Rates of reaction – practical experiments | 16–18 chemistry

Royal Society Of Chemistry

9 Nov 202119:01

Summary

TLDRThis video explains two key methods for measuring reaction rates: the initial rate method and the continuous monitoring method. It demonstrates the iodine clock reaction, where the time for a color change is measured to determine the reaction rate, and the gas production method, where hydrogen gas is measured during a reaction between magnesium and hydrochloric acid. The video emphasizes the importance of careful measurement, safety, and the impact of factors like concentration and temperature on reaction rates. The practical applications of these methods in production chemistry and experimental accuracy are also discussed.

Takeaways

😀 The rate of a chemical reaction is the change in concentration of reactants or products per unit time, and understanding this is crucial for production chemists.
😀 Two primary methods for measuring reaction rates are the initial rate method and the continuous monitoring method.
😀 The initial rate method involves measuring the time for a noticeable event to occur, such as a color change, while keeping the concentration close to the initial value.
😀 The continuous monitoring method provides more data but requires further calculations to determine concentration changes during the reaction.
😀 Examples of continuous monitoring techniques include using colorimetry to measure color changes, pH sensors to track acidity, and temperature sensors for thermal changes.
😀 The iodine clock reaction demonstrates the initial rate method, where hydrogen peroxide reacts with potassium iodide, starch, and sodium thiosulfate to produce a color change from colorless to blue-black.
😀 The reaction between iodine and starch occurs after the thiosulfate ions are consumed, forming a blue-black complex, indicating the end of the reaction.
😀 Accurate measurement techniques, such as using pipettes, burettes, and appropriate cleaning procedures, are essential for ensuring correct concentrations and reliable results.
😀 The concentration of hydrogen peroxide can be calculated using its volume and the balanced chemical equation, noting that hydrogen peroxide concentration is often expressed in volumes (e.g., 5 vol or 20 vol).
😀 In continuous monitoring, experiments like the reaction of magnesium with hydrochloric acid are used to measure the volume of gas produced, and this can be repeated at different temperatures to explore the effect of temperature on reaction rates.
😀 Temperature controls such as thermostatic water baths or Bunsen burners are used to study the effect of temperature on the rate of reaction, with examples at 60°C and 80°C.
😀 Proper disposal of reaction mixtures, especially those containing harmful chemicals like iodine, must be done safely by using a neutralizing solution like sodium carbonate.

Q & A

What is the definition of the rate of reaction?
-The rate of reaction is defined as the change in concentration of reactants or products per unit time.
Why is it important for production chemists to understand the rate of reaction?
-Production chemists must understand the rate of reaction to ensure that when production is scaled up, the rate remains consistent. This helps prevent potential cost, health, and safety issues.
What are the two main methods for measuring reaction rates?
-The two main methods for measuring reaction rates are the initial rate method and the continuous monitoring method.
How does the initial rate method work?
-The initial rate method involves measuring the time it takes for a noticeable event, such as a color change, to occur in the reaction. It assumes the concentration of reactants remains close to its initial value, making calculations easier.
What is a clock reaction, and how does it help measure reaction rates?
-A clock reaction, such as the iodine clock reaction, involves a color change (from colorless to blue-black) as a result of the reaction. The time taken for this color change is used to calculate the rate of reaction.
What is the role of sodium thiosulfate in the iodine clock reaction?
-Sodium thiosulfate reacts with iodine formed during the reaction, converting iodine to tetrathionate ions. This prevents the immediate formation of free iodine, allowing for a delayed color change once all the thiosulfate is consumed.
How is the continuous monitoring method different from the initial rate method?
-The continuous monitoring method tracks reaction progress over time by recording various properties, such as gas volume, color change, or temperature. This provides more data, but additional calculations are required to determine the concentration at different points during the reaction.
What kind of data can be obtained using continuous monitoring?
-Continuous monitoring can provide data on properties such as color change (using colorimetry), pH (using a pH sensor), temperature (using a temperature sensor), or gas volume (measuring the amount of gas produced).
What are the key steps involved in preparing the iodine clock reaction?
-To prepare the iodine clock reaction, you need to add potassium iodide, sodium thiosulfate, and starch to a conical flask, followed by varying concentrations of hydrogen peroxide and sulfuric acid. The reaction is then started, and the time for the color change is measured.
How can temperature affect the rate of reaction, and how is this demonstrated in the script?
-Temperature can increase the rate of reaction by providing the reactants with more energy, leading to more frequent and successful collisions. In the script, this is demonstrated by repeating the magnesium and hydrochloric acid reaction at different temperatures (e.g., 60°C and 80°C) to observe the effect on the rate.