Chapter 8 Reacitvity Trends

Question 1

What are the characteristic physical/chemical properties of the group 2 elements?

Answer 1

They are alkali metals because they form alkaline metal hydroxides
Highly reactive and do not occur as metals in nature
Form stable compounds like calcium carbonate

Question 2

Why are the group 2 elements considered as reducing agents?

Answer 2

Each metal is oxidised losing 2 electrons to form a 2+ ion

Another species will gain these electrons and be reduced, therefore they are reducing agents

Question 3

What occurs during a redox reaction with group 2 elements and oxygen? Give an example and equation with Magnesium

Answer 3

They form a metal oxide with the general formula MO made of M2+ and O2- ions
For example:Mg burns with a brilliant white light to form MgO
2Mg(s) + O2(g) -> 2MgO(s)
Oxygen is reduced

Question 4

What occurs during a redox reaction with a group 2 element and water? Give an equation with Strontium

Answer 4

Form an alkaline hydroxide with the general formula M(OH)2 and H2(g)
Water and Mg react slowly but the reaction becomes more vigorous down the group as the reactivity increase down the group

Sr(s) + 2H2O(l) -> Sr(OH)2(aq) + H2(g)
most hydrogen is reduced but the H in Sr(OH)2 doesn’t have a change in oxidation number

Question 5

What occurs in a redox reaction with group 2 elements and dilute acids? Give an equation with Magnesium and Hydrochloric Acid

Answer 5

Form a salt and hydrogen gas
metal+acid->salt+hydrogen

Mg(s) + 2HCl(aq) -> MgCl2(aq) + H2(g)
Hydrogen is reduced

Question 6

Describe the trends in reactivity and ionisation energy for group 2 elements

Answer 6

Ionisation energies decrease down the group because the attraction between the nucleus and outer shell electrons decreases
This is a result of increasing atomic radius and electron shielding from the increased electron shells
This makes it easier (require less energy) to lose electrons

Reactivity increases down the group for the same reasons

Question 7

Describe the reaction between group 2 oxides and water. Use calcium oxide as an example for equations

Answer 7

They react to release hydroxide ions which can react with group 2 metal actions to make metal hydroxides

CaO(s) +H2O(l) -> Ca2+ (aq) + 2OH-

Group 2 hydroxides are only slightly soluble in water. When the solution becomes saturated metal ions and hydroxide ions will form a solid ppt.

Ca2+(aq) + 2OH-(aq) -> Ca(OH)2(s)

Question 8

Explain the trend in solubility of group2 hydroxides down the group.

Answer 8

Solubility of group 2 hydroxides in water increases down the group, so the resulting solutions have a higher concentration of OH- ions making them more alkaline ( higher pH )
Mg(OH)2 is slightly soluble in water with a low OH- concentration and a pH~ 10
Ba(OH)2 is much more soluble in water with a higher concentration of OH- and a pH ~13

Question 9

How can group 2 compounds be used in agriculture?

Answer 9

Ca(OH)2 is added to fields as lime by farmers to increase the pH of acidic soils

Ca(OH)2(s) + 2H+(aq) -> Ca2+(aq) + H2O(l)

Question 10

How can group 2 compounds be used in medicine?

Answer 10

Often used as antacids for treating acid indigestion
Many tablets use MgCO3 and CaCO3
Milk of magnesia is a suspension of white Mg(OH)2 in water
Stomach acid is mostly HCl

Mg(OH)2 (aq) + 2HCl(aq) -> MgCl2(aq) + 2H2O(l)
CaCO3(s) + 2HCl(aq) -> CaCl2(aq) + H2O(l) CO2(g)

Carbonates decompose at higher temperatures down the group

Question 11

How can calcium carbonate be used in power stations?

Answer 11

Sprayed down power station chimneys to neutralise sulphuric dioxide as a scrubber, to prevent acid rain

Question 12

What are the trends down the group of the halogen boiling points?

Answer 12

Boiling point increases down the group because each diatomic particle has more electrons than the previous halogen
This means that the induced dipole-dipole forces are stronger which require more energy to break

Question 13

What happens to the oxidising power of the halogens down the group?

Answer 13

Oxidising power (reactivity) deacreases down the group because:
Atomic radius increases
Electron shielding increases (outweighs increase in nuclear charge)
Attraction to the nucleus is lowered
Ability to gain an electron decreases

Question 14

What are halogens considered as oxidising agents? Use Chlorine to wire a half equation

Answer 14

Each halogen atom is reduced, gaining 2 electron to form a 1- halide ion
Therefore they oxidise another species in the reaction
Cl2 + 2e- -> 2Cl-

Question 15

Describe the halogen displacement reactions of Chlorine, Bromine and Iodine as well as the colour changes seen and the colour change with a suitable organic compound such as cyclohexane.

Answer 15

A solution of each halogen is added to an aqueous solution of a halide and another compound.
If the halogen is more reactive than the halide present:
-the halogen will displace the halide
-the solution changes colour

Chloride + bromine or Iodine = no reaction
Bromide+ chlorine= displacement to form an orange solution (Br2) which remains orange in cyclohexane
Bromide + Iodine= no reaction
Iodide + chlorine or bromine= displacement to form an orange brown solution which turns violet in cyclohexane

Question 16

Give the equation and ionic equation of a displacement reaction between Chlorine and Sodium Bromide.

Answer 16

Cl2(aq) + 2NaBr(aq) -> 2NaCl(aq) + Br2(aq)
Cl2 + 2Br- -> 2Cl- + Br2
Chlorine is reduced and Bromine is oxidised (displaced)

Question 17

What is a disproportionation reaction? Give an example of chlorine and water (in the presence of cold dilute sodium hydroxide)

Answer 17

A redox reaction where the same element is both oxidised and reduced simultaneously

Cl2(aq) + H2O(l) -> HClO(aq) + HCl(aq)
Chlorine is reduced to form hydrochloric acid
Chlorine is oxidised to form chloric acid
Chlorate ions kill bacteria and act as a weak bleach ClO-

Question 18

Write the disproportionation reaction between chlorine and cold, dilute sodium hydroxide.

Answer 18

Chlorine is limited by its poor solubility in water

Cl2(aq) +2NaOH(aq) -> NaClO (aq) + NaCl(aq) + H2O(l)
Chlorine is reduced to form sodium chloride
Chlorine is oxidised to form sodium chlorate

This provides a higher concentration of chlorate ions so is used to make household bleach

Question 19

What are the benefits and risks of using chlorine in water purification?

Answer 19

Benefits:

• Makes water potable
• kills bacteria

Risks:

• highly toxic
• respiratory irritant
• can react with hydrocarbons (CH4) which can make carcinogens

Question 20

How can halides be used as reducing agents?

Answer 20

Halides reduce halogens in oxidation (displacement) reactions and can reduce other strong oxidising agents like sulfuric acid

Chloride ions are not strong enough

Bromide ions can form sulphur dioxide
2Br- + H2SO4 + 2H+ -> SO2 + Br2 + 2H2O

Iodide ions are more powerful and form sulphur which is reduces further to hydrogen sulphide

1. 2I- + H2SO4 + 2H+ -> SO2 + I2 +2H2O
2. 2I- + SO2 + 2H+ -> S + I2 + H2O
3. 2I- + S + 2H+ -> I2 + H2S

Question 21

Describe the test for carbonate ions. Create an equation with sodium carbonate

Answer 21

1. React compound in a test tube with nitric acid
2. Collect any gas given off
3. Pass gas through limewater, if it turns cloudy the gas is CO2

If the gas is CO2 the original compound contained carbonate ions

Na2CO3(aq) + 2HNO3(aq) -> 2NaNO3(aq) + H2O(l) + CO2(g)

Question 22

Describe the test for sulphate ions. Create an ionic equation to prove this.

Answer 22

Barium sulphate is one of few sulphate that is insoluble in water.

1. Add Ba2+ ions (usually barium nitrate) to the compound
2. If a white ppt. Forms the compound contains SO42- ions

Ba2+(aq) + SO42-(aq) -> BaSO4(s)

Question 23

Describe the tests for halides. Create an overall ionic equation using X to represent a halide/halogen

Answer 23

Silver halides are one of few halides that are insoluble in water
1. Add aqueous silver nitrate (AgNO3) to an aqueous solution of a halide
2. Silver ppts. form but are different colours:
AgCl is white
AgBr is cream
AgI is yellow
These colours can be hard to distinguish

Ag+(aq) + X- -> AgX(s)

3. Test the solubility of the ppts. in ammonia:
   AgCl is soluble in dilute NH3
   AgBr is soluble in concentrated NH3
   AgI is insoluble in concentrated NH3

Question 24

What sequence should the anion tests be completed in to prevent false positive results?

Answer 24

Carbonate test
- neither of the other anions will bubble in dilute acid
Sulphate test
- Ba2+ ions will form a white ppt with carbonate ions so must be done after the carbonate test
Halide text
- AgCO3 and AgSO4 are insoluble in water so must be done last or there will be a false positive

Question 25

Describe the test for ammonium ions. Create a suitable ionic equation

Answer 25

1. Add aqueous NaOH to a solution of ammonium ions
2. Ammonia gas forms, won’t see bubbles as ammonia is very soluble in water
3. Heat the mixture to release the gas
4. Test the gas with damp pH indicator paper, ammonia is alkaline do the gas will turn the paper blue

NH4+(aq) + OH-(aq) -> NH3(g) + H2O(l)