Topic 16: Kinetics II

Question 1

Define rate of reaction

Answer 1

Change of concentration/amount of reactant or product, per unit of time

Amount of product used / time

Question 2

Define rate equation

Answer 2

Links the rate with concentrations of substances
Rate = K[A]^a[B]^b
K = rate constant
AB = concentration of substances
ab = orders of reaction

Question 3

Define order with respect to a substance in a rate equation

Answer 3

How the concentration of the substance affects the rate
0 order - a change in the conc. has no effect on rate
1 order - change in conc. has a proportional change on rate
2 order - change in conc. has a squared proportional change on rate
—> e.g. if [A] doubles then rate quadruples

Question 4

Define overall order of reaction

Question 5

Define rate constant

Answer 5

K - allows us to equate rate with concentration
only fixed at a particular temperature
If temp changes, K changes
Larger value of K, larger rate of reaction but conc. of substances remain the same

Question 6

Define half-life

Answer 6

The time it takes for half the reactant to be used up

Question 7

Define rate-determining step

Answer 7

The slowest step in a multi-step reaction

Question 8

Define activation energy

Question 9

Define heterogeneous/homogeneous catalyst

Question 10

How can rate be measured by electrical conductivity?

Answer 10

Electrical conductivity - may be a change in the number of ions during reaction

Question 11

How can rate be measured by Mass lost?

Answer 11

Mass lost - place reaction on balance and measure the mass lost (as a gas)

Question 12

How can rate be measured by volume of gas produced?

Answer 12

Volume of gas produced - using a gas syringe measured over certain time period. (if mixed in wrong proportions, too much gas can be produced)

Question 13

How can rate be measured by pH change?

Answer 13

Change in pH - use pH meter to measure pH at regular intervals (acid-base)

Question 14

How can rate be measured by Titration?

Answer 14

Titration - change in concentration, by taking aliquots at certain time intervals.

Question 15

How can rate be measured by Colourimetry?

Answer 15

If there is a colour change, measure absorbance of light —> e.g. propanone + iodine (brown to colourless solution, as products are all colourless)
—> Must plot a calibration curve of absorbance on Y by concentration on X.
—> used to find conc. of Iodine.

Question 16

Why does the reaction need to be stopped in a Titration when measuring rate?

Answer 16

When we take the aliquot, we must stop the original reaction, otherwise it would carry on and the conc. would change as we do the titration

Question 17

What is quenching / how is it done?

Answer 17

Stopping a reaction by adding a chemical quenching agent

Question 18

What is the Initial Rates Method used for?

Answer 18

A way to calculate the rate equation for a reaction

Question 19

How do you do an Initial rates method experiment?

Answer 19

1. Repeat the experiment several times, changing the concentrations of the reactants one at a time
2. Calculate the initial rate for each experiment
3. Record concentrations of each reactant and their initial rate to look at the relationship between them, to calculate the orders.

Question 20

Why is a ‘Clock reaction’ used?

Answer 20

Simplify the initial rate method
It times how long it takes for a reaction to occur

Question 21

What 3 assumptions are made during the clock reaction?

Answer 21

1. Temperature remains constant
2. Concentration of reactants does not significantly change
3. Reaction has not proceeded too far when the end point is seen

Question 22

Explain the Iodine-clock reaction

Answer 22

Small amount of Sodium thiosulfate and starch are added to excess H2O2 and iodide ions in acidic solution (H+ ions)
The sodium thiosulfate reacts instantaneously with any iodine which is formed (from the reaction between H202 + I- —> H20 + I2)
Initially, all the iodine is used up in the reaction between sodium thiosulfate and iodine. BUT once all the sodium thiosulfate is reacted, the Iodine produced stays in solution, causing the starch indicator to suddenly turn blue-black.

Question 23

When is the end-point of the Iodine clock reaction?

Answer 23

When the indicator turns blue-black.

Question 24

What changes the time taken for the end point of the iodine clock reaction?

Answer 24

Varying concentrations of Iodine, or Hydrogen peroxide concentration

Question 25

How is a rate-concentration graph created?

Answer 25

By knowing the rate:
Once the rate is calculated from the gradient at various points on a concentration-time graph

Question 26

How can half-life be calculated?

Answer 26

Concentration-time graph
1. Find the first conc. e.g. 10 and the second concentration e.g. 5
2. Follow the lines across to the curve, and then down to the corresponding times.
3. Calculate the time difference, and this shows the time it takes for half the reactant to be used

Question 27

Explain the half-life on a concentration-time graph for 0 order

Answer 27

The difference between times isn’t the same each time
the rate on a straight line graph is constant, therefore changing conc. doesnt change the rate
HALF-LIFE DECREASES

Question 28

Explain the half-life on a concentration-time graph for 1 order

Answer 28

Half-life is constant
The rate changes in equal amounts

Question 29

Explain the half-life on a concentration-time graph for 2 order

Answer 29

Half-life increases
Rate changes in unequal amounts

Question 30

Reactants that appear in the rate equation….

Answer 30

Reactants that appear in the rate equation will affect the rate of reaction
Therefore these reactants must appear in the rate determining step

Question 31

Substances not in the rate equation…

Answer 31

Wont be in the rate determining step

Question 32

Where can we find the rate-determining step?

Answer 32

From the rate equation

Question 33

How can you find the reaction mechanism?

Answer 33

From the rate determining step.

Question 34

Which mechanism do halogenoalkanes react by?

Answer 34

Nucleophilic substitution

Question 35

What is a nucleophile?

Answer 35

An electron pair donor

Question 36

What property of the haloalkane allows it to be attacked by a nucleophile?

Answer 36

The C - Br (or any halogen) bond is polar.
This is because Br is more electronegative than C, so pulls the bonding pair of electrons towards itself.
This results in a more + C and more - Br

Question 37

What conditions are required for the reaction of haloalkanes and hydroxide ions?

Answer 37

1. Warm NaOH (aq)
2. Reflux - allows this to be heated without losing reactants or products

Question 38

What is the general equation for the overall reaction of the haloalkane and hydroxide ions?

Answer 38

R-X + NaOH —> ROH + NaX

Haloalkane + sodium hydroxide –> alcohol + Sodium compound

Question 39

What does the SN1 reaction tell us?

Answer 39

There is one molecule in the rate-determining step
it is a two step reaction

Question 40

What type of haloalkane reacts via SN1?

Answer 40

secondary and tertiary

Question 41

What does the SN2 reaction tell us?

Answer 41

There are two molecules in the rate-determining step
It is a one-step reaction (with an intermediate/transition stage)

Question 42

What type of haloalkane reacts via SN2?

Answer 42

primary and secondary

Question 43

What does the Arrhenius equation link?

Answer 43

Activation energy and temperature to the rate constant

Question 44

What is the relationship between activation energy and the rate constant?

Answer 44

as the activation energy decreases, the rate constant increases

Question 45

Explain the relationship between activation energy and rate constant

Answer 45

As the activation energy decreases, more particles have enough energy to react and collide, therefore the rate of reaction increases

Question 46

What is the relationship between temperature and the rate constant?

Answer 46

As the temperature increases, the rate constant increases

Question 47

Explain the relationship between temperature and rate constant

Answer 47

As the temp increases, particles have more kinetic energy and are more likely to collide, therefore rate of reaction increases

Question 48

How do you rearrange the Arrhenius equation to calculate Ea?

Answer 48

Ea = (lnA −lnK) × RT

Question 49

What equation is used to plot a graph of lnK against 1/t?

Answer 49

lnK = lnA - Ea/RT