# Electrochemistry

## Oxidation states

Indicates charge (ionisation) of an element

**Oxidation** - loss of e- (at anode)  
**Reduction** - gain of e- (at cathode)

Main group elements (i.e. group 2) - generally one oxidation state:

| elements      | valence config | oxidation state |
| ------------- | -------------- | --------------- |
| alkali metals | $s^1$          | +1              |
| alkali earths | $s^2$          | +2              |
| aluminium     | $s^2 p^1$      | +2              |
| nitrogen      | $s^2 p^3$      | -3              |
| oxygen        | $s^2 p^4$      | -2              |
| halogens      | $s^2 p^5$      | -1              |
| noble gases   | $s^2,\>s^2p^5$ | n/a             |

Transition metals (d shell) may have several oxidation states.

Common oxidation numbers:

| elements          | common ox. state | exceptions          |
| ----------------- | ---------------- | ------------------- |
| main group metals | valency          |                     |
| hydrogen          | +1               | metal hydrides (-1) |
| oxygen            | -2               | ce{H2O2} (-1)       |
| halogens          | -1               |                     |


### Rules for oxidation states

- oxidation states >3 may only exist in compounds
- oxidation number of free element is 0
- oxidation number of simple ion is the charge of the ion
- sum of oxidation numbers in polyatomic ion is the charge of the ion
- sum of oxidation numbers of a neutral compound is zero

## Electrochemical series

- Top is most likely to be reduced
- Strongest reductants are bottom right
- Strongest oxidants are top left
- Strong oxidants have weak conjugate reductants
- $E^0$ values are measured relative to ce{H2} / ce{H^+} = 0V

## Conjugate redox pairs

Oxidant and conjugate *reduced form*  
e.g. ce{Cu^2+} / ce{Cu}, $\quad$ ce{Zn^2+} / ce{Zn}

Usually one member of pair is used as electrode (except for *inert electrodes*, e.g. platinum)

## Electrochemical/galvanic cells

Spontaneous reaction

1. Find two half reactions involved (between electrode and solution)
2. Higher equation will proceed left to right
3. Lower equation will proceed right to left

emf for each cell is calculated as $E^0(\text{red}) - E^0(\text{ox})$

For a *spontaneous* (primary/fuel cell) reaction to occur, species on left must be in electrical contact with species on lower right

### Primary cells

Used for low-current electronic devices. Fixed quantity of reactants.

- **Zinc-carbon dry cell** - carbon rod cathode and zinc anode (case) in ammonium chloride/zinc chloride electrolyte
- **Alkaline cell** - steel cathode (case) and steel/brass rod anode in potassium hydroxide electrolyte
- **Silver-zinc cell** - zinc anode, graphite/silver-oxide electrolyte, potassium hydroxide electrolyte
- **Lithium cell** - magnesium oxide anode, nickel/steel cathode (case), lithium, electrolyte. Lithium is low on electrochemical series enables higher voltage

### Fuel cells

Used for vehicles/long-lasting applications. ce{H2} may be replenished. 

- **Alkaline fuel cell** - ce{KOH(aq)} electrolyte, ce{H2(g)} from tank, ce{O2(g)} from atmosphere, water out of hydrogen side
- **Acid fuel cell** - ce{H3PO4} electrolyte, water out of oxygen side

## Electrolysis reactions

- Occurs when electricity passes through ionic compound or electrolyte solution
- Opposite of reactions in electrochemical (galvanic) cells
- Non-spontaneous
- Electrical energy $\rightarrow$ chemical energy
- Anode +ve; cathode -ve
- Cathode & anode swap relative to galvanic cell
- Molten e.g. ce{Na+(l)} vs electrolyte e.g. ce{Na+(aq)}
- Molten - use echem series to determine probability of electrolyssis of solution or water
- Min voltage = e_oxidising - e_reducing

### Factors affecting electrolysis

- concentration of electrolyte
- - e- values must be "close" for electrolysis rxn to prevail over \ce{H2O}
- nature of electrodes

### Electroplating

- For each ion going into plated object, an ion is replaced from the anode (+ve)
- Electrolyte balances charges

### Coulomb's law

$$Q=It$$

### Faraday's first law

$$m \propto Q$$

i.e. mass produced at cathode is proportional to charge supplied

*Faraday* - charge on 1 mol of electrons = 96500 C.

### Faraday's second law

> To produce one mole of substance by electrolysis, a whole number of mole of electrons is needed