📖 Lesson 14 ⏱ ~30 min Year 10 · Unit 2 ⚡ +115 XP

Analysing Reaction Rate Data

In 2022, three CSIRO researchers timing the same HCl-marble reaction got 42 s, 44 s, and 61 s, spotting that outlier prevented a flawed conclusion about reaction rate.

Today's hook: In 2022, a Year 10 science class at a CSIRO Education Open Day timed the same HCl-marble chip reaction three times and recorded 42 s, 44 s, and 61 s. The third result was caused by a chip left over from a previous run contaminating the solution, averaging all three would have given a rate 20% slower than the real value. Spotting the difference between random scatter and a genuine outlier is one of the most important skills in real science. How would you decide whether 61 s belongs in your dataset or not?

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Warm-up

Think First

+5 XP each

Q1 · If you measured how long a reaction took and got three results, 42 s, 44 s, and 61 s, what would you do with those numbers and why?

Q2 · What makes a graph more useful than a table of numbers when communicating scientific results?

Learning objectives

What you'll master

3 areas

● Know

How to read and interpret graphs of reaction rate data
How to calculate a mean average from repeated measurements
The difference between independent, dependent and controlled variables

● Understand

Why repeating measurements improves reliability
How to identify anomalous results and decide whether to exclude them
What makes an experiment a fair test

● Can do

Draw conclusions from reaction rate graphs and tables
Evaluate experimental design and suggest improvements
Process data by calculating averages and identifying anomalies

Vocabulary · tap to flip

Words You Need

6 terms

Core term Concept Skill Reference

Independent variable

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Independent variable

The factor that is deliberately changed by the investigator in an experiment.

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Dependent variable

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Dependent variable

The factor that is measured or observed to see how it responds to changes in the independent variable.

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Controlled variable

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Controlled variable

A factor that is kept constant so that it does not affect the outcome of the experiment.

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Fair test

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Fair test

An investigation in which only the independent variable is changed and all other variables are kept constant.

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Anomaly

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Anomaly

A measurement that does not fit the pattern of the other data, often due to experimental error.

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Reliability

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Reliability

The degree to which an investigation can be repeated to produce consistent results.

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Cross-lesson links: The data analysis skills you practise here, reading graphs, spotting outliers, and calculating means, are the same skills needed to interpret the rate-vs-time graphs used throughout Lessons 11–13. These investigation skills also connect to Lessons 18 and 19, where you design experiments and evaluate evidence more formally.

Core learning

Stop & Check, Reading Graphs

Quick Check

+5 XP

Plot the volume of CO2 gas collected every 30 seconds as marble chips react with hydrochloric acid and you get a curve that rises steeply at first, then levels off completely, the graph is showing you the reaction slowing down in real time as reactants are used up. Graphical analysis of reaction data reveals how rate changes over time and allows comparison of different conditions.

Concentration-time graphs: Plot reactant concentration (or product amount) on the y-axis against time on the x-axis. The slope at any point equals the instantaneous rate at that time. Steep slopes mean fast rates; shallow slopes mean slow rates. A horizontal line means zero rate.

Initial rate: Draw a tangent to the curve at t=0. The gradient of this tangent is the initial rate. Initial rate is useful because it reflects the starting conditions before significant reactant depletion.

Comparing curves: When investigating how a factor affects rate, plot multiple curves on the same axes. The curve that rises fastest has the highest rate. If the final plateau is lower, the factor may have affected yield as well as rate.

Example

When investigating how temperature affects the reaction between sodium thiosulfate and hydrochloric acid, students measure the time for a cross to disappear as sulfur precipitate forms. At 20C, the cross disappears in 120 seconds. At 30C, it disappears in 60 seconds. At 40C, it disappears in 30 seconds. Plotting 1/time (proportional to rate) against temperature gives an exponential curve. The graph clearly shows that rate doubles for each 10C increase, confirming the rule of thumb and validating collision theory predictions.

Real-world anchor

Australian chemical kinetics: The Bragg Institute at ANSTO uses neutron scattering to measure reaction rates at the molecular level. By observing how molecules move and collide in real time, scientists can validate and refine collision theory models. This research supports the design of better catalysts and industrial processes. Australian researchers have made significant contributions to understanding enzyme kinetics and protein folding dynamics.

Watch out

The rate at any point on a concentration-time graph is the y-value (concentration) at that point. This is false. The rate is the slope (gradient) of the curve, not the height. A high concentration with a flat curve means zero rate - the reaction has stopped even though plenty of reactant remains (perhaps due to equilibrium or catalyst deactivation). Conversely, a low concentration with a steep curve means a fast rate. Rate is about change, not absolute value.

Spot the slip-up+5 XP

Find the error in this student analysis of a rate graph.

A student claims the reaction rate is zero at t=60s because the curve is flat there.

The curve is flat at t=60s, meaning concentration is not changing.
If concentration is not changing, the rate must be zero.
Wait - the curve might still have a slope if you zoom in.
Actually, a flat curve means the reaction has finished, so rate is indeed zero.

Designing valid and reliable investigations

Fair Testing and Variables

+5 XP

For quantitative analysis, chemists use rate equations that relate reaction rate to reactant concentrations:

Rate = k[A]^m[B]^n

Where k is the rate constant, [A] and [B] are concentrations, and m and n are the orders with respect to each reactant. The overall order is m + n.

Zero order (m=0): Rate is independent of concentration. The concentration-time graph is a straight line with constant slope.

First order (m=1): Rate is directly proportional to concentration. The concentration-time graph is exponential decay. The half-life is constant.

Second order (m=2): Rate is proportional to concentration squared. The half-life increases as concentration decreases.

Orders must be determined experimentally - they cannot be predicted from the balanced equation.

Example

Radioactive decay is a first-order process. The half-life of carbon-14 is 5,730 years. This means that no matter how much C-14 you start with, half of it will decay in 5,730 years, then half of the remainder in the next 5,730 years, and so on. This constant half-life is the basis of radiocarbon dating. Archaeologists measure the remaining C-14 in organic samples and calculate age using the first-order decay equation. The technique was developed by Willard Libby in 1949 and revolutionised archaeology.

Real-world anchor

Australian radiocarbon dating: The Australian Nuclear Science and Technology Organisation (ANSTO) operates radiocarbon dating facilities that support Australian archaeology and climate science. Scientists date Aboriginal artefacts, megafauna bones, and sediment cores to understand human arrival in Australia (estimated at 65,000 years ago) and extinction of giant marsupials. Accurate dating depends on understanding first-order kinetics and carefully calibrating for variations in atmospheric C-14 levels over time.

Watch out

The rate constant k changes when you change concentration. This is false. The rate constant is constant at a given temperature. Changing concentration changes the rate (because rate = k[concentration]^n), but k itself stays the same. Only temperature changes affect k, because k depends on activation energy and temperature through the Arrhenius equation. This is why k is called a constant - it is independent of concentration but dependent on temperature.

On a concentration-time graph, how do you determine the rate at t=20s?

Stop & Check, Averages and Anomalies

Quick Check

+5 XP

Reliable rate data requires careful experimental design and honest analysis.

Systematic errors: Consistent biases that affect all measurements in the same direction. Examples: a stopwatch that runs slow, a thermometer that reads 2C high, or a concentration that was prepared incorrectly. Systematic errors cannot be reduced by repeating measurements.

Random errors: Unpredictable variations that scatter measurements around the true value. Examples: slight variations in timing, temperature fluctuations, or reading a scale at slightly different angles. Random errors can be reduced by taking more repeats and calculating a mean.

Anomalies: Individual results that deviate significantly from the pattern. Never simply delete anomalies - investigate possible causes. Was there a power failure? Did you misread a measurement? Good scientists report anomalies and explain why they were or were not included in analysis.

Example

In a rate experiment using magnesium and acid, a student obtains reaction times of 32s, 34s, 33s, and 58s. The first three agree well, but the fourth is anomalous. Investigation reveals that the fourth run used a different piece of magnesium that had a visible oxide coating. The oxide reacted first with acid (MgO + 2HCl -> MgCl2 + H2O), consuming acid before the magnesium proper could react. Once the cause is identified, the anomalous result is explained and can legitimately be excluded from the mean, with the reason documented.

Real-world anchor

Australian measurement standards: The National Measurement Institute (NMI) maintains Australia primary standards for time, mass, temperature, and other quantities. Their laboratories in Sydney ensure that instruments used in research and industry are traceable to international standards. When Australian chemical companies measure reaction rates for process control, their instruments are calibrated against NMI standards, ensuring consistency and comparability of data across the country.

Watch out

Taking more repeats always improves accuracy. This is false. Repeats reduce the effect of random errors and improve precision, but they do not eliminate systematic errors. If your thermometer reads 5C high, taking 100 measurements will give you a very precise but inaccurate average. To improve accuracy, you must identify and correct systematic errors through calibration, control experiments, or independent verification.

Predict then reveal+8 XP

1 · Predict

2 · Reveal

3 · Compare

A student repeats a reaction rate experiment three times and gets times of 45s, 48s, and 72s. What should they do with the 72s result?

Confidence 50%

Heads-up · common traps

Spot the Trap

3 myths

✗

Wrong: "An average means you can just guess the middle number." No � the mean average is calculated precisely by adding all values and dividing by the count. Guessing introduces error.

✓

Right: The mean is calculated by adding all valid values and dividing by the number of values, it is a precise calculation, not an estimate. Guessing a middle number introduces error and undermines the reliability of your data.

✗

Wrong: "If a result does not fit my hypothesis, I should leave it out." No � you should only exclude anomalous results if you can identify a specific error. Excluding valid data is unscientific.

✓

Right: You should only exclude a data point if you can identify a specific cause for the error, equipment failure, a spill, a recording mistake. An anomalous result that cannot be explained should be reported and discussed, not silently removed.

✗

Wrong: "Doing an experiment once is enough if you are careful." No � even careful scientists get random errors. Repeating measurements is essential for reliability.

✓

Right: Careful technique reduces systematic error but cannot eliminate random error. Repeating measurements and calculating a mean reduces the influence of random variation, which is why replication is a core requirement of reliable scientific work.

Australian Context

CSIRO and Reaction Rate Research

Australia's national science agency, CSIRO, conducts research into reaction rates across many fields. In mineral processing, CSIRO scientists study how to speed up the leaching reactions that extract gold and copper from ore, making Australian mining more efficient and reducing environmental impact.

CSIRO also researches reaction rates in agriculture, such as how quickly fertilisers break down in different Australian soils. Understanding these rates helps farmers apply the right amount at the right time, reducing runoff into the Great Barrier Reef catchment.

From the lesson

Copy Into Books

✍ Copy Into Your Books

▾

Reading Rate Graphs

Steeper slope = faster reaction
Flat line = reaction finished
Same final height = same total product

Fair Test Checklist

Only change the independent variable
Keep all controlled variables constant
Repeat and calculate a mean

Anomalies

Identify results far from the pattern
Check for human or equipment error
Exclude only with a stated reason

From the lesson

Activity 1

Evaluate the Experiment

Read each scenario and identify what went wrong and how to fix it.

1 A student tests how surface area affects reaction rate using large marble chips in one test and powdered marble in another, but uses 50 mL of acid for the chips and 30 mL for the powder.

Answer in your book.

2 A student measures the time for antacid tablets to dissolve in water at 20 °C, 40 °C and 60 °C. They do each temperature once. Their 60 °C time is much longer than expected.

Answer in your book.

3 A group measures gas volume every 10 seconds but one student reads the gas syringe from above instead of at eye level.

Answer in your book.

From the lesson

Activity 2

Process the Data

Calculate averages and identify anomalies for each data set.

1 Reaction times (s) at 25 °C: 34, 36, 35, 62, 33. Calculate the mean, identify any anomaly and calculate the corrected mean.

Answer in your book.

2 Gas volumes (mL) after 60 seconds at three acid concentrations: 0.5 mol/L: 24, 26, 25; 1.0 mol/L: 48, 47, 49; 2.0 mol/L: 91, 12, 93. Identify the anomaly and calculate the means.

Answer in your book.

3 A graph shows two curves for the same reaction with and without a catalyst. Both flatten at 120 mL, but the catalysed curve reaches 120 mL in 30 seconds while the uncatalysed curve takes 90 seconds. What conclusion can you draw?

Answer in your book.

Reflect

Revisit your thinking

reflect

At the start of this lesson, the hook gave you three reaction times, 42 s, 44 s, and 61 s, and asked whether you'd average all three or treat one as suspicious. What did you decide then, and why?

Now that you understand random error, outliers, and how scientists identify anomalous results, would you change your answer? What is the difference between a genuine outlier and random variation, and how has your approach to reading data shifted from your first instinct?

Quick check · multiple choice

Quick check

On a reaction rate graph, what does a steep initial slope indicate?

+10 XP

Quick check

In a fair test investigating how temperature affects reaction rate, which variable is the dependent variable?

+10 XP

Quick check

A student gets these times for a reaction: 42 s, 44 s, 43 s and 78 s. What is the best way to process this data?

+10 XP

Quick check

Two curves on the same graph both flatten at 150 mL of gas, but Curve X reaches 150 mL in 40 seconds while Curve Y takes 80 seconds. Which conclusion is valid?

+10 XP

Quick check

A student tests how catalyst concentration affects reaction rate. They use 1 g of manganese dioxide powder in one test and 1 g of manganese dioxide granules in another, keeping everything else the same. What is the main problem with this design?

+10 XP

From the lesson

Additional content

Short answer

Short answer · explain in your own words

Show your reasoning

3 questions

Understand Core 2 marks

Q1. 1. Explain why scientists repeat measurements in experiments and calculate a mean average. In your answer, include what "reliability" means. 4 MARKS

Apply Core 3 marks

Q2. 2. A group of you investigates how concentration affects the rate of reaction between sodium thiosulfate and hydrochloric acid. They time how long it takes for a cross drawn under the flask to disappear. Name the independent, dependent and two controlled variables in this investigation. 4 MARKS

Analyse Core 3 marks

Q3. 3. The table below shows the volume of hydrogen gas produced every 20 seconds when zinc reacts with hydrochloric acid. Describe the trend in the data, explain why the rate changes over time, and calculate the total gas produced after 100 seconds.

From the lesson

Revisit

Revisit Your Thinking

Go back to your Think First answer. Has your understanding changed?

Can you now describe what a fair test requires in more detail?
What new skill did you learn about processing data?

Update your thinking in your book.

Model answers (click to reveal)

Answers

▾

MCQ 1

CA steep slope on a reaction rate graph means the reaction is producing product quickly at the start. A flat line would mean the reaction has stopped.

MCQ 2

BThe dependent variable is what you measure. In this case, the time taken for the reaction to finish is the measured outcome that depends on temperature.

MCQ 3

D78 s is very different from 42–44 s and is likely an anomaly. The best approach is to identify it as an anomaly, check for a cause, and calculate the mean of the remaining reliable values: (42 + 44 + 43) / 3 = 43 s.

MCQ 4

ABoth curves flatten at the same height (150 mL), meaning both reactions produced the same total amount of gas. Curve X reached this value faster, so it had a faster reaction rate.

MCQ 5

CPowder and granules have different surface areas even at the same mass. Changing both the form and amount of catalyst means two variables changed at once, so it is not a fair test.

Short Answer 1

Model answer: Scientists repeat measurements because individual readings can be affected by small random errors, such as reaction time when starting a stopwatch or slight variations in equipment. Repeating and calculating a mean average gives a more representative value that smooths out these random errors. Reliability refers to how consistently an experiment produces the same results when repeated under the same conditions. The more repeats that agree closely, the more reliable the data.

Short Answer 2

Model answer: Independent variable: concentration of hydrochloric acid (or concentration of sodium thiosulfate). Dependent variable: time taken for the cross to disappear. Controlled variables: volume of acid used, volume of sodium thiosulfate used, temperature of the solutions, same size and shape of flask, same cross and viewing distance, same person judging when the cross disappears.

Short Answer 3

Model answer: The trend shows that the volume of gas increases over time but the rate slows down. In the first 20 seconds, 32 mL was produced; in the next 20 seconds, only 24 mL; then 16 mL, then 8 mL, then 4 mL. The rate decreases because the concentration of the acid is dropping as it is used up in the reaction. Fewer acid particles are available to collide with zinc, so successful collisions become less frequent. The total gas produced after 100 seconds is 84 mL.

Quick-fire challenge

Game time

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