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Controlling chemical reactions - OCR GatewayPractical activity - colour change

The greater the frequency of successful collisions between reactant particles, the greater the reaction rate. Temperature, concentration, pressure and the use of catalysts affect reaction rate.

Part of Chemistry (Single Science)Monitoring and controlling chemical reactions

Practical activity - colour change

Measuring rates of reaction by colour change

It is important in this practical to use the appropriate apparatus to make and record a range of measurements accurately, including time, temperature and volume. This practical includes the safe use of apparatus and monitoring chemical changes.

This outlines one way to carry out the practical. Eye protection must be worn.

Aims

To investigate the effect of changing the temperature on the rate of a reaction.

Sodium thiosulfate solution reacts with dilute hydrochloric acid:

sodium thiosulfate + hydrochloric acid 鈫 sodium chloride + water + sulfur dioxide + sulfur

Na2S2O3(s) + 2HCl(aq) 鈫 2NaCl(aq) + H2O(l) + SO2(g) + S(s)

The sulfur forms a cloudy yellow-white during the reaction. The time taken for this to achieve a given cloudiness provides a way to measure the reaction time.

Method

The result of adding dilute acid to a transparent sodium thiosulfate solution is a more opaque solution.
  1. Using a measuring cylinder, add 50 cm3 of dilute sodium thiosulfate solution to a conical flask.
  2. Place the conical flask on a piece of paper with a black cross drawn on it.
  3. Using a different measuring cylinder, add 10 cm3 of dilute hydrochloric acid to the conical flask. Immediately swirl the flask to mix its contents, and start a stop clock.
  4. Look down through the reaction mixture. When you can no longer see the cross, record the time on the stop clock.
  5. Measure and record the temperature of the reaction mixture, and clean the apparatus as directed by your teacher.
  6. Repeat steps 1 to 5 with different starting temperatures of sodium thiosulfate solution.
A sealed conical flask connected to a gas syringe. The flask contains a reaction mixture that is giving off bubbles of gas.

Results

Record the results in a table. This table gives some example results.

Temperature of reaction mixture (掳C)Reaction time (s)Reaction rate, 1000/time (/s)
188012.5
295717.5
423231.3
492050.0
Temperature of reaction mixture (掳C)18
Reaction time (s)80
Reaction rate, 1000/time (/s)12.5
Temperature of reaction mixture (掳C)29
Reaction time (s)57
Reaction rate, 1000/time (/s)17.5
Temperature of reaction mixture (掳C)42
Reaction time (s)32
Reaction rate, 1000/time (/s)31.3
Temperature of reaction mixture (掳C)49
Reaction time (s)20
Reaction rate, 1000/time (/s)50.0

Analysis

  1. Calculate 1,000 / time for each temperature. This value is proportional to the rate of reaction.
  2. Plot a graph to show:
    • reaction rate (/s) on the vertical axis
    • temperature (掳C) on the horizontal axis
    • draw a curve of best fit
Graph showing the reaction rate rising sharply with the temperature.
Figure caption,
Reaction rate by temperature

Question

Describe the effect of increasing the temperature of the reaction mixture on the rate of reaction. Use your graph to help you.

Evaluation

Question

Suggest a reason why the same person should look at the black cross each time.

Hazards, risks and precautions

Evaluate the hazards and the precautions needed to reduce the risk of harm. For example:

HazardPossible harmPossible precaution
Hot sodium thiosulfate solutionBurns to the skin.Do not heat above 60掳C.
Sulfur dioxideCan cause irritation to the eyes and lungs, particularly to people with asthma.Make sure the room is well ventilated. Avoid breathing directly over the top of the flask.
HazardHot sodium thiosulfate solution
Possible harmBurns to the skin.
Possible precautionDo not heat above 60掳C.
HazardSulfur dioxide
Possible harmCan cause irritation to the eyes and lungs, particularly to people with asthma.
Possible precautionMake sure the room is well ventilated. Avoid breathing directly over the top of the flask.

Fran Scott demonstrates how to measure the rate of reaction and how to increase it