DM - redox *03

Question 1

what is oxidation?

Answer 1

a loss of electrons

Question 2

What is reduction?

Answer 2

A gain of electrons

Question 3

What is a redox reaction?

Answer 3

when reduction and oxidation happens simultaneously

Question 4

What is a reducing agent?

Answer 4

donates its electrons to something

(oxidised itself)

the more powerful a reducing agent the more easily it can be oxidised

Question 5

What is an oxidising agent?

Answer 5

takes electrons away from something

(reduced itself)

the more powerful the oxidising agent the more easily it can be reduced

Question 6

What do half equations show?

Answer 6

show whats being reduced and whats been oxidised

eg
Na —-> Na+ + e-
Cl2 + 2e- —-> 2Cl-

Question 7

Balancing half equations

Answer 7

sometimes cannot balance the equation by just multiplying up the reactants and products and adding electrons

1. If oxidising agent contains OXYGEN, need to add some H+ ions (reactants side) and H2O (products side) to make half equations balance
2. also need to balance charges
   - might need to multiply up and add electrons

Question 8

Balancing half equations - MnO4- —> Mn2+ by Fe2+ ions

Answer 8

iron is oxidised = Fe2+ (aq) —> Fe3+ (aq) + e-

manganate reduced = MnO4- (aq) —> Mn2+ (aq)

to balance oxygens = MnO4- (aq) —> Mn2+ (aq) + 4H2O (l)

then need to balance hydrogens = MnO4- (aq) + 8H+ (aq) —-> Mn2+ (aq) + 4H2O (l)

finally need to balance charges by adding electrons =
MnO4- (aq) + 8H+ (aq) + 5e- —-> Mn2+ (aq) + 4H2O (l)

overall equation
MnO4- (aq) + 5Fe2+ + 8H+ —-> Mn2+ + 5Fe3+ + 4H2O

Question 9

Acid-Base titrations - what do they find?

Answer 9

how much acid is needed to neutralise a base

Question 10

acid-base titrations - how to set up?

Answer 10

1. measure out alkali using a pipette, put it in a flask with some indicator, eg. phenolphthalein
2. add acid to the burette and do a rough titration to get an idea of where the end point is
   - swirl each time acid is added
3. now do accurate titrations, run the acid within 2cm^3 of the end point then add the acid dropwise
4. record the vol. of acid used to neutralise the alkali
   - repeat until concordant results (within 0.1cm^3)

Question 11

Redox titrations - what do they show?

Answer 11

how much oxidising agent is needed to exactly react with a quantity of reducing agent

Question 12

redox titration - what do you need to know?

Answer 12

concentration of either the oxidising or reducing agent

can use titration results to find the concentration of the other

Question 13

redox titrations - Manganese (VII) ions, MnO4- method

Answer 13

1. measure quantity of reducing agent eg. aq Fe2+ ions using a pipette and put it into a conical flask
2. add some dilute sulfuric acid to the flask (in excess)
   - so plenty of H+ ions to allow the oxidising agent to be reduced
3. Add aq MnO4- (oxidising agent) to the reducing agent using a burette, swirling the flask as you do so
4. stop when the mixture in the flask becomes tainted with the colour of MnO4- (purple) this is the end point - a rough titration
5. then do accurate titrations until concordant results (within 0.1cm^3)

Question 14

redox titrations - Manganese (VII) ions, MnO4- - colour change

Answer 14

MnO4- in aq potassium manganate (VII), KMnO4, are purple

when added to the reducing agent, they react with it are are reduced to colourless Mn2+ ions

the reaction continues until all the reducing agent has reacted
the next drop into the flask will give the mixture the pink colour of the oxidising agent

need to spot exactly where this happens

Question 15

redox titrations - what can results be used for?

Answer 15

to find the conc. of the reagent

Question 16

redox titrations - Manganese (VII) ions, MnO4- and Fe2+ equation

Answer 16

MnO4- (aq) + 8H+ (aq) + 5Fe2+ (aq) —–> Mn2+ (aq) + 2H2O (l) + 5Fe3+ (aq)

5 moles of Fe2+ react with 1 mole of MnO4-

Question 17

electrochemical cells - what are they?

Answer 17

made from two different metals dipped in salt solution of their own ions and connected by a wire

always two reactions - redox (one reduction and one oxidation)
- oxidation at anode (-ve electrode)
- reduction at cathode (+ve electrode)
CHARGES ARE THE OTHER WAY ROUND

so electrons flow through the wire from the most reactive metal to the least

Question 18

electrochemical cells - zinc/copper

Answer 18

zinc loses electrons more easily than copper, so in the half cell zinc (s) (from the zinc electrode) loses electrons and is oxidised to Zn2+ (aq) ions
Zn (s) —-> Zn2+ (aq) + 2e-

this releases electrons into the external circuit

in the other half cell the same number of electrons are taken from the external circuit, reducing the Cu2+ ions to copper atoms
Cu2+ (aq) + 2e- ——> Cu (s)

Question 19

electrochemical cells - how can you measure the cell potential, Ecell?

Answer 19

put a voltmeter between the two half cells to measure the voltage between the two half cells

this is the cell potential

Question 20

electrochemical cells - half cells involving solutions of two aqueous ions of the same element

eg. Fe2+ (aq) / Fe3+ (aq)

Answer 20

the conversion of Fe2+ Fe3+ happens on the surface of the electrode

neither the reactants nor products are solids need something else for the electrode

it needs to conduct electricity and be very inert so that it won’t react with anything in the half cell
- Platinum excellent but v. expense so graphite often used instead.

Question 21

electrochemical cells - drawing them, anode left or right

Answer 21

the half cell where oxidation happens (anode) always on the left

the half cell where reduction happens (cathode) always on the right

Question 22

electrochemical cells - how to set up?

Answer 22

1. get a strip of each of the metals you’re investigating (these are the electrodes)
   - clean the surface of the metals using emery paper (or sandpaper)
2. clean any grease or oil from the electrodes using propanone
   - don’t touch the surface with your hands and could transfer grease back onto the electrode
3. place electrode in beaker filled with a solution containing ions of that metal
   - sometimes also have to add acid
4. create a salt bridge to link the two solutions together
   - soak a piece of filter paper in salt solution, KCl (aq) or KNO3 (aq)
   - drape between the two beakers, the ends should be immersed in the salt solution
5. connect the electrodes to a voltmeter using crocodile clips and wires
   - if connected correctly should get a reading on your voltmeter

Question 23

electrochemical cells - are reactions at each electrode reversible?

Answer 23

yes

the reactions can go in either direction

Question 24

electrochemical cells - equations for zinc/copper

Answer 24

Zn2+ (aq) + 2e- Zn (s)

Cu2+ (aq) + 2e- Cu (s)

Question 25

electrochemical cells - how are half equations written?

Answer 25

the reduction reaction always go forwards

electons always added on left side

Question 26

electrode potential

Answer 26

the volatage

• between or half cells
• each half cell has its own potential (hydrogen electrode)

Question 27

why does each half cell have an electrode potential

Answer 27

there is a potential difference between electrode and solution

eg. zinc half cell - Zn electrode -vely charged as electrons left behind when Zn2+ ions form, Zn2+ ions in solution +vely charged

Question 28

elecrode potential - combining electrode potentials

Answer 28

the more +ve standard electrode potential goes forward (reduced)

the more -ve standard electrode potential goes backwards (oxidised)

Question 29

elecrode potential - combining electrode potentials

eg. zinc-copper cell

Answer 29

Zn2+(aq)/Zn(s) electrode potential = -0.76V
Cu2+(aq)/Cu(s) electrode potenial = +0.34V

zinc half cell more -ve so is oxidised, goes backwards
copper half cell more +ve so is reduced, goes forwards

overall reaction = Cu2+ (aq) + Zn (s) Cu(s) + Zn2+ (aq)

reducing agent = zinc
oxiding agent = copper

Question 30

how do you measure the electrode potential of a half cell?

Answer 30

against a standard hydrogen electrode

Question 31

what is a standard hydrogen electrode?

Answer 31

H2 gas bubbles into H+ solution

Platinum foil surface on electrode

salt bridge

voltmeter

always drawn on the left

Question 32

what are the standard conditions for measuring the electrode potential of a half cell using a hydrogen electrode?

Answer 32

any solution must have a conc. of 1.00 mol dm^03

temperature must be 298 K (25degrees)

pressure must be 100kPa

Question 33

half equation for the reaction at the hydrogen electrode?

Answer 33

2H+ (aq) + 2e- H2 (g)

Question 34

what is the standard electrode potential of a hydrogen half cell?

Answer 34

0.00V

Question 35

Draw the standard hydrogen electrode half cell

Answer 35

H2 gas bubbles in at 100kPa

tube thing surrounding it

H+ ions in solution at 1 mol dm^-3

Solid Pt foil surface on electrode

wire connecting it to metal electrode

voltmeter

salt bridge

Question 36

How do you work out Ecell?

Answer 36

use electrode potentials

Ecell = Emore +ve - Emore -ve

this value will always be a +ve Volatge

Question 37

why do reactive metals have large negative electrode potentials?

Answer 37

the more reactive a metal is the more it wants to LOSE ELECTRONS to form a +ve ion

(its a stronger reducing agent)

Question 38

why do more reactive non-metals have more positive standard electrode potentials

Answer 38

the more reactive a non-metal is the more it wants to GAIN ELECTRONS, to form a -ve ion

(its a stronger oxidising agent)

Question 39

what is the electrochemical series?

Answer 39

a list a redox equilibria

arranged in order of electrode potential
- most -ve at top

Question 40

what does the electrochemical series show?

Answer 40

what is reactive

Question 41

electrochemical series - more negative electrode potentials mean that:

Answer 41

1. the right hand substances are more easily oxidised
2. the left hand substances are more stable

decreases down series (obvs) as getting less -ve

Question 42

electrochemical series - more positive electrode potentials mean that:

Answer 42

1. the left hand substances are more easily reduced
2. the right hand substances are more stable

increases down series (obvs) as getting more +ve

Question 43

how can you use electrode potentials to predict whether a reaction will happen?

eg. predict whether zinc metal reacts with aqueous copper ions

Answer 43

need half equations and electrode potentials:
Zn2+ (aq) + 2e- Zn (s) E= -0.76 V
Cu2+ (aq) + 2e- Cu (s) E = +0.34 V

put the most -ve on top
Zn2+ (aq) + 2e- —-> Zn (s)
Cu2+ (aq) + 2e- —–> Cu (s)
read anti clockwise

Zn (s) + Cu2+ (aq) —> Zn2+ (aq) + Cu (s)

zinc metal WILL react with copper ions

ONLY UNDER STANDARD CONDITIONS

Question 44

predicitng feasible reactions - why could predicition be wrong?

Answer 44

kinetics not favourable:

1. rate of reaction may be so slow that the reaction might not appear to happen
2. if a reaction has a high activation energy, this may stop it happening

conditions not standard

1. changing conc. or temp. changes electrode potential
   - its shifts the equilibrium

Question 45

rusting - what is it?

Answer 45

when iron is exposed to oxygen and water it will turn into rust

Question 46

rusting - how?

Answer 46

two half equations:
Fe2+ (aq) + 2e- < —> Fe (s) E= -0.44 V
2H2O (l) + O2 (g) + 4e- < —-> 4OH- (aq) E = +1.23 V

overall: 2H2O (l) + O2 (g) + 2Fe (s) —-> 2Fe2+ (aq) + 4OH- (aq)
E = +1.67 V

Fe2+ and OH- combine to form a percipiate of iron (II) hydroxide
Fe2+ (aq) + 2OH- (aq) —-> Fe(OH)2 (s)

Fe(OH)2 if further oxidised to Fe(OH)3 by oxygen
2H2O (l) + O2 (g) + 4Fe(OH)2 (s) —–> 4Fe(OH)3 (s)

Iron (III) hydroxide will eventually turn into hydrated iron (III) oxide, Fe2O3.xH2O (this is rust)

Question 47

rusting - why is rust less likely to form in alkaline conditions?

Answer 47

would shift equilibrium of 2H2O (l) + O2 (g) + 4e- 4OH- (aq) would shift left to get rid of extra OH-

as a result, the equilibrium of Fe2+ (aq) + 2e- < —>Fe (s) is pushed right to get rid of extra electrons this produces

so less Fe2+ to take part in Fe2+ (aq) + 2OH- (aq) —-> Fe(OH)2 (s) so LESS rust

Question 48

rusting - how to prevent? - COATING

Answer 48

coat iron with barrier to keep out either O2 or H2O or both

1. painting/coating with a polymer - idea for big for small structures can also be decorative
2. oiling/greasing - this has to be using when moving parts are involves, eg. bike chains