has the larger atomic radius?
(a) Cl or Br (b) O or S (c) C or N (d) N or O (e) C or O
Answers: electronegativity: (a) Cl > Br (b) O > S (c) N > C (d) O > N (e) O > C
Answers: atomic radius: (a) Br > Cl (b) S > O (c) C > N (d) N > O (e) C > O
Atomic Properties
Ions and Ionic Compounds
1.4 Write a Lewis structure for each of the following ions.
(a) NO₂− (b) SO₃− (c) NH₂− (d) CO₃−
Lewis Structures of Covalent Compounds
1.5 Write a Lewis structure for each of the following compounds.
(a) NH₂OH (b) CH₃CH₃ (c) CH₃OH (d) CH₃NH₂ (e) CH₃Cl (f) CH₃SH
1.3 Write a Lewis structure for each of the following ions.
(a) OH− (b) CN− (c) H₃O+ (d) NO₃−
Answers:
(a) OH (b) (c)
− − −
−
C N H O
H
H H N
H
(d) H
H
(e) O N O
O
(a) (b) (c) (d) H N H (e) O C O
O
O
−
− −
−
− −
−
N O O S O
O
O
O S O
O
(a) (b) (c)
(d)
H N O
H H
H C C
H
H
H
H
H
H C O
H
H
H
H C N
H
H
H
H
(e) H C Cl
H
H
(f) H C S
H
H
H
Answers:
Answers:
solutions to End-of-chapter exercises
7
1.6 Write a Lewis structure for each of the following compounds.
(a) HCN (b) HNNH (c) CH₂NH (d) CH₃NO (e) CH₂NOH (f) CH₂NNH₂
1.7 Add any required unshared pairs of electrons that are missing from the following formulas.
CH3 C OH
O
(a) CH3 C OCH3
O
(b) H C NHCH3
O
(c)
(d) CH3 S CH CH2 CH3 C CH3
N
(e)
H
(f) N C CH2 C N
Answers:
(a) H C N (b) H N N H C
H
(c)
(d) (e) (f)
H N H
H C N
H
H
O H C
H
N O H H C
H
N N H
H
Answers:
CH3 C OH
O
(a) CH3 C OCH3
O
(b) H C NHCH3
O
(c)
(d) CH3 S CH CH2 CH3 C CH3
N
(e)
H
(f) N C CH2 C N
1.8 Add any required unshared pairs of electrons that are missing from the following formulas.
CH3 C Cl
O
(a) CH3 C SH
O
(b) CH3 O CH (c)
(d)
CH2
NH2 C O
O
CH3 CH (e) (f) CH3 O CH2
O CH3
O CH3 CH3 O CH3
Answers:
CH3 C Cl
O
(a) CH3 C SH
O
(b) CH3 O CH (c)
(d)
CH2
NH2 C O
O
CH3 CH (e) (f) CH3 O CH2
O CH3
O CH3 CH3 O CH3
1.9 Using the number of valence electrons in the constituent atoms and the given arrangement of atoms in the compound, write the
Lewis structure for each of the following molecules.
H N
H
C N
H
H
O
C N C
H
H
H
H
H
(a) C Cl
O
(b) Cl
(c) (d) H C
H
S O H
H O
8
1.10 Using the number of valence electrons in the constituent atoms and the given arrangement of atoms in the compound, write the
Lewis structure for each of the following molecules.
(a) (b)
(c)
(d) H C
H
O C N
H
H C S
H
H
C
H
H
H
S H C
H
C S H
O
H
H
H C
H
O
H
C
H
Cl
H
O
H
H
1.11 Two compounds used as dry cleaning agents have the molecular formulas C₂Cl₄ and C₂HCl₃. Write the Lewis structures for each
compound.
Answers:
(a) CH2 (b) Cl C
O
N CH3 Cl (c) C (d)
O
NH2 NH2 C
S
CH3 O H
Answers:
(a) CH3 S S CH3 C S
O
(b)
(c) CH3 O C (d)
CH3 H
Cl
H
H
C N
O
H
H
CH3 O
Answers:
(a) C C (b)
Cl
Cl Cl
Cl
C C
Cl
Cl H
Cl
1.12 Acrylonitrile, a compound used to produce fibers for rugs, is represented by the formula CH₂CHCN. Write the Lewis structure
for the compound.
Answer:
C C
H
H C
H
N
9
(a) none of the atoms has a formal charge
(b) nitrogen is +1; carbon is −1
(c) nitrogen is +1; oxygen is −1
(d) nitrogen atoms from left to right have 0, +1, and −1 formal charges
1.14 Assign the formal charges for the atoms other than carbon and hydrogen in each of the following species.
1.15 All of the following species are isoelectronic, that is, they have the same number of electrons bonding the same number of atoms.
Determine which atoms have a formal charge. Calculate the net charge for each species.
Answers:
(a) carbon is −1; oxygen is +1; total charge is 0
(b) nitrogen is zero; oxygen is +1; total charge is +1
(c) carbon is −1; nitrogen is 0; total charge is −1
(d) both carbon atoms are −1; total charge is −2
(a) C O (b) N O (c) C N (d) C C
Answers:
(a) oxygen is +1; boron is −1
(b) nitrogen is +1; aluminum is −1
(c) nitrogen is +1; singly bonded oxygen atom is −1
(d) phosphorus is +1; oxygen atom on the right is −1
(a) (b)
(c) (d)
CH3 O
CH3
N
CH3
CH3
P O
OCH3
OCH3
CH3 N CH3 O
O
O
BF3 CH3 AlCl3
1.16 All of the following species are isoelectronic, that is, they have the same number of electrons bonding the same number of atoms.
Determine which atoms have a formal charge. Calculate the net charge for each species.
Answers:
(a) central nitrogen atom is +1; the other nitrogen atoms are each −1; the total charge is −1
(b) nitrogen atom is +1; both oxygen atoms are 0; the total charge is +1
(a) N N N (b) O N O
Formal Charge
1.13 Assign the formal charges for the atoms other than carbon and hydrogen in each of the following species.
(a) H O C
CH3 N O
−
−
−
CH3
(b)
(c) (d) CH3 N
N H O N C
CH3
N N
Answers:
(a) H O C
CH3 N O
CH3
(b)
(c) (d) CH3 N
N H O N C
CH3
N N
10
1.18 The following species are isoelectronic. Determine which atoms have a formal charge. Calculate the net charge for each species.
Answers:
(a) O is −1 (b) Br is 0
(c) C is +1 (d) S is 0
(e) N is 0 (f ) N is −1
1.19 Acetylcholine, a compound involved in the transfer of nerve impulses [Show Less]