Calculating Rates of Reactions (AQA GCSE Chemistry)
Revision Note
Calculating rates of reactions
Reactions take place at different rates depending on the chemicals involved and the conditions
Some are extremely slow e.g. rusting and others are extremely fast e.g. explosives
The rate of reaction can be measured in two different ways:
How fast a reactant is used up
How fast a product is made
Three methods used to determine the rate of reaction are:
Mass loss - measuring the mass loss in the reactants over time
Gas collection - measuring the amount of a gas formed over time
Precipitation - measure the formation of a precipitate over time
Depending on the method used, the rate of reaction can be calculated using the appropriate equation:
Rate = 
OR Rate = 
Formula triangle for calculating the rate of reaction
This formula triangle can help with rearranging rate equations for calculations
Measurements for rate
Time is always measured when determining the rate of a chemical reaction
Time is usually in seconds as many reactions studied in the lab are quite quick
The amount of reactant used up or product formed is the other measurement
Several of these measurements are made to ensure that there is sufficient data to establish a conclusion
Measuring the amount of product forming is usually easier than measuring the amount of reactant being used up
The calculation and units for rate depend on the reaction
If mass is being measured in grams, then the units for rate would be g/s
If volume is being measured in cm3 or dm3, then the units for volume would be cm3/s or dm3/s
Mass loss method
When a gas is produced in a reaction it usually escapes from the reaction vessel, so the mass decreases
For example, the reaction of calcium carbonate with hydrochloric acid producing carbon dioxide:
Calcium carbonate + hydrochloric acid → calcium chloride + water + carbon dioxide
The mass is measured every few seconds and the change in mass over time is recorded as the gas escapes
The reaction is typically performed in a conical flask placed on top of a balance to measure the loss in mass
Cotton wool can be placed in the neck of the flask to allow the gas to escape while stopping any materials from being ejected
The set-up for measuring the reaction rate by mass loss
A timer is started when the reactants are combined and the mass is recorded over time
However, one limitation of this method is the gas must be sufficiently dense or the change in mass is too small to measure on a 2 or 3 decimal place balance
So, carbon dioxide would be suitable (Mr = 44) but hydrogen would not (Mr = 2)
Gas collection method
When a gas is produced in a reaction, it can be trapped and its volume measured over time
This method can be used for any reaction that produces a gas but is particularly useful when the gaseous product is hydrogen or another gas with a small relative formula mass, Mr
For example, the reaction of magnesium with hydrochloric acid producing hydrogen:
Magnesium + hydrochloric acid → magnesium chloride + hydrogen
The volume of gas produced over time is recorded
One gas collection set-up involves collecting a gas through water using an inverted measuring cylinder
This technique is called the downward displacement of water
The set-up for measuring the reaction rate by gas collection
The gas displaces the water from the inverted measuring cylinder and the volume of gas produced is recorded over time
Alternatively, the gas could be captured in a gas syringe which measures its volume
Alternative set-up for measuring the reaction rate by gas collection
The gas fills the gas syringe and the volume of gas produced is recorded over time
Precipitation method
Precipitation reactions form a solid precipitate when two clear solutions are mixed together
The precipitate clouds the reaction mixture so if the flask is placed over a piece of paper with a cross on it, the time it takes for the cross to disappear from view (due to the formation of the precipitate) can be measured
For example, the reaction of sodium thiosulfate and hydrochloric acid:
Sodium thiosulfate + hydrochloric acid → sodium chloride + sulfur dioxide + water + sulfur
The time taken for the cross to disappear is measured
The disappearing cross experiment
The chemicals are mixed which forms a a precipitate. The time taken for the precipitate to block the cross from view is recorded
This method is susceptible to error though as they are subjective, given that different people may not agree on the exact moment that the cross disappears
Another disadvantage is that only one data point is produced per experiment, so a rate of reaction graph cannot be plotted
You've read 0 of your 5 free revision notes this week
Sign up now. It’s free!
Did this page help you?