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Introduction to Organic Chemistry
Chapter 19
Introduction to Organic Chemistry
Chapter 19
Hein and Arena (modified 5-06 with a couple of corrections 08)
Eugene PasserChemistry DepartmentBronx Community College
© John Wiley and Sons, Inc.
Version 1.0
This power point is from the old text. The Prentice Hall text is chapter 22-23. The content you are expected to know for ch. 22-23 is the Organic Molecules Lab and the worksheet that follows this power point (ch. 22 worksheet)
2
Chapter Outline19.2 The Carbon Atom
19.3 Hydrocarbons
19.4 Alkanes19.13 Alkyl Halides
19.14 Alcohols19.5 Structural Formulas and
Isomerism
19.6 Naming Alkanes
19.12 Hydrocarbon Derivatives
19.15 Naming Alcohols
19.16 Ethers
19.7 Alkenes and Alkynes
19.8 Naming Alkenes and Alkynes
19.11 Naming Aromatic Compounds
19.9 Reactions of Alkenes
19.10 Aromatic Hydrocarbons
19.17 Aldehydes and Ketones
19.18 Naming Aldehydes and Ketones
19.19 Carboxylic Acids
19.20 Esters
19.21 Polymers–Macromolecules
3
Organic Chemistry
The branch of chemistry that deals with carbon compounds.
– fats, proteins, carbohydrates
– fabrics
– wood and paper products
– plastics
– medicinals
4
Sources of Organic Compounds
Carbon-containing raw materials– petroleum and natural gas
– coal
– carbohydrates
– fats and oils
5
The Carbon Atom
The Carbon Atom
6
12 136 6 Carbon has two stable isotopes C and C.
146
Carbon has several radioactive isotopes.
The C isotope is used in radiocarbon
dating.
• The carbon atom is central to all organic compounds.
7
Carbon has four valence electrons
1s2, 2s2, 2p2
C
8
C
Carbon forms four single covalent bonds by sharing electrons with other atoms.
H
HH H
9
CH
HH H
Carbon forms four single covalent bonds by sharing electrons with other atoms.
10
CH
HH H
The bonds between carbon and other atoms are often drawn at right angles.
11
Actually the angle between the bonds is 109.5o
19.1 c
12
19.1 a
The bonds point to the corners of a tetrahedron.
19.1 b
14
19.1 a
The bonds point to the corners of a tetrahedron.
19.1 d
15
Space filling models.
19.2
16
One covalent bond can be formed between two carbon atoms. C C
single bond
A dash represents a covalent bond.
17
One covalent bond can be formed between two carbon atoms.
single bond
C C
18
Two covalent bonds can be formed between two carbon atoms. C C
double bond
19
Two covalent bonds can be formed between two carbon atoms.
double bond
C C
20
Three covalent bonds can be formed between two carbon atoms. C C
triple bond
21
Three covalent bonds can be formed between two carbon atoms.
triple bond
C C
22
Long chains of carbon atoms form by linking one carbon atom to another through covalent bonds.
CC
CC
CC
Cseven carbon chain
23
CC
CC
CC
C
C
Cnine carbon chain
C C
Long chains of carbon atoms form by linking one carbon atom to another through covalent bonds.
24
CC
CC
CC
C
C
Cnine carbon branched chain
Long chains of carbon atoms form by linking one carbon atom to another through covalent bonds.
25
HydrocarbonsHydrocarbons
26
• Hydrocarbons are compounds composed entirely of carbon and hydrogen atoms bonded to each other by covalent bonds.
27
• Saturated hydrocarbons have only single bonds between carbon atoms.
• Unsaturated hydrocarbons contain a double or triple bond between two carbon atoms.
• Aromatic hydrocarbons include benzene and all compounds resembling benzene.
28
19.3
carbon to carbon single bonds
carbon to carbon double bonds
carbon to carbon triple bonds
This is not the chart to copy for ch. 22 worksheet
29
AlkanesAlkanes
30
• Alkanes are also known as paraffins or saturated hydrocarbons.
• They are straight- or branched-chain hydrocarbons.
• There are only single covalent bonds between the carbon atoms of alkanes.
31
• Each member of a homologous series differs from the next member by a CH2
group.
• The members of a homologous series are similar in structure but differ in formula.
• Successive members in the alkane series differ from each other by one carbon and two hydrogen atoms. They form a homologous series.
32
The general formula of alkanes is CnH2n+2
n = 7
2 x 7 + 2 = 16
C7H16This is the chart you copy for the ch. 22 ws
33
Structural Formulas and Isomerism
Structural Formulas and Isomerism
34
• Structure means the way in which the atoms bond within the molecule.
• The properties of an organic substance are dependent on its molecular structure.
35
• Each carbon atom is joined to four other atoms by covalent bonds.
• These bonds are separated by angles of 109.5o.
• Alkane molecules are essentially nonpolar.
• Alkane molecules contain only carbon-carbon and carbon-hydrogen bonds.
36
Ccarbon has 4 bonds Nnitrogen has 3 bondsoxygen has 2 bonds Ohydrogen has 1 bond HIiodine has 1 bondchlorine has 1 bond Clbromine has 1 bond BrFfluorine has 1 bond
The majority of organic compounds are made from relatively few molecules: carbon, hydrogen, oxygen, nitrogen and the halogens.
37
Structures of Common Alkanes
Structures of Common Alkanes
38
C
H
HH
H
line structure form of
methane
CH4
space filling form of
methane
There is 1 possible structure for CH4.
19.419.4
39
CH3CH3
line structure form of ethane
C
H
CH
H
H
H
H
space filling form of ethane
There is 1 possible structure for C2H6.
19.4
40
line structure form of propane
C
H
CH
H
C
H
H
H
H
H
space filling form of propane
CH3CH2CH3
There is 1 possible structure for C3H8.
19.4
41
C C CC
H
H
H H
H
HH
H
H
H
line structure form of butane
CH3CH2CH2CH3space filling
form of butaneThere are 2 possible structures for C4H10
unbranched chain19.4
42
C C C
C
H
H
H
H H
HH
H H
H
line structure form of 2-methyl
propane
CH2CHCH3
CH3
branched chain
space filling form of 2-methyl
propane
branched chain
There are 2 possible structures for C4H10.
19.4
43
normal butane (n-butane) C4H10
2 –methyl propane
C4H10
C C CC
H
H
H H
H
HH
H
H
H
C C C
C
H
H
H
H H
HH
H H
H
m.p. 0.5oC
b.p. –138.3oC
m.p. –159.5oC
b.p. – -11.7oC
Normal butane and 2-methyl propane are isomers.
Isomers are compounds with the same molecular formula but different structural formulas.
44
Pentane (C5H12) has 3 isomers.
This is the carbon skeleton with the longest continuous carbon chain. It is the first isomer of pentane.
C C C C C
n-pentane
C C C C C
H
H
H
H
H
H
HH
H
H
H
H
Hydrogen is added to each carbon to form four bonds.
45
Pentane (C5H12) has 3 isomers.
2-methylbutane
To form the next isomer write a four carbon chain.
C C C CC C C C
C
Add the fifth carbon atom to either of the middle carbon atoms.
C C C C
C
Hydrogen is added to each carbon to form four bonds.
C C C C H
CH
H
H
H
HHH
H
H
H
H
46
Pentane (C5H12) has 3 isomers.
2,2-dimethylpropane
To form the third isomer write a 3 carbon chain.
C C C
Add the remaining two carbon atoms to the central carbon atom.
C C C
C
C
Hydrogen is added to each carbon to form four bonds.
C C C
C
C
HHH
HHH
H
H
H
H
H
47
Condensed structural formulas are often used to save time and space.
In a condensed structural formula the atoms and groups attached to a carbon atom are written to the right of that carbon atom.
C C CC
H
H
H H
H
HH
H
H
Hstructuralformula
CH3CH2CH2CH3
condensedstructural formula
C C C
C
H
H
H
H H
HH
H H
H
CH2CHCH3
CH3
48
Naming AlkanesNaming Alkanes
49
• The general formula of an alkyl group is CnH2n+1.
• Alkyl groups are used to name organic compounds.
The corresponding alkane has the formula
CnH2n+2
50
R= CnH2n+1 (any alkyl group)
R = CH3 — methyl group
R = CH3CH2 — ethyl group
The letter “R” is often used in formulas to represent any of the possible alkyl groups.
51
52
The naming of organic compounds is now done in accordance with the IUPAC system.
53
Alkenes and AlkynesAlkenes and Alkynes
54
• They contain fewer than the maximum number of hydrogens.
• Alkynes have four fewer hydrogen atoms than an alkane.
• Alkenes and alkynes are unsaturated.
• Alkenes have two fewer hydrogen atoms than an alkane.
55
Alkenes contain a carbon-carbon double bond.
Alkynes contain a carbon-carbon triple bond.
General formula for alkenes: CnH2n
General formula for alkynes: CnH2n-2
56
57
19.5
Alkene Alkyne
double bond
58
19.5
Alkene Alkyne
triple bond
59
NamingAlkenes and Alkynes
NamingAlkenes and Alkynes
60
Reactions of AlkenesReactions of Alkenes
61
• This greater reactivity is due to the carbon-carbon double bonds.
• Addition at the carbon-carbon double bond is the most common alkene reaction.
• Alkenes are more reactive than their corresponding alkanes.
62
Addition Reactions
Addition of bromine to 2-penteneBromine adds across the double bond.
2,3-dibromopentane
double bond breaks saturated
63
Addition Reactions
Addition of hydrogen chloride to 1-butene
2-chlorobutane
Hydrogen chloride adds across the double bond.
double bond breaks saturated
64
Aromatic Hydrocarbons
Aromatic Hydrocarbons
65
• Aromatic originally referred to the pleasant odor of these molecules, but this meaning has been dropped.
• Benzene and all substances with structures resembling benzene are classified as aromatic compounds.
66
• Its molecular formula is C6H6
• The determination of a structural formula for benzene was difficult.
• Benzene was discovered in 1825 by Michael Faraday.
67
• In 1865 August Kekulé proposed that the carbon atoms in a benzene molecule are arranged in a six-membered ring with one hydrogen atom bonded to each carbon atom and with three carbon-carbon double bonds.
68
benzene space filling model
benzene Kekulé structure
3 double bonds
6 carbons in a ring
69
Benzene does not react like an alkene.
C6H6 + Cl2 → C6H5Cl + HClFe
Chlorine substituted for a hydrogen.
Instead of addition reactions it undergoes substitution reactions.
70
Benzene is a hybrid of these two Kekulé structures.
71
The corner of each hexagon represents a carbon and a hydrogen atom.
The structure of benzene can be represented in two abbreviated ways.
CH
CH
72
Naming Aromatic Compounds
Naming Aromatic Compounds
73
• A monosubstituted benzene has the formula C6H5G where G is the group that replaces a hydrogen atom.
• All hydrogens in benzene are equivalent.
• It does not matter which hydrogen is replaced by G.
• A substituted benzene is derived by replacing one or more of benzene’s hydrogen atoms with an atom or group of atoms.
74
Monosubstituted BenzenesMonosubstituted Benzenes
75
• Some monosubstituted benzenes are named by adding the name of the substituent group as a prefix to the word benzene.
• The name is written as one word.
76
nitrobenzene
nitro group
77
ethylbenzene
ethyl group
78
• Certain monosubstituted benzenes have special names.
• These are parent names for further substituted compounds.
79
methyl group
toluene
80
hydroxy group
phenol
81
carboxyl group
benzoic acid
82
amino group
aniline
83
• C6H5— is the phenyl group.
• It is used to name compounds that cannot be easily named as benzene derivatives.
84
diphenylmethane
4-phenyl-2-pentene
85
Disubstituted BenzenesDisubstituted Benzenes
86
• Three isomers are possible when two substituents replace hydrogen in a benzene molecule.
• The prefixes ortho-, meta- and para- (o-, m- and p-) are used to name these disubstituted benzenes.
87
ortho-dichlorobenzene(1,2-dichlorobenzene)mp –17.2oC, bp 180.4oC
ortho disubstituted benzene
substituents on adjacent carbons
88
meta-dichlorobenzene(1,3-dichlorobenzene)mp –24.82oC, bp 172oC
meta disubstituted benzene
substituents on adjacent carbons
89
para-dichlorobenzene(1,4-dichlorobenzene)mp 53.1, bp 174.4oC
para disubstituted benzene
substituents are on opposite sides of the benzene ring
90
phenolnitrophenol
When one substituent corresponds to a monosubstituted benzene with a special name, the monosubstituted compound becomes the parent name for the disubstituted compound.
91
When one substituent corresponds to a monosubstituted benzene with a special name, the monosubstituted compound becomes the parent name for the disubstituted compound.
toluenem-nitrotoluene
92
Hydrocarbon Derivatives
Hydrocarbon Derivatives
93
• Hydrocarbon derivatives are compounds that can be synthesized from a hydrocarbon.
• In addition to carbon, they contain such additional elements as oxygen, nitrogen, or a halogen.
• The compounds can be grouped into several classes. The compounds in each class have similar properties.
94
95
AlkylHalidesAlkyl
Halides
96
• An alkyl halide has the formula RX where X = Cl or Br.
• They are formed in a substitution reaction in which a halogen replaces hydrogen.
97
RH + X2 → RX + HXuv
light
When a specific halogen is used the name reflects this: chlorination
CH3CH3 + Cl2 → CH3CH2Cl + HCluv
light
98
AlcoholsAlcohols
99
• Alcohols are organic molecules whose molecules contain the –OH functional group.
• The general formula for alcohols is ROH.
100
• Alcohols do not dissociate in water yielding OH- as do metallic hydroxides.
• The –OH group is attached to the carbon by a covalent bond and not an ionic bond as in metallic hydroxides.
• Alcohols are classified as primary (1o), secondary (2o) or tertiary (3o).
• Alcohols form a homologous series.
102
Primary Alcohol
The carbon to which the – OH group is attached is bonded to one carbon.
103
Secondary Alcohol
The carbon to which the –OH group is attached is bonded to two carbons.
104
Tertiary Alcohol
The carbon to which the –OH group is attached is bonded to three carbons.
105
19.6
106
• Alcohols that contain more than one OH group attached to different carbons are called polyhydroxy alcohols.
Polyhydroxy Alcohols
• Monohydroxy: one OH group per molecule.
• Dihydroxy: two OH groups per molecule.
• Trihydroxy: three OH groups per molecule.
107
108
Naming AlcoholsNaming Alcohols
109
EthersEthers
110
• An ether has the formula ROR´.
• R and R´ can be the same or different groups.
• R and R´ can be saturated, unsaturated or aromatic.
• Saturated ethers have little chemical reactivity but are often used as solvents.
111
• Alcohols and ethers are isomeric.
• They have the same molecular formula but different structural formulas.
• An alcohol and its isomeric ether have different chemical and physical properties.
112
CH3CH2OH
ethanolB.P. 78.3oC
hydrogen bondssoluble in water
C2H6O
CH3–O–CH3
dimethyl etherB.P. –27.3oC
does not hydrogen bondinsoluble in water
C2H6O
113
Naming EthersNaming Ethers
114
Common Names
Common names of ethers are formed from the names of the groups attached to the carbon atom in alphabetical order followed by the word ether.
CH3CH2CH2 — O — CH2CH3
propyl ethyl
ethyl propyl ether
ether
115
Aldehydesand KetonesAldehydes
and Ketones
116
carbonyl groupcarbon is
double bonded to the oxygen
Aldehydes and ketones contain
the carbonyl group.
117
Aldehydes have at least one hydrogen bonded to the carbonyl group. The other group bonded to the carbonyl group is an alkyl (R) or aromatic (Ar) group.
118
Ketones have two alkyl (R) or aromatic (Ar) groups bonded to the carbonyl group.
119
Naming Aldehydesand Ketones
Naming Aldehydesand Ketones
120
Naming AldehydesNaming Aldehydes
121
The IUPAC names of aldehydes are obtained by dropping the –e and adding -al to the name of the parent hydrocarbon.
butane butanal al
122
Naming KetonesNaming Ketones
123
• The IUPAC name of a ketone is derived from the name of the alkane corresponding to the longest carbon chain that contains the ketone-carbonyl group.
• The parent name is formed by changing the –e ending of the alkane to -one.
propane propanone one
124
Carboxylic AcidsCarboxylic Acids
125
carbonyl group
Carboxylic acids contain the carboxyl group.
OH bonded to a carbonyl
carbon.
126
The carboxyl group can also be written as
or
127
• Open-chain carboxylic acids form a homologous series.
• The carbonyl group ( ) is always at the beginning of a carbon chain.
• The carbonyl carbon atom is always designated as C-1.
3 2 1
128
• The IUPAC name of a carboxylic acid is derived from the name of the alkane corresponding to the longest carbon chain that contains the carboxyl group.
• The parent name is formed by changing the –e ending of the alkane to –oic acid.
methanone oic acid methane
129 propanone oic acid
• The IUPAC name of a carboxylic acid is derived from the name of the alkane corresponding to the longest carbon chain that contains the caroxyl group.
• The parent name is formed by changing the –e ending of the alkane to –oic acid.
propane
130
• Organic acids are usually known by common names.
• These names usually refer to a natural source of the acid.
ethanoic acid
IUPAC name
acetic acid
common name
131
• Organic acids are usually known by common names.
• These names usually refer to a natural source of the acid.
methanoic acid
IUPAC name
formic acid
common name
132
• This is the simplest aromatic acid.
benzoic acid
133
134
EstersEsters
135
carbonyl group
OR´ bonded to a carbonyl
carbon.
An ester is an organic compound derived from a carboxylic acid and an alcohol.
The ester functional group is –COOR.
136
137
Polymers-Macromolecules
Polymers-Macromolecules
138
• A polymer (macromolecule) is a natural or synthetic giant molecule formed from smaller molecules (monomers).
• Monomers are the small units that undergo polymerization to form a polymer.
• Polymerization is the process of forming very large, high molar-mass molecules from monomers.
139
Formation of Polyethylene
nCH2=CH2 → CH2 CH2[CH2 CH2]n CH2 CH2 CH2 CH3
ethylene monomerpolyethylene
• n = the number of monomer units.
• n ranges from 2,500 to 25,000
140
141
142
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