Topic 14 - Redox II Flashcards

Question 1

Q

What happens to an element’s oxidation number when it is oxidised?

Answer

A

It increases.

Question 2

Q

Do s-block elements react by gaining or losing electrons?

Answer

A

Losing them

Question 3

Q

Do p-block elements react by gaining or losing electrons?

Answer

A

Metals -> Losing electrons

* Non-metals -> Gaining electrons

Question 4

Q

Do d-block elements react by gaining or losing electrons?

Answer

A

It varies, by but they tend to form positive ions with positive oxidation numbers.

Question 5

Q

Describe the structure of a basic electrochemical cell.

Answer

A

Anode and cathode
Each electrode is dipped in a solution of its own ions
Salt bridge between solutions
External circuit connecting electrodes, with voltmeter

Question 6

Q

In an electrochemical cell, what is the salt bridge made of?

Answer

A

Filter paper soaked in a salt solution

Question 7

Q

What are the two processes in an electrochemical cell?

Answer

A

Oxidation

* Reduction

Question 8

Q

In an electrochemical cell, which electrode does oxidation always happen at?

Answer

A

Anode

Remember: A + O are vowels!

Question 9

Q

In an electrochemical cell, explain which metal becomes the anode and which becomes the cathode? Where do oxidation and reduction occur?

Answer

A

MORE REACTIVE METAL:
• Forms ions more readily, so it loses electrons electrons more easily
• This is oxidation
• So this is the anode (relatively positive)
LESS REACTIVE METAL:
• Forms ions less readily, so it instead accepts electrons and ions from the solution, reforming the metal
• This is reduction
• So this is the cathode (relatively negative)

Question 10

Q

In an electrochemical cell, which electrode does reduction always happen at?

Question 11

Q

Do reactive or unreactive metals form ions more readily?

Question 12

Q

In an electrochemical cell, which direction do electrons flow in?

Answer

A

From the more reactive metal to the less reactive metal.

Question 13

Q

What is the symbol for cell potential?

Question 14

Q

What is cell potential?

Answer

A

The difference between the two half-cells in an electrochemical cell.

Question 15

Q

Do half-cells have to involve a metal and solution of metal ions?

Answer

A

No, they can also involve:
• A solution of two different aqueous ions of the same element (in the same half-cell) with an inert electrode
• Gas with solution of its own ions and an inert electrode

Question 16

Q

Give an example of a half-cell with a solution of two aqueous ions of the same element. Describe the structure.

Answer

A

• Solution of Fe³⁺ and Fe²⁺
• Platinum (or graphite) electrode 
• Oxidation or reduction (depending on whether the half-cell has the anode or cathode) occurs on the electrode surface
Possible reactions:
• Fe²⁺(aq) -> Fe³⁺(aq) + e⁻
• Fe³⁺(aq) + e⁻ -> Fe²⁺(aq)

Question 17

Q

When an inert electrode is required in an electrochemical cell, what elements tend to be used?

Answer

A

Platinum

* Graphite

Question 18

Q

Given that zinc is more reactive than copper, explain what happens in the zinc/copper electrochemical cell. Include half-equations.

Answer

A

Zinc loses electrons more easily, so it is oxidised to the ion, releasing electrons into the circuit
Zn(s) -> Zn²⁺(aq) + 2e⁻
Copper ions in the solution are reduced using electrons from the circuit, to form copper solid
Cu²⁺(aq) + 2e⁻ -> Cu(s)

Question 19

Q

Describe how a half-cell can be set up with a gas.

Answer

A

The gas is bubbles over a platinum/graphite catalyst sitting in a solution of its aqueous ions
Oxidation or reduction occurs on the surface of the electrode

Question 20

Q

When drawing electrochemical cells, which half-cell is on the left?

Answer

A

The one where oxidation occurs (anode).

Question 21

Q

Are the reactions at each electrode reversible?

Answer

A

Yes

* The direction each reaction goes in depends on how easily the metal loses electrons

Question 22

Q

Which way are half-reactions at each electrode in an electrochemical cell written?

Answer

A

The reduction reaction is the forward direction.

e.g. Zn²⁺ + 2e⁻ -> Zn

Question 23

Q

Describe how you can set up an electrochemical cell involving two metals.

Answer

A

1) Get a strip of each of the metals you’re investigating. Clean the surfaces using emery paper (or sandpaper).
2) Clean any grease or oil from the electrodes using some propanone.
3) Place each electrode into a beaker with a solution containing ions of that metal. If any solution contains an oxidising agent that contains oxygen (e.g. MnO₄⁻), add acid too.
4) Create a salt bridge to link the two beaters together. Do this by soaking a piece of filter paper in salt solution.
5) Connect the electrodes to a voltmeter using crocodile clips and wires. There should be a voltmeter reading.

Question 24

Q

What things are used to clean the electrodes when preparing an electrochemical cell?

Answer

A

Emery paper (or sandpaper) -> Cleans surface

* Propanone -> Cleans off any grease or oil

Question 25

Q

What solution could be used in a half-cell of copper metal?

Answer

A

CuSO₄ (for example)

Question 26

Q

What should you do if the solution in a half-cell contains an oxidising agent that contains oxygen (e.g. MnO₄⁻)?

Answer

A

Add acid too

Question 27

Q

Describe what a half-cell electrode potential essentially is.

Answer

A

How easily the substance in the half-cell is oxidised (i.e. loses electrons).

Question 28

Q

Why does a potential difference build up in a half-cell?

Answer

A

There is a difference between the charge of the electrode and the ions in the solution.

Question 29

Q

When there are two half-cell potentials, how can you tell which reaction goes forwards and which goes backwards?

Answer

A

The half-reaction with the MORE positive electrode potential goes forward.
The half-reaction with the MORE negative electrode potential goes backwards.

Question 30

Q

Zn²⁺ + 2e⁻ -> Zn (-0.76V)
Cu²⁺ + 2e⁻ -> Cu (+0.34V)

Which reaction goes forwards and which goes backwards?

Write the ionic equation for the reaction.

Answer

A

The zinc reaction is more negative -> It goes backwards
The copper reaction is more positive -> It goes forwards

Cu²⁺(aq) + Zn(s) -> Cu(s) + Zn²⁺(aq)

Question 31

Q

What does the little ° next to the E show?

Answer

A

It is the STANDARD electrode potential.

Question 32

Q

Zn²⁺ + 2e⁻ -> Zn (-0.76V)
Cu²⁺ + 2e⁻ -> Cu (+0.34V)

Which is oxidised and which is reduced?

Answer

A

Oxidised -> Zinc

* Reduced -> Copper

Question 33

Q

What is the symbol for standard electrode potential?

Question 34

Q

Define standard electrode potential.

Answer

A

The voltage measured under standard conditions when the half-cell is connected to a standard hydrogen electrode.

Question 35

Q

What are the standard conditions for a standard electrode potential?

Answer

A

Solutions of the ions you’re interested in must have a concentration of 1.0 mol/dm³
298K
100kPa

Question 36

Q

Describe the structure of a standard hydrogen half-cell.

Answer

A

Hydrogen is pumped into an upturned vessel in a 1.00 mol/dm³ H⁺ solution
Platinum electrode is in the upturned vessel
At 298K and 100kPa

Question 37

Q

When measuring standard electrode potential, what is the equation at the hydrogen electrode?

Answer

A

2H⁺(aq) + 2e⁻ -> H₂(g)
OR
H₂(g) -> 2H⁺(aq) + 2e⁻

Question 38

Q

In a setup to calculate the standard electrode potential for a half-cell, is the hydrogen half-cell where oxidation or reduction happens?

Answer

A

It can be either.

Question 39

Q

When drawing out the setup to calculate the standard electrode potential for a half-cell, where is the hydrogen half-cell drawn?

Answer

A

On the left (regardless of whether it is reduced or oxidised).

Question 40

Q

Describe how a standard hydrogen half-cell can be used to work out the half-cell electrode potential of an different half-cell.

Answer

A

Other half-cell is connected on the right of the hydrogen half-cell in order to make a full cell
The voltage reading is the half-cell potential of the other half-cell

Question 41

Q

What is the electrode potential of a standard hydrogen electrode?

Question 42

Q

What is the equation for the cell potential of an electrochemical cell?

Answer

A

E°(cell) = E°(red) - E°(oxid)

Question 43

Q

What can be said about the value of E°(cell) for a working electrochemical cell and why?

Answer

A

It is always positive

* Because the more negative E° value is being subtracted from the more positive E° value

Question 44

Q

Calculate the cell potential of a magnesium-bromine electrochemical cell:
Br₂ + Mg -> Mg²⁺ + 2Br⁻

Mg²⁺(aq) + 2e⁻ -> Mg(s) E° = -2.37V
1/2Br₂(aq) + e⁻ -> Br⁻(aq) E° = +1.09V

Answer

A

E°(cell) = E°(red) - E°(oxid)

* E°(cell) = +1.09 - (-2.37) = +3.46V

Question 45

Q

When doing E°(cell) calculations, do you have to account for the number of electrons transferred at each electrode?

Answer

A

No, just use the E° values.

Question 46

Q

Why are electrode potentials quoted under standard conditions?

Answer

A

The temperature, pressure and concentration may affect the equilibrium position, which affects the cell potential.

Question 47

Q

What is the name for the shorthand method of drawing electrochemical cells?

Answer

A

Conventional representation

Question 48

Q

What are the rules for drawing an electrochemical cell in shorthand?

Answer

A

Half-cell with more negative potential goes on the left:
• Far left -> Reduced form (usually the uncharged metal)
• Dashed line
• Middle left -> Oxidised form (usually the charged ion)
Double vertical dashed lines show the salt bridge linking to the half-cell with the more positive potential:
• Middle right -> Oxidised form (usually the charged ion)
• Dashed line
• Far right -> Reduced form (usually the uncharged metal)

Commas separate species that are in the same half-cell and the same physical state
If there is a standard hydrogen half-cell, it should be on the left
Show inert electrodes on the outside of the diagram (separated by a dashed line)

Question 49

Q

What do the double vertical dashed lines show on an electrochemical cell shorthand diagram?

Answer

A

Salt bridge

Question 50

Q

What do the single vertical dashed lines show on an electrochemical cell shorthand diagram?

Answer

A

The show the boundary between species in different physical states.

Question 51

Q

How are species in the same half-cell and in the same physical state separated in an electrochemical cell shorthand diagram?

Question 52

Q

How are inert electrodes shown on an electrochemical cell shorthand diagram?

Answer

A

They are on the outside of the diagram, separated by a vertical dashed line.

Question 53

Q

Draw the conventional representation of the electrochemical cell formed between magnesium and the standard hydrogen half-cell.

Answer

A

Pt | H₂(g) | 2H⁺(aq) || Mg²⁺(aq) | Mg(s)

Question 54

Q

With a half-cell on the left of a standard electrochemical diagram, what can be assumed?

Answer

A

It is the anode
So oxidation happens there -> Electrons are lost
So the half-cell electrode potential must be more negative (than the other half-cell), since the half-cell equations are written with reduction in the forward direction

Anode, Oxidation, Negative E°

Question 55

Q

How does a metal’s reactivity affect how easily it forms ions?

Answer

A

The most reactive it is, the more easily it loses electrons to form a positive ion.

Question 56

Q

How does a non-metal’s reactivity affect how easily it gains electrons?

Answer

A

The more reactive it is, the more easily it gains electrons to form a negative ion.

Question 57

Q

What is an electrochemical series show?

Answer

A

How reactive metals and non-metals are based on their standard electrode potentials.

Question 58

Q

Describe how you can tell how reactive an element is from it’s standard electrode potential.

Answer

A

See if it is a metal or non-metal
If it is a metal -> The more negative the standard electrode potential, the more reactive it is
If it is a non-metal -> The more positive the standard electrode potential, the more reactive it is

Question 59

Q

How can you work out the feasibility of a reaction of a metal with the aqueous ions of another metal using electrode potentials?

Answer

A

1) Write the equation as the half-equations
2) Look at the standard electrode potential of each half-equation (in the normal reduction direction)
3) E°(cell) = E°(red) - E°(oxid)
4) If this gives a positive value, the reaction is feasible

Question 60

Q

When using electrode potentials to work out whether a reaction is feasible, what shows that the reaction is feasible?

Answer

A

E°(cell) is positive (calculated by E°(red) - E°(oxid))

Question 61

Q

Predict whether zinc metal reacts with aqueous copper ions.

Zn²⁺(aq) + 2e⁻ -> Zn(s) E° = -0.76V
Cu²⁺(aq) + 2e⁻ -> Cu(s) E° = +0.34

Answer

A

Zn(s) + Cu²⁺(aq) -> Zn²⁺(aq) + Cu(s)
E°(cell) = E°(red) - E°(oxid) = 0.34 -(-0.76) = +1.10V
This is positive, so the reaction will happen.

Question 62

Q

What is the name for a species being simultaneously oxidised and reduced?

Answer

A

Disproportionation

Question 63

Q

Can electrode potentials be used to predict whether a disproportionation reaction is feasible?

Question 64

Q

Use the following equations to predict whether or not Ag⁺ ions will disproportionate on solution.

Ag⁺(aq) + e⁻ -> Ag(s) E° = +0.80V
Ag²⁺(aq) + e⁻ -> Ag⁺(aq) E° = +2.00V

Answer

A

2Ag⁺(aq) -> Ag(s) + Ag²⁺ (aq)
E°(cell) = E°(red) - E°(oxid) = 0.80 - (2.00) = -1.20V
This is negative, so the reaction will not happen.

Answer 58

A

The conditions are not standard

* The reaction kinetics are not favourable

Answer 59

A

The half-cell equilibrium shifts to the right, reducing the ease of electron loss of Zn.
The electrode potential of Zn/Zn²⁺ becomes less negative.
The whole cell potential will be lower.

Answer 60

A

The half-cell equilibrium shifts to the right, increasing the ease of electron gain of Cu²⁺.
The electrode potential of Cu²⁺/Cu becomes more positive.
The whole cell potential will be higher.

Answer 61

A

The rate of reaction might be so slow that is it might not appear to happen
The activation energy may be too high for the reaction to happen spontaneously

Answer 62

A

Entropy change

* Equilibrium constant

Answer 63

A

E° ∝ ΔS(total)

Answer 64

A

E° ∝ lnK

Answer 65

A

E° ∝ ΔS(total)

* Entropy and the equilibrium constant are linked

Answer 66

A

The more reactive a metal, the more negative the standard electrode potential.
The more reactive a non-metal, the more positive the standard electrode potential.

Answer 67

A

They are essentially batteries

* They work just like electrochemical cells

Answer 68

A

Using the electrode potentials of the substances used in the cell.

(i.e. Just like with a normal electrochemical cell)

Answer 69

A

a) Combine the two reactions in the feasible reaction (so that E° is positive):

2NiO(OH) + 2H₂O + Fe -> 2Ni(OH)₂ + Fe(OH)₂

b) E°(cell) = E°(red) - E°(oxid)

E°(cell) = +0.49 -(-0.89) = 1.38V

Answer 70

A

Electrochemical cells that have fuel stored outside the cell and fed in when electricity is required.

Answer 71

A

Hydrogen-oxygen fuel cell

Answer 72

A

Acidic

* Alkaline

Answer 73

A

Powering electric vehicles

Answer 74

A

H₂ gas is fed next to negative platinum electrode -> H₂O flows away
O₂ gas is fed next to positive platinum electrode
Electrons flow through circuit from negative hydrogen electrode to positive oxygen electrode
Electrodes are separated by an anion-exchange membrane that allows OH⁻ and H₂O to pass through it, but not H₂ and O₂
Electrolyte between membranes is KOH, in which OH⁻ ions flow from oxygen to hydrogen side

Answer 75

A

Anion-exchange membranes

Answer 76

A

Allow anions (OH⁻) and water to pass through

* Don’t allow H₂ and O₂ to pass through

Answer 77

A

Electrons flow away from the negative electrode.

Answer 78

A

The electrode which:
• Anions flow to
• Electrons flow away from

Answer 79

A

The electrode which:
• Cations flow to
• Electrons flow to

Answer 80

A

From negative electrode near hydrogen to the positive electrode near oxygen. OH⁻ carry the charge from there through the electrolyte to the negative electrode again.

Answer 81

A

• Hydrogen is fed to the negative electrode. It combines with the OH⁻ travelling through the electrolyte:
2H₂(g) + 4OH⁻(aq) -> 4H₂O(l) + 4e⁻
• Oxygen is fed to the positive electrode. It combines with water in the solution to produce OH⁻:
O₂(g) + 2H₂O(l) + 4e⁻ -> 4OH⁻(aq)
• OH⁻ travel through the solution to the negative electrode, where they are used by the hydrogen.
• Electrons move away from the negative electrode (hydrogen-side) and travel around the circuit to the positive electrode (oxygen-side).

Overall effect:
2H₂(g) + O₂(g) -> 2H₂O(l)

Answer 82

A

• Negative electrode:
2H₂(g) + 4OH⁻(aq) -> 4H₂O(l) + 4e⁻
• Positive electrode:
O₂(g) + 2H₂O(l) + 4e⁻ -> 4OH⁻(aq)
• Overall:
2H₂(g) + O₂(g) -> 2H₂O(l)

Answer 83

A

2H₂(g) + 4OH⁻(aq) -> 4H₂O(l) + 4e⁻

Answer 84

A

O₂(g) + 2H₂O(l) + 4e⁻ -> 4OH⁻(aq)

Answer 85

A

Pg 160 of revision guide

Answer 86

A

H₂ gas is fed next to negative electrode
O₂ gas is fed next to positive electrode
Electrons flow through circuit from negative hydrogen electrode to positive oxygen electrode
Electrodes are separated by a polymer electrolyte membrane that allows H⁺ ions to get through, but not electrons, O₂ or H₂
Electrolyte is in the polymer electrolyte membrane

Answer 87

A

Polymer electrolyte membrane (PEM)

Answer 88

A

It allows H⁺ ions to travel across, but not O₂, H₂ or electrons. So electrons are forced around the external circuit.

Answer 89

A

From negative electrode near hydrogen to the positive electrode near oxygen. H⁺ carry positive charge from the hydrogen side to the oxygen.

Answer 90

A

• Hydrogen is fed to the negative electrode. It is forced to split into H⁺ and e⁻:
H₂ -> 2H⁺ + 2e⁻
• Oxygen is fed to the positive electrode. It combines with H⁺ ions travelling across the PEM:
1/2O₂ + 2H⁺ + 2e⁻ -> H₂O
• H⁺ travelled through the polymer electrolyte membrane (PEM) from the hydrogen to the oxygen side.
• Electrons move away from the negative electrode (hydrogen-side) and travel around the circuit to the positive electrode (oxygen-side).

Overall effect:
2H₂(g) + O₂(g) -> 2H₂O(l)

Answer 91

A

• Negative electrode:
H₂ -> 2H⁺ + 2e⁻
• Positive electrode:
1/2O₂ + 2H⁺ + 2e⁻ -> H₂O
• Overall:
2H₂ + O₂ -> 2H₂O

Answer 92

A

H₂ -> 2H⁺ + 2e⁻

Answer 93

A

1/2O₂ + 2H⁺ + 2e⁻ -> H₂O

Answer 94

A

Pg 161 of revision guide

Answer 95

A

Hydrogen side -> Anode -> Negative

* Oxygen side -> Cathode -> Positive

Answer 96

A

Electrons flow in the same direction and the overall reaction is the same, except:
• Alkaline cell uses KOH electrolyte and anion-exchange membranes, while acidic cell uses polymer electrolyte membrane -> So in an alkaline cell OH⁻ moves from positive to negative electrode, while in an acidic cell H⁺ moves from positive to negative electrode
• So there are different half-equations at each electrode

Answer 97

A

Hydrogen-rich fuels, including methanol and ethanol.

Answer 98

A

Traditionally, they can be converted into H₂ in the car by a reformer -> They are then used
Alternatively, there is a new generation of fuel cells that can use alcohols directly without having to reform them into hydrogen first

Answer 99

A

• Alcohol is oxidised at the anode in the presence of water:
CH₃OH + H₂O -> CO₂ + 6e⁻ +6H⁺
• The H⁺ ions pass through the electrolyte and are oxidised to water.
6H⁺ + 6e⁻ + 3/2O₂ -> 3H₂O

Answer 100

A

H⁺ moves through the electrolyte from the anode to the cathode.

Answer 101

A

Acid-base titrations

* Redox titrations

Answer 102

A

You work out how much acid is needed to neutralise a given volume of alkali of known concentration (or vice versa)
This is used to work out the concentration of the unknown acid/alkali

Answer 103

A

Pipette
Burette
Conical flask
Acid/Alkali of known concentration
Acid/Alkali of unknown concentration

Answer 104

A

Used to work out the concentration of an oxidising or reducing agent
It works by titrating a reducing agent against an oxidising agent of a known concentration (or vice versa)
From this, the concentration can be worked out

Answer 105

A

Transition element ions, because they are good at changing oxidation number. This makes them good oxidising and reducing agents.

Answer 106

A

The solution of known concentration is added to the solution of unknown concentration.

Answer 107

A

1) Pipette a quantity of a reducing agent (e.g. aqueous Fe²⁺) into a conical flask.
2) Add an excess of dilute sulfuric acid (this is ensure that the oxidising agent can easily be reduced).
3) Do a rough titration by adding MnO₄⁻ using a burette until the colour changes from colourless to purple.
4) Repeat and average to get an accurate titration volume.
5) Do the right calculations to work out the concentration.

Answer 108

A

This is irrelevant. The solution of known concentration is added to the solution of unknown concentration.

Answer 109

A

An excess of dilute sulfuric acid is added

* This is to make sure there are plenty of H⁺ ions to allow the oxidising agent to be reduced

Answer 110

A

Usually no, because the transition metals tend to change colour when they change oxidation state.

Answer 111

A

Oxidising agent

Answer 112

A

MnO₄⁻ -> Purple

* Mn²⁺ -> Colourless

Answer 113

A

• MnO₄⁻ + 8H⁺ + 5e⁻ -> Mn²⁺ + 4H₂O
• 5Fe²⁺ -> 5Fe³⁺ + 5e⁻
Full equation:
• MnO₄⁻ + 8H⁺ + 5Fe²⁺ -> Mn²⁺ + 4H₂O + 5Fe³⁺

From purple to colourless.

Answer 114

A

Oxidising agent

Answer 115

A

Cr₂O₇²⁻ -> Orange

* Cr₃⁺ -> Green

Answer 116

A

• Cr₂O₇²⁻ + 14H⁺ + 6e⁻ -> 2Cr³⁺ + 7H₂O
• 3Zn -> 3Zn²⁺ + 6e⁻
Full equation:
• Cr₂O₇²⁻ + 14H⁺ + 3Zn -> 2Cr³⁺ + 7H₂O + 3Zn²⁺

Orange to green.

Answer 117

A

Doing it in front of a white surface.

Answer 118

A

1) Work out the number of moles used of the reactant of known concentration.
2) Use the equation to find the number of moles of the reactant of unknown concentration.
3) Use “conc = moles / vol” to work out the concentration of the reactant of unknown concentration.

Answer 119

A

MnO₄⁻ + 5Fe²⁺ + 8H⁺ -> Mn²⁺ + 5Fe³⁺ + 4H₂O
Number of moles of MnO₄⁻ = Conc x Vol = 0.0200 x (27.5 / 1000) = 5.50 x 10⁻⁴ mol
Therefore, the number of moles of Fe²⁺ = 5.50 x 10⁻⁴ x 5 = 2.75 x 10⁻³ mol
Concentration of Fe²⁺ = Moles / Vol = (2.75 x 10⁻³) / (25.0 x 10⁻³) = 0.110 mol/dm³

Answer 120

A

Estimating the percentage of iron in iron tablets.

Answer 121

A

Iron(II) sulfate

Answer 122

A

MnO₄⁻ + 8H⁺ + 5Fe²⁺ -> Mn²⁺ + 4H₂O + 5Fe³⁺
Moles of MnO₄⁻ = Conc x Vol = 0.0250 x (12.5 x 10⁻³) = 3.125 x 10⁻⁴ mol
Therefore moles of Fe²⁺ = 1.5625 x 10⁻³ mol
Moles of Fe²⁺ in 250cm³ = 1.5625 x 10⁻³ x 10 = 1.5625 x 10⁻² mol
Mass of iron in the tablet = Mr x Moles = 55.8 x 1.5625 x 10⁻² = 0.871g
Percentage of iron in tablet = (0.871 / 2.56) x 100 = 34.1%

Answer 123

A

Reactant: H⁺

* Product: H₂O

Answer 124

A

Iodine - Sodium thiosulfate

Answer 125

A

S₂O₃²⁻

Answer 126

A

1) Use a sample of the oxidising agent to oxidise as much I⁻ (from KI) as possible
2) Find out how many moles of I₂ have been produced -> By reacting it with sodium thiosulfate until the colour fades and the starch that is added remains blue
3) Calculate the concentration of the oxidising agent from the moles of I₂ produced

Answer 127

A

STAGE 1:
• Measure out a 25cm³ sample of potassium iodate(V)
• Add this to an excess of acidified potassium iodide solution (KI).
• Some of the iodide ions are oxidised to iodine:
IO₃⁻ + 5I⁻ + 6H⁺ -> 3I₂ + 3H₂O
STAGE 2:
• From a burette, add sodium thiosulfate of known concentration to the solution drop by drop:
I₂ + 2S₂O₃²⁻ -> 2I⁻ + S₄O₆²⁻
• When the colour fades to a pale yellow, add 2cm³ of starch solution to detect the presence of iodine -> This turns the solution dark blue
• Add sodium thiosulphate until the blue colour disappears (end point)
• Using the titre volume, calculate the moles of iodine in the original solution
STAGE 3:
• Using the original equation, work out the moles of the oxidising agent and therefore its concentration

Answer 128

A

1) Take a flask containing I₂ produced by a redox reaction of an oxidising agent.
2) From a burette, add sodium thiosulfate to the flask, drop by drop.
3) When the iodine fades to a pale yellow colour, add 2cm³ of starch solution (to detect the presence of iodine). This gives a blue-black colour.
4) Continue adding the sodium thiosulfate drop by drop until the blue colour disappears (end point).
5) Use the titre volume and the equation to work out the moles of I₂ in the original solution.

Answer 129

A

Yellow -> Pale yellow -> Blue-black (when starch added) -> Colourless

Answer 130

A

IO₃⁻(aq) + 5I⁻(aq) + 6H⁺(aq) -> 3I₂(aq) + 3H₂O(l)

Answer 131

A

I₂(aq) + 2S₂O₃²⁻(aq) -> 2I⁻(aq) + S₄O₆²⁻(aq)

Answer 132

A

• IO₃⁻ + 5I⁻ + 6H⁺ -> 3I₂ + 3H₂O
• I₂ + 2S₂O₃²⁻ -> 2I⁻ + S₄O₆²⁻
Second reaction:
• Moles of thiosulfate = 0.120 x 11.0 x 10⁻³ = 1.32 x 10⁻³ mol
• Therefore, moles of iodine = 1.32 x 10³ / 2 = 6.60 x 10⁻⁴ mol
First reaction:
• Therefore, moles of iodate = 6.60 x 10⁻⁴ / 3 = 2.20 x 10⁻⁴ mol
• Concentration of potassium iodate(V) = 0.00880 mol/dm³

Answer 133

A

STAGE 1:
• Dissolve a weighed amount of the alloy in some concentrated nitric acid
• Pour this mixture into a 250cm³ volumetric flask and make up to 250cm³ using deionised water
• Pipette out 25cm³ and transfer to a flask.
• Slowly added sodium carbonate to neutralise any remaining acid until a precipitate form. Add drops of ethanoic acid to remove it.
• Add an excess of potassium iodide solution:
2Cu²⁺ + 4I⁻ -> 2CuI + I₂
• A white precipitate forms. The copper(II) ions have been reduced to copper(I).
STAGE 2:
• Titrate the mixture against sodium thiosulfate (see other flashcards) to find the number of moles of iodine present.
• I₂ + 2S₂O₃²⁻ -> I⁻ + S₄O₆²⁻
STAGE 3:
• Use the first equation to work out the moles of copper in 25cm³, and therefore 250cm³
• From this, calculate the mass of copper in the whole piece of the alloy
• Work out the percentage by mass of the copper in the alloy

Answer 134

A

2Cu²⁺(aq) + 4I⁻(aq) -> 2CuI(s) + I₂(aq)

Answer 135

A

White solid (insoluble)

Answer 136

A

Pg 166 of revision guide

Answer 137

A

1) The starch indicator has to be added at the right point, when most of the I₂ has reacted, or the blue colour will be very slow to disappear
2) Starch solution needs to be freshly made or it won’t behave as expected
3) In copper alloy calculations, the copper(I) iodide precipitate can make seeing the colour of the solution difficult
4) Iodine produced before the iodine-thiosulfate titration can evaporate, giving a too low percentage or concentration of the initial reactant.

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