Physical and chemical changes
Chemical vs physical changes:
| Physical changes | Chemical changes |
|---|---|
| Can be undone easily | Difficult to reverse |
| No new material formed: chemically the same | New materials formed |
| Change in state | Colour change |
| Bubbles formed |
Rate of reaction
The speed at which reactants are converted into product in a chemical reaction.
Generic formula: rate = (change in mass of product/reactant) / time
Factors that increase the rate of reaction:
- Increasing concentration of the reactants
- Increasing the pressure used
- Increasing the temperature used
- Increasing the surface area of the reactants
- Using a catalyst
Catalyst — a substance that increases the rate of reaction while remaining unchanged (not used up) at the end of the reaction.
Collision theory
For a reaction to take place, the particles must:
- Collide with each other
- Collide with enough energy (equal to or more than the activation energy) to be successful
Thus, to increase the chances of successful collisions you can:
- Increase the number of particles colliding (by increasing the concentration of reactants or increasing pressure)
- Increase the kinetic energy of the particles (by increasing the temperature)
- Increase the frequency of collision (by increasing the surface area of the reactants)
- Add a catalyst (which would lower the activation energy required of the particles)
Same as 'factors that increase rate of reaction', but explained by collision theory.
Methods for investigating rate of reaction
- Measuring a change in mass of reactant or product — change in mass recorded on a weighing balance in a given time; divide this change in mass by the time experimented to find the rate.
- Measuring the formation of a produced gas — either use an inverted measuring cylinder via a displacement method, where gas displaces the water when delivered into the cylinder (delivery tube and measuring cylinder needed); or use a gas syringe, where the gas produced is directly delivered into the syringe for recording. Divide the recorded gas volume by the time measured to find the rate.
- Measuring the time taken for reaction completion (often a visible change) — e.g. iodine clock; record the time taken for an image to be obscured, indicating reaction completion.
Reversible reactions and equilibrium
A reversible reaction is represented by the symbol: ⇌
Examples of reversible reactions include hydrated and anhydrous compounds:
- When you add water to anhydrous compounds they become hydrated
- When you heat hydrated compounds they become anhydrous
- Hydrated salt — chemically combined with H2O
- Anhydrous salt — does not contain H2O
| Compound | State | Colour |
|---|---|---|
| Copper(II) sulphate | Anhydrous | White |
| Copper(II) sulphate | Hydrated | Blue |
| Cobalt(II) chloride | Anhydrous | Blue |
| Cobalt(II) chloride | Hydrated | Pink |
Water of crystallisation — the water present in a hydrated compound.
A reaction in equilibrium — when the forward and the backward reaction are equal in rate, the concentration of reactants and products remain constant, and the reaction happens in a closed system.
Equilibrium shifts
How factors affect the yield of forward and backward reactions:
| Change | Effect on equilibrium |
|---|---|
| Increase in temperature | Favours side with endothermic reaction |
| Decrease in temperature | Favours side with exothermic reaction |
| Increase in pressure | Favours side with fewer moles |
| Decrease in pressure | Favours side with more moles |
| Increase in concentration | Favours the production of products |
| Decrease in concentration | Favours the production of reactants |
| Adding a catalyst | Increases rate of reaction but does not affect equilibrium shifts/yield |
Yield and rate of reaction are NOT equivalent.
Processes studied
Haber process
- Creation of ammonia
- Reacting N2 and H2 to produce NH3
- An exothermic process
- Nitrogen from air and hydrogen from methane
N2 + 3H2 ⇌ 2NH3
Conditions:
- 200 atm (20,000 kPa)
- Iron catalyst
- Temperature of 450 degrees celsius
Contact process
- Making of sulfuric acid
- Burn sulphur in air or roast sulphur ore to produce sulphur dioxide
- React sulphur dioxide with oxygen to produce sulphur trioxide (reversible part)
- Sulphur trioxide reacts with sulphuric acid to produce oleum (H2S2O7)
- Oleum reacts with water to produce sulphuric acid
Have to transfer into oleum because directly reacting SO3 with water is highly exothermic and the fumes are toxic.
S + O2 -> SO2
2SO2 + O2 ⇌ 2SO3
SO3 + H2SO4 -> H2S2O7 (oleum)
H2S2O7 + H2O -> 2H2SO4
Conditions:
- Vanadium(V) oxide catalyst
- Temperature of 450 degrees celsius
- 2 atm (200 kPa)
Why aren't lower temperatures used since the reactions are exothermic (exothermic reactions favour lower temperatures)?
- Below 450 degrees celsius, the rate of reaction is too slow
- Above 450 degrees celsius, the yield of the forward reaction decreases
Why aren't higher pressures used (since higher pressure favours the side with fewer moles)?
- Higher pressures are dangerous
- Higher pressures are more expensive to maintain
Redox
A reaction that undergoes both oxidation AND reduction.
What is oxidation and reduction?
| Oxidation | Reduction |
|---|---|
| Loss of hydrogen | Gain of hydrogen |
| Gain of oxygen | Loss of oxygen |
| Loss of electrons (OIL — Oxidation Is Loss of electrons) | Gain of electrons (RIG — Reduction Is Gain of electrons) |
| Increase of oxidation state | Decrease in oxidation state |
Oxidation state rules:
- Elements not combined (alone) have an oxidation state of 0, e.g. H2, Mg
- Oxidation state = charge (it is represented as roman numerals), e.g. cobalt(II) has an oxidation state of +2
- Sum of all oxidation states in a molecule is 0
- In complex ions (e.g. SO4), the sum of oxidation numbers equals the charge
- Oxidising agent — the substance that causes another substance to be oxidised in a reaction. It itself is reduced.
- Reducing agent — the substance that causes another substance to be reduced in a reaction. It itself is oxidised.
Agent tests:
| Substance | Role | Colour change |
|---|---|---|
| Potassium(VII) manganate | Oxidising agent | Purple to colourless when it is reduced |
| Potassium iodide | Reducing agent | Colourless to yellow/brown when it is oxidised |