# Organic Chemistry

Organic compounds > 90% of known chemicals
Carbon makes living systems possible

Carbon forms 4 covalent bonds (4 valence pairs)
Strong bonds with other non-metals
Bonds with itself with single, double or triple
Can form chains or rings

Large number of compounds due to:
- 4 valence pairs
- single / double / triple bonds
- cyclic (ring) structures

## Hydrocarbons

Hydrocarbons - only carbon and hydrogen
If all C-C bonds are single, the hydrocarbon is saturated

Hydrocarbons
- linear (aliphatic)
- - saturated (all single C-C bonds)
- - - alkane ($C_n H_{2n+2}$)
- - unsaturated
- - - alkene ($C_n H_{2n}$)
- - - alkyne ($C_n H_{2n-2}$)
-
- cyclic (ring)
- - saturated
- - - e.g. cyclohexane
- - unsaturated
- - - e.g. benzene

Carbon compounds with 4 branches are tetrahedral

Compounds with $C-H$ are insoluble in water
These compounds are almost non-polar due to similar electronegativities

Only dispersion forces (between electrons on the outside of two molecules) hold each molecule together
Dispersion forces increase with size (chain length), therefore MP and BP of straight molecules increases with length

Branched molecules have lower MP and BP due to lower density (molecules are further apart due to their shape, so dispersion forces are weaker)

Homologous series - formula for molecules (e.g. alkanes, alkenes, alkynes) where each member differs by some increment

Structural isomers - same molecular formula, different configuration (structural formula)

## Alkanes
$$C_n H_{2n+2}$$
- Single bonds between carbon atoms
- ending in *-ane*

methane $CH_4$
ethane $C_2H_6$
propane $C_3H_8$
butane $C_4H_10$
pentane $C_5H_12$
hexane $C_6H_14$
$\dots$

Alkanes burn in oxygen forming $CO_2 + H_2O$ (oxidation / combustion reaction)

Alkanes react with chlorine or fluorine (substitution reaction) - Cl or F replace H. Result is a haloalkane.

## Alkenes

$$C_nH_{2n}$$

- C-C double bond
- ending in *-ene*

methene $CH_2$
ethene $C_2H_4$
propene $C_3H_6$
butene $C_4H_8$
pentene $C_5H_10$
hexene $C_6H_12$
$\dots$

Alkenes burn in oxygen forming $H_2O + CO_2$.

Alkenes react with hydrogen or a halogen (addition reaction) - additive breaks the double bond (catalyst is required).

## Alkynes

$$C_nH_{2n-2}$$

- C-C triple bond
- ending in *-yne*

Alkynes undergo combustion (oxidation) and addition reactions (same as alkenes).

## Rules for naming HCs

1. Find longest chain of C atoms (incl. branches)
2. Start at end nearest a branch or double/triple bond
3. Name carbon atoms from end chosen
4. Branches end with *-yl*
5. When there are $\ge$ 2 branches, number of C atom is indicated before each branch, and names are in alphabetic order.
6. When there are $\ge$ 2 identical branches, *di-*, *tri-*, and *tetra-* are used.

## Combustion
$$C_xH_y+z0_2 \to\ xCO_n+{y \over 2}H_2O$$
**Complete**
$z=x+{y \over 4}, n=2$

**Incomplete**
$z={{2x+y} \over 4}, n=1$
$z={{x+y} \over 4}, n=0$

## Functional groups

Atom(s), or a bond, which give a properties to an organic molecule.

### Alcohols / hydroxyls

- ---OH functional group
- ends in *-ol*
- alcohols have multiple isomers
- combustible with oxygen
- BP and MP are affected by H-bonding
- **H-bonds are represented by dotted lines**

### Carboxylic acids / carboxys

- ---COOH functional group
- ends in *-oic acid*
- first portion of name (e.g. **methan**oic acid) refers to **total** number of carbons
- weak acids (proton from O is donated)
- high BP

### Esters
- carboxylic acid reacts with alcohols to form esters (condensation / esterification)
- catalyst is $H_2SO_4$
- low boiling points
- intermolecular bonding is dipole-dipole and dispersion rather than H-bonding
- ends in *-oate*