Download Packet 14: Organic Chemistry

Organic Chemistry
TOPIC 11 REVIEW BOOK
TA B L E S P, Q A N D R
What is Organic Chemistry?
 study of carbon and the compounds that it forms
 carbon has 4 valence electrons so it will form 4 covalent
bonds- lends itself to a great variety of compounds
 May also contain but are not limited to the following
elements:
a) Oxygen
e) Phosphorus
b) Nitrogen
f) Sulfur
c) Fluorine
g) hydrogen
d) Bromine
Properties of Organic Compounds
 Covalent bonds
 generally nonpolar- what does that mean?
 insoluble in water
 low mp’s and bp’s: boiling point is directly related to the
length of carbon chain
 nonelectrolytes
 slow to react because of the covalent bonds – many
reactions require a catalyst
 Hundreds of thousands of organic compounds because C
can form so many bonds
Quick Review
 How many valence electrons does an atom of carbon
have?
 How many bonds can an atom of carbon make?
 Draw a Lewis structure for CH4
 Draw C2H6
Draw C6H14
Hydrocarbons (Tables P and Q)
 molecules that contain only
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carbon and hydrogen
May have single, double or
triple bonds
May form straight chains,
branched chains or rings
homologous series 
different groups of
hydrocarbons
each group contains
molecules that have similar
structures and properties
as the molecular mass
increases, the boiling point
increases (why?)
1. Alkanes
 Only single bonds
 Saturated the general formula is CnH2n+2
 End in –ane
 Prefix tells you the number of carbon atoms
 Example: Methane, Ethane, Propane, etc
 May be straight or
branched chains
2. Alkenes
 One double bond (C = C) rest are single
 Unsaturated
 The general formula is CnH2n
 First member is ethene
Examples: Propene, Butene, Pentene
 May be straight or
 branched chains
3. Alkynes
 one triple bond, the rest are single
 unsaturated
 the general formula is CnH2n-2
 First member is ethyne
Example: Propyne, Butyne,
Pentyne
May be straight or branched
Aromatic Hydrocarbons
 Made up of a chain of hydrocarbons that form a ring
 Most common one is benzene
 C6H6 in a ring of alternating double
And single bonds
Isomers
 molecules that have the same number and types of
elements but are arranged differently
 They will have different properties
Naming and Drawing Straight Chain Alkanes
Without Branches
 identify the number of carbons
 use table P to get the prefix for that number
 add the suffix “ane”
 Ex: CH4= “meth” + “ane” = methane
 ethane

propane
 Butane
 Pentane
 Hexane
 octane
Naming and Drawing Straight Chain Alkenes
Alkenes without branches
 Name alkenes the same way you would alkanes, EXCEPT you
must specify the location of the double bond by using the lower
number of the two that it is in between
Examples:
Ethene
Propene
Butene (1 Butene, 2 Butene)
Pentene (1 Pentene, 2 Pentene, 3 Pentene)
Naming and Drawing Alkynes
 The rules for naming alkynes are the same for alkenes,
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except there is a triple bond instead of a double bond
2-butyne
2-hexyne
3 hexyne
1 pentyne
3 octyne
Naming and Drawing Branched Alkanes
You need to be able to identify
three things: Parent chain, branch
name, location
1. Identify the longest continuous
chain (parent chain)- use table P
for the prefix and add -ane
2. Find the branches
3. Number the carbons in the parent
chain, starting at the side closest
to the branch
4. Count the number of carbon
atoms in the branch and get the
prefix from Table P and add the
suffix –yl
5. Use the number of the parent
carbon atom, the name of the side
chains and the name of the parent
chain
Example
 4 ethyl octane
Naming Branched Alkanes
 If the same group occurs
more than once as a
side chain, you indicate
this using prefixes (ex:
di, tri). Indicate the
positions of each group
with a number
 If the side chains are
different, name the one
with the smallest carbon
number first
 2,3 dimethyl pentane
Naming and Drawing Branched Alkenes
and
Alkynes
Branched Alkenes and Alkynes
 follow the same rules for naming branched alkanes,
EXCEPT when numbering the carbons, start with
the side closest to the double bond or triple bond
rather than the nearest side chain
Functional Groups – Replacement of
One or
More H
 Other types of organic
compounds can form when
different atoms replace
one or more of the
hydrogens
 happens to alkanes
 These atoms or groups of
atoms are called functional
groups
 They give the compound
specific physical and
chemical properties
1. Halides
 When one of the halogens (F, Cl, Br, I) replaces a hydrogen
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atom
called a halide or a halocarbon
The functional group is the halogen
Naming: Specify the location of the halogen and use the
following prefixes: chloro, fluoro, bromo, iodo
Uses: Teflon, Freon, CFC’s, dry cleaning solvents,
pesticides
2. Alcohols
 a hydrogen on an alkane is replaced with an
-OH
group (hydroxyl group- NOT hydroxide ion!)
 the functional group is –OH
 Classified according to the number of carbons bonded
to the carbon where the –OH is
 Primary, secondary, tertiary
 Naming: Drop the “e” and add “ol”; specify the location
of the –OH
 Uses: fuel, solvents, industrial feedstock (used to make
other products, such as formaldehyde, etc)
3. Ethers
 The functional group is -O Naming: you name the left group and the right group
and you follow it by the word ether
 if both group are the same, use "di“
 Used to be used as anesthetics, used for
4. Aldehydes
 contain a carbonyl (C=O) group on an end carbon
 No numbering
 Naming: Drop the “e” and add “al”
5. Ketones
 Carbonyl group on any carbon atom except the end
ones
 Formed by the oxidation of a secondary alcohol
 Naming: drop the “e” and add “one”, specify the
location
6. Organic Acids
 The functional group is -COOH which is called a carboxyl
group
 Usually formed by oxidizing alcohols
 Carboxyl groups are only attached to end carbons, so no
numbering is needed
 Naming: drop the “e” and add “oic acid”
7. Esters
 They are formed from a reaction between a carboxylic
acid and an alcohol
 Naming: The name of the alcohol is given first, with the
suffix changed to “yl”
 Then the name of the acid is given with the suffix
changed to “oate”
8. Amines
 The functional group is -NH2
 called an amino group
 Naming: drop the “e” and adding “amine”, specify
location
9. Amides
 They contain an amino group attached to the carbon
atom of a carbonyl group
 Naming: drop the “e” and add “amide”
Organic Reactions
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Hydrocarbons are not reactive at room temperature
because of strong C-C and C-H bonds
at very high temps, hydrocarbons can undergo many
different reactions
1. Substitution
 replacement of one or more hydrogen atoms in an alkane
with another atom or group
 ex. halogen atoms replace a hydrogen atom on an alkane
to make a halide and an acid
 ex. C2H6 + Cl2  C2H5Cl + HCl
2. Addition
 involves adding one or more atoms at the site of a double
or triple bond
 occurs in alkenes or alkynes
 Ex. C2H4 + Cl2  C2H4Cl2
3. Hydrogenation
 type of addition
 it is the addition of hydrogen to an unsaturated
compound to make it saturated
 it requires a catalyst and a raised temp
 Ex. C2H4 + H2  C2H6
4. Esterification
 the reaction of an organic acid with an alcohol to produce
an ester plus water
 slow reaction that is reversible
 usually have pleasant odors
5. Saponification
 when an ester (fat) reacts with an inorganic base (NaOH)
to produce an alcohol and a soap
6. Polymerization
 the formation of large molecules called polymers by
combining smaller units called monomers
 used to make plastics and rubber, proteins, starches and
cellulose
 Condensation polymerization: the bonding of
monomers by a dehydration reaction
 ex. glucose + glucose  sucrose + water
 Addition polymerization: the joining of monomers by
eliminating double or triple bonds
 Ex. ethene + ethene = butane
7. Fermentation
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when yeast breaks down 6-carbon sugars to produce
carbon dioxide and an alcohol
ex. C6H12O6  2C2H5OH + CO2
8. Combustion (and so...we end as we began)
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When a saturated hydrocarbon reacts with oxygen to produce
water and carbon dioxide
A lot of energy (heat) is given off
C3H6 +5O2  3CO2 + 4H2O
Lastly…
 Practice your regents exams
 Use the Barron’s book
 Bring a NON-GRAPHING calculator, a black pen and pencil
(for drawing) to the Regents Exam
Have a great summer and come back to visit next year!