Knowt
Introduction to Organic Chemistry
organic compounds - compounds that contain carbon atoms
hydrocarbons - the simplest organic compounds, can be divided into four groups
Division of Hydrocarbons
Hydrocarbons - aliphatic and aromatic
Aliphatic - saturated and unsaturated
Saturated aliphatic-alkanes
Unsaturated aliphatic - alkenes, alkynes
Hydrocarbon Bonding
four valence electrons allow four other atoms to bond with carbon
alkanes - compounds that have only single bonds between the carbon atoms
alkenes and alkynes - compounds that have double or triple bonds between the carbon atoms
aromatic - carbon compounds in a ring structure
Nomenclature
stem that is used for all aliphatic compounds, different endings that indicate if the compound is an alkane, alkene, or alkyne
Number of Carbon atoms | Stem |
|---|---|
1 | Meth |
2 | Eth |
3 | Prop |
4 | But |
5 | Pent |
6 | Hex |
7 | Hept |
8 | Oct |
9 | Non |
10 | Dec |
Groups | Formulas |
|---|---|
Alkanes | CnH2n+2 |
Alkenes | CnH2n |
Alkynes | CnH2n-2 |
Two things to determine when naming an organic compound
the number of carbon atoms in the compound
the family the compound belongs to
Rules for Naming ALKANES
select the longest continuous chain in the molecule and count the number of carbon atoms to determine the stem
Consider every branch of the main chain to be a substituent derived from another hydrocarbon. For each group that is a substituent, take the stem and add “yl” (ex. methyl, ethyl)
Number the carbon atoms so that the substituents have the lowest possible number
Name each substituent by finding the number of the carbon atoms it is attached to and using the name from step two
Separate numbers using commas and letters using dashes
Arrange substituents alphabetically
Rules for Naming ALKENES and ALKYNES
Identify the longest continuous carbon chain that contains the double or triple bond.
Number the carbon atoms in the chain, starting from the end closest to the double or triple bond.
Determine the position of the double or triple bond by assigning the lowest possible numbers to the carbon atoms involved.
Use the appropriate prefix to indicate the number of double or triple bonds: "ene" for alkenes and "yne" for alkynes.
Indicate the position of the double or triple bond by using the corresponding number before the prefix.
If there are multiple double or triple bonds, use the prefixes "di-" (two), "tri-" (three), etc.
Include the names of any substituents attached to the carbon chain, using appropriate prefixes.
Separate numbers and prefixes with hyphens and separate multiple numbers with commas.
If there are different substituents, list them in alphabetical order.
Use commas to separate numbers and dashes to separate numbers from letters.
Example: 2-butyne
Halogen Attachment
Halogen attachments (F, Br, Cl, I) are very simple to include; they’re treated just as any other substituent
ending of their name is dropped and an “o” is added
Ex. Br becomes “bromo”
Isomers and the Use of “n” and “iso” Prefixes
Isomers are compounds that have the same molecular formula, but different structural formulas
the term “normal” is used to describe any STRAIGHT chain hydrocarbon above propane
abbreviation is the letter “n”
ex. n-butane, n-octane, n-decane
the term “iso” is used on a straight-chain alkane with a hydrogen atom replaced by a methyl group on the SECOND carbon
ex. isopentane, isobutane, isohexane
Cycloalkanes and Aromatic Compounds
In many hydrocarbons, the ends of the carbon chain bend around to form a chain
cyclic hydrocarbon - compounds that contain ring structures
aliphatic compounds - hydrocarbon does NOT contain a ring structure
Two main types of ring structures: cycloalkanes and aromatic compounds
Cycloalkanes
cycloalkanes are saturated ring compounds
carbon to carbon bonds are all single bonds, alkanes
their general molecular formula is the same for alkanes, CnH2n
naming rules are similar to rules for alkanes
Aromatic Compounds
aromatic compounds contain single or multiple rings
the simplest aromatic compound is benzene, C6H6
this molecule is a six-carbon chain, each with one hydrogen atom attached to it
this leaves one electron from each carbon atom free to bond and form a double bond
Naming Aromatic Rings
To name a compound attached to a benzene ring, follow similar rules to naming aliphatic compounds
If there's only one attachment, the name is the same as if it were attached to an alkane, and there's no need for numbering
If there are two attachments, number the compound, starting with the first attachment as one, and ensuring that the substituents have the lowest numbers
The numbers can be placed to the right or left of the benzene ring, with only three possible combinations
These combinations can be identified by numbers or prefixes.
Position | Prefix | Symbol |
|---|---|---|
1 and 2 | Ortho | o |
1 and 3 | Meta | m |
1 and 4 | Para | p |
When two benzene rings are joined together, the name is naphthalene, three rings is anthracene
if the benzene rings is attached to an aliphatic, the benzene radical is called “phenyl”
can be named as a benzene ring compound or aliphatic compound
Functional Groups
Functional Groups are structural fragments, or pieces, of different chemical compositions that are responsible for:
The classification of different substances into families, such as aliphatic and aromatic compounds
The reactivity of the family for chemical reactions
Examples of functional groups: alkanes, alkenes, alkynes, aromatic, cycloalkanes
label the base chain of carbon atoms as R and R’
R and R’ stand for any length of carbon atoms
alkyne: R-C-R’ or R-C-C-R’
Other Functional Groups
Alcohols - hydroxyl group -OH attached, R-OH
Ethers - two chains of carbon with an oxygen atom in the middle joining the atoms together R-O-R’
Organic acids - the carboxyl group and often called carboxylic acids
Esters - similar to organic acids but have a hydrocarbon group in place of the OH’s hydrogen atom on the carboxyl group
Aldehydes - related to esters by having the O-R’=H atom
Ketones - related to esters by having the O-R’ replaced with a R’
Amines - based on ammonia where one or more of the hydrogen is replaced with an organic group
Halocarbons - carbon chains that contain halogen atoms
Organic Compound - Functional Group Families
Compound Type | Functional Group Name |
|---|---|
Halocarbons | Halogen |
Alcohol | Hydroxyl |
Ether | Ether |
Aldehyde | CarbonYL |
Ketone | CarbonYL |
Carboxylic acid | CarbonXYL |
Ester | Ester |
Type | Group | Name | Examples |
|---|---|---|---|
Alcohol | R-OH | Take the name of the R group alkane and drop the “e” and add “ol | CH3OH - methanol CH3CH2CH2OH - butanol CH3CH2OH - ethanol |
Ether | R-O-R’ | Take the names of the R and R’ groups in alphabetical order and add the world ether at the end | CH3CH2-O-CH3 ethylmethyl ether CH3-O-CH3 dimethyl ether |
Aldehyde | O || R-C-H | Take the name of the R group, drop “e” and add “al”. The aldehyde carbon is given the number one in naming | CH3CH2CH2COH
(CH3)2CH2COH
|
Ketone | O || R-C-R’ | 1. Combine the O=R-C-R’ group as one long carbon chain and name it 2. O=R-C-R’ group is gen the lowest possible number. Drop the “e“ and add “one” | O || CH3CCH3
O || CH3CH2CCH3
|
Carboxylic | O || R-C-O-H | The COOH group is given the number one when naming. Drop the “e” in the name of the R group and add “oic” and the word acid | HCOOH - methanoic acid (formic acid) CH3COOH - ethnic acid (acetic acid) CH3CH2COOH - propanoic acid |
Ester | O || R-C-O-R’ | These names are derived from the name of the acid from which the ester comes from. Drop the “ic” and the ending “ate” is added. The R’ group is named first as a separate word | O || CH3CH2C-OCH2CH3
O || CH3CH2CH2C-OCH2CH3
|
Introduction to Organic Chemistry
organic compounds - compounds that contain carbon atoms
hydrocarbons - the simplest organic compounds, can be divided into four groups
Division of Hydrocarbons
Hydrocarbons - aliphatic and aromatic
Aliphatic - saturated and unsaturated
Saturated aliphatic-alkanes
Unsaturated aliphatic - alkenes, alkynes
Hydrocarbon Bonding
four valence electrons allow four other atoms to bond with carbon
alkanes - compounds that have only single bonds between the carbon atoms
alkenes and alkynes - compounds that have double or triple bonds between the carbon atoms
aromatic - carbon compounds in a ring structure
Nomenclature
stem that is used for all aliphatic compounds, different endings that indicate if the compound is an alkane, alkene, or alkyne
Number of Carbon atoms | Stem |
|---|---|
1 | Meth |
2 | Eth |
3 | Prop |
4 | But |
5 | Pent |
6 | Hex |
7 | Hept |
8 | Oct |
9 | Non |
10 | Dec |
Groups | Formulas |
|---|---|
Alkanes | CnH2n+2 |
Alkenes | CnH2n |
Alkynes | CnH2n-2 |
Two things to determine when naming an organic compound
the number of carbon atoms in the compound
the family the compound belongs to
Rules for Naming ALKANES
select the longest continuous chain in the molecule and count the number of carbon atoms to determine the stem
Consider every branch of the main chain to be a substituent derived from another hydrocarbon. For each group that is a substituent, take the stem and add “yl” (ex. methyl, ethyl)
Number the carbon atoms so that the substituents have the lowest possible number
Name each substituent by finding the number of the carbon atoms it is attached to and using the name from step two
Separate numbers using commas and letters using dashes
Arrange substituents alphabetically
Rules for Naming ALKENES and ALKYNES
Identify the longest continuous carbon chain that contains the double or triple bond.
Number the carbon atoms in the chain, starting from the end closest to the double or triple bond.
Determine the position of the double or triple bond by assigning the lowest possible numbers to the carbon atoms involved.
Use the appropriate prefix to indicate the number of double or triple bonds: "ene" for alkenes and "yne" for alkynes.
Indicate the position of the double or triple bond by using the corresponding number before the prefix.
If there are multiple double or triple bonds, use the prefixes "di-" (two), "tri-" (three), etc.
Include the names of any substituents attached to the carbon chain, using appropriate prefixes.
Separate numbers and prefixes with hyphens and separate multiple numbers with commas.
If there are different substituents, list them in alphabetical order.
Use commas to separate numbers and dashes to separate numbers from letters.
Example: 2-butyne
Halogen Attachment
Halogen attachments (F, Br, Cl, I) are very simple to include; they’re treated just as any other substituent
ending of their name is dropped and an “o” is added
Ex. Br becomes “bromo”
Isomers and the Use of “n” and “iso” Prefixes
Isomers are compounds that have the same molecular formula, but different structural formulas
the term “normal” is used to describe any STRAIGHT chain hydrocarbon above propane
abbreviation is the letter “n”
ex. n-butane, n-octane, n-decane
the term “iso” is used on a straight-chain alkane with a hydrogen atom replaced by a methyl group on the SECOND carbon
ex. isopentane, isobutane, isohexane
Cycloalkanes and Aromatic Compounds
In many hydrocarbons, the ends of the carbon chain bend around to form a chain
cyclic hydrocarbon - compounds that contain ring structures
aliphatic compounds - hydrocarbon does NOT contain a ring structure
Two main types of ring structures: cycloalkanes and aromatic compounds
Cycloalkanes
cycloalkanes are saturated ring compounds
carbon to carbon bonds are all single bonds, alkanes
their general molecular formula is the same for alkanes, CnH2n
naming rules are similar to rules for alkanes
Aromatic Compounds
aromatic compounds contain single or multiple rings
the simplest aromatic compound is benzene, C6H6
this molecule is a six-carbon chain, each with one hydrogen atom attached to it
this leaves one electron from each carbon atom free to bond and form a double bond
Naming Aromatic Rings
To name a compound attached to a benzene ring, follow similar rules to naming aliphatic compounds
If there's only one attachment, the name is the same as if it were attached to an alkane, and there's no need for numbering
If there are two attachments, number the compound, starting with the first attachment as one, and ensuring that the substituents have the lowest numbers
The numbers can be placed to the right or left of the benzene ring, with only three possible combinations
These combinations can be identified by numbers or prefixes.
Position | Prefix | Symbol |
|---|---|---|
1 and 2 | Ortho | o |
1 and 3 | Meta | m |
1 and 4 | Para | p |
When two benzene rings are joined together, the name is naphthalene, three rings is anthracene
if the benzene rings is attached to an aliphatic, the benzene radical is called “phenyl”
can be named as a benzene ring compound or aliphatic compound
Functional Groups
Functional Groups are structural fragments, or pieces, of different chemical compositions that are responsible for:
The classification of different substances into families, such as aliphatic and aromatic compounds
The reactivity of the family for chemical reactions
Examples of functional groups: alkanes, alkenes, alkynes, aromatic, cycloalkanes
label the base chain of carbon atoms as R and R’
R and R’ stand for any length of carbon atoms
alkyne: R-C-R’ or R-C-C-R’
Other Functional Groups
Alcohols - hydroxyl group -OH attached, R-OH
Ethers - two chains of carbon with an oxygen atom in the middle joining the atoms together R-O-R’
Organic acids - the carboxyl group and often called carboxylic acids
Esters - similar to organic acids but have a hydrocarbon group in place of the OH’s hydrogen atom on the carboxyl group
Aldehydes - related to esters by having the O-R’=H atom
Ketones - related to esters by having the O-R’ replaced with a R’
Amines - based on ammonia where one or more of the hydrogen is replaced with an organic group
Halocarbons - carbon chains that contain halogen atoms
Organic Compound - Functional Group Families
Compound Type | Functional Group Name |
|---|---|
Halocarbons | Halogen |
Alcohol | Hydroxyl |
Ether | Ether |
Aldehyde | CarbonYL |
Ketone | CarbonYL |
Carboxylic acid | CarbonXYL |
Ester | Ester |
Type | Group | Name | Examples |
|---|---|---|---|
Alcohol | R-OH | Take the name of the R group alkane and drop the “e” and add “ol | CH3OH - methanol CH3CH2CH2OH - butanol CH3CH2OH - ethanol |
Ether | R-O-R’ | Take the names of the R and R’ groups in alphabetical order and add the world ether at the end | CH3CH2-O-CH3 ethylmethyl ether CH3-O-CH3 dimethyl ether |
Aldehyde | O || R-C-H | Take the name of the R group, drop “e” and add “al”. The aldehyde carbon is given the number one in naming | CH3CH2CH2COH
(CH3)2CH2COH
|
Ketone | O || R-C-R’ | 1. Combine the O=R-C-R’ group as one long carbon chain and name it 2. O=R-C-R’ group is gen the lowest possible number. Drop the “e“ and add “one” | O || CH3CCH3
O || CH3CH2CCH3
|
Carboxylic | O || R-C-O-H | The COOH group is given the number one when naming. Drop the “e” in the name of the R group and add “oic” and the word acid | HCOOH - methanoic acid (formic acid) CH3COOH - ethnic acid (acetic acid) CH3CH2COOH - propanoic acid |
Ester | O || R-C-O-R’ | These names are derived from the name of the acid from which the ester comes from. Drop the “ic” and the ending “ate” is added. The R’ group is named first as a separate word | O || CH3CH2C-OCH2CH3
O || CH3CH2CH2C-OCH2CH3
|
