The big idea: Cell respiration releases energy from glucose. In aerobic respiration it uses up oxygen and releases carbon dioxide.
The respiration rate is simply how fast this happens — for example how much oxygen is used (or carbon dioxide is made) per minute.
Because we can't see respiration directly, we measure it indirectly by tracking one of the things that changes: the gases, the temperature, or the mass of the organism.
- Respiration rate
- How quickly an organism respires — usually measured as the volume of oxygen used, or carbon dioxide produced, in a given time (e.g. per minute).
- Respirometer
- A piece of apparatus that measures respiration rate by detecting the change in gas volume (usually the oxygen used up) as organisms respire.
- Indicator (variable)
- A measurable quantity that changes as respiration happens — oxygen used, carbon dioxide produced, temperature rise or mass lost — that lets us estimate the rate.
- Control (dead organisms)
- An identical set-up using non-respiring (dead or boiled) organisms, used to show that any change measured is caused by living respiration and not by something else.
Why we measure indirectly: You can't watch a cell respire. But every time it respires it takes in oxygen, gives out carbon dioxide, warms up slightly and loses a little mass (as carbon leaves in CO₂).
Each of these is something we can measure — so measuring any one of them tells us the respiration rate.
The classic way to measure respiration rate is a respirometer. A common school version uses germinating seeds (or small invertebrates) sealed in a tube, connected to a thin tube containing a drop of coloured liquid.
As the seeds respire, they use up oxygen from the sealed air. This lowers the gas volume, so the coloured liquid moves towards the seeds. How far it moves in a set time measures the oxygen used — the respiration rate.
The role of potassium hydroxide (KOH): There's a problem: respiration uses oxygen but also releases carbon dioxide. If both gases changed, the volume might barely move and you couldn't tell what was happening.
So a small amount of potassium hydroxide (KOH) is added. KOH absorbs all the carbon dioxide the seeds release.
Now the only gas change left is the oxygen being used up — so the coloured liquid moves in cleanly, and its movement measures exactly that.
Why you need a dead-seed control: The coloured liquid could also move if the temperature or air pressure in the room changed — nothing to do with respiration.
To rule this out, an identical tube is set up with dead (boiled) seeds, which do not respire.
If the liquid in the control tube stays still, you know any movement in the live tube is caused by respiration, not by the surroundings. This makes the experiment a fair test.
| Part of the set-up | Its job | What the data tells you |
|---|---|---|
| Germinating seeds (or small animals) | The living, respiring organisms | They use up oxygen, so the coloured liquid moves towards them |
| Potassium hydroxide (KOH) | Absorbs all the carbon dioxide released | Removes CO₂ so the ONLY gas change left is the oxygen used up |
| Coloured liquid in the tube | Shows the change in gas volume | Its movement measures how much oxygen was taken in over time |
| Dead (or boiled) seeds — the control | Identical set-up but not respiring | The liquid should NOT move; proves the movement is caused by living respiration, not temperature or pressure |
Germinating (live) seeds
- Respire — use up oxygen
- KOH absorbs the CO₂ they release
- Coloured liquid moves towards them
- Distance moved = respiration rate
Dead (boiled) seeds — control
- Do not respire
- No oxygen used, no CO₂ made
- Coloured liquid should not move
- Proves movement is caused by respiration
A memory hook: KOH = 'Kills Off the H' — think of it as removing the unwanted gas (CO₂) so the only thing the respirometer 'sees' is oxygen disappearing.
Liquid moves towards the seeds because oxygen is being used up (volume shrinks).
A respirometer tracks the gases of respiration: in aerobic organisms it uses up oxygen and releases carbon dioxide. Measuring how fast either gas changes tells you the respiration rate.
Interactive diagram
Explore the labelled diagram, charts and maps for this topic in full study mode.
Feeling unprepared for exams?
Get a clear study plan, practice with real questions, and know exactly where you stand before exam day. No more guessing.
Get Exam Ready Free7-day free trial • No card required
How this is tested: Respirometers are a Paper 1B / Paper 2 data favourite. A 1-mark question often shows a respirometer with germinating versus dead seeds and KOH and asks you to interpret what the moving coloured liquid demonstrates — that living seeds use up oxygen as they respire.
A Suggest question may ask how a graph shows an inhibitor (such as cyanide) slowing respiration — the liquid moves less, so less oxygen is used.
Another Suggest format asks you to propose another quantity that could measure respiration rate — carbon dioxide produced, temperature rise or mass lost are all valid.
IB-style question — interpret the respirometer
In a respirometer, germinating seeds with potassium hydroxide cause a drop of coloured liquid to move towards them, while an identical tube of dead seeds shows no movement. Explain what these results demonstrate. [3]
How to score all three marks
- Say what the moving liquid means. The living seeds are using up oxygen as they respire, lowering the gas volume, so the coloured liquid is drawn towards them.
- Explain the role of KOH. The potassium hydroxide absorbs the carbon dioxide released, so the only gas change left is the oxygen being used — this is what the liquid's movement measures.
- Explain the dead-seed control. The dead seeds do not respire, so the liquid does not move; this shows the movement in the live tube is caused by respiration, not by temperature or pressure. (Mark 1: oxygen used / liquid drawn in. Mark 2: KOH absorbs CO₂. Mark 3: control shows movement is due to respiration.)
Final answer
The germinating seeds use up oxygen, so the liquid moves towards them; KOH absorbs the CO₂ so only the oxygen change is measured; the unmoving dead-seed control proves the movement is caused by living respiration.
✓ Why this scores full marks: It links each observation to a reason: oxygen used → liquid moves; KOH → only oxygen is measured; dead control → movement must be respiration.
A common slip is to say the liquid moves 'because of carbon dioxide' — but KOH removes the CO₂, so it is the oxygen being used that moves the liquid.
| What you measure | What happens during respiration | How you detect it |
|---|---|---|
| Oxygen used up | Aerobic respiration consumes oxygen from the air | Gas volume falls, so coloured liquid in a respirometer moves towards the organism |
| Carbon dioxide produced | Respiration releases carbon dioxide | Detect with an indicator (e.g. hydrogencarbonate indicator turning yellow), or measure the gas given off |
| Temperature rise | Respiration releases some energy as heat | A thermometer or data-logger in an insulated flask shows the temperature climbing |
| Mass lost | Carbon leaves as carbon dioxide gas over time | Weigh the organisms (e.g. germinating seeds) before and after — dry mass falls |