Which of the following does not act as a nucleophile?
☐ | A | HBr | |
☐ | B | H2O | |
☐ | C | NH3 | |
☐ | D | CN– |
Did this page help you?
Which of the following does not act as a nucleophile?
☐ | A | HBr | |
☐ | B | H2O | |
☐ | C | NH3 | |
☐ | D | CN– |
How did you do?
Did this page help you?
This question concerns halogenoalkanes.
1-chloropropane can react to form organic products as shown in the reaction scheme:
How did you do?
The bromoalkanes, X, Y and Z, were each added to a mixture of aqueous silver nitrate and ethanol at 50°C. The rate of hydrolysis was compared by measuring the time for a precipitate to appear.
The relative rates of hydrolysis are in the order (fastest first)
☐ | A | X, Y, Z | |
☐ | B | Z, X, Y | |
☐ | C | Z, Y, X | |
☐ | D | X, Z, Y |
How did you do?
Did this page help you?
This question is about halogenoalkanes.
2‐chloro‐2‐methylpropane can be hydrolysed by water.
The equation for this reaction is
(CH3)3CCl + H2O → (CH3)3COH + H++ Cl−
The graph shows how the concentration of 2‐chloro‐2‐methylpropane changes with time during an investigation of this reaction.
Calculate the rate of reaction at 50s. Show your working on the graph.
Include units with your final answer.
Rate of reaction at 50s = ............................
How did you do?
What is the classification of the mechanism for the hydrolysis of 2‐chloro‐2‐methylpropane by water?
☐ | A | addition | |
☐ | B | elimination | |
☐ | C | free radical substitution | |
☐ | D | nucleophilic substitution |
How did you do?
The letters X, Y and Z refer to three different halogenoalkanes:
X | 1‐bromobutane |
Y | 2‐bromobutane |
Z | 2‐bromo‐2‐methylpropane |
1 cm3 of each of these halogenoalkanes was added to separate test tubes containing 5 cm3 of ethanol and 5 cm3 of aqueous silver nitrate solution in a water bath at 50 °C.
☐ | A | X, Z, Y | |
☐ | B | Z, X, Y | |
☐ | C | Z, Y, X | |
☐ | D | X, Y, Z |
How did you do?
Under different conditions, 2‐chloro‐2‐methylpropane can react to produce 2‐methylpropene,
(2)
(2)
(4)
How did you do?
Did this page help you?
This is a question about the hydrolysis of halogenoalkanes.
Devise an experiment, giving outline details only, that would enable the relative rates of hydrolysis of halogenoalkanes to be compared.
How did you do?
Explain the trend in the rates of hydrolysis of 1-chlorobutane, 1-bromobutane and 1-iodobutane.
How did you do?
The product of the hydrolysis of 2-bromobutane is butan-2-ol. Both molecules are chiral.
State what is meant by the term chiral, using three-dimensional diagrams of the enantiomers of butan-2-ol to illustrate your answer.
How did you do?
Compare and contrast the mechanism of hydrolysis, using aqueous potassium hydroxide, of the primary halogenoalkane, RCH2X, with that of the tertiary halogenoalkane, R3CX.
Include diagrams of any intermediate or transition state.
Curly arrows are not required.
How did you do?
Did this page help you?
Bromobutanes react with hot ethanolic potassium hydroxide solution to produce gaseous butenes.
Procedure
Result
The final volume of but-1-ene collected was 22.0 cm3.
State the purpose of the condenser.
How did you do?
Describe a chemical test on the gas in the syringe to identify its functional group.
Include the expected result.
How did you do?
Calculate the percentage of 1-bromobutane which was converted to but-1-ene.
[Molar volume of a gas at r.t.p. = 24 000 cm3 mol–1]
How did you do?
Before cooling, the volume of but-1-ene in the gas syringe was 24.0 cm3.
Calculate the temperature of the gas in the syringe before it cooled.
[Assume no loss from the gas syringe during cooling, and a constant pressure]
How did you do?
(1)
Chemical test reagent | Observation | |||
☐ | A | sodium carbonate solution | effervescence | |
☐ | B | aqueous silver nitrate | cream precipitate | |
☐ | C | Fehling’s solution | red precipitate | |
☐ | D | phosphorus(V) chloride | steamy fumes |
Draw the mechanism for the reaction of 1-bromobutane with hydroxide ions to form butan-1-ol.
Include curly arrows, and any appropriate lone pairs and dipoles.
(3)
How did you do?
Alkene molecules are formed by elimination from 2-bromobutane.
How many isomeric alkene products will be formed in this reaction?
☐ | A | 1 | |
☐ | B | 2 | |
☐ | C | 3 | |
☐ | D | 4 |
How did you do?
Did this page help you?