Reactivity Trends (Chapter 8)

Question 1

What is the name for the Group 2 metals?

Answer 1

The alkaline earth metals - because of the alkaline properties of their metal hydroxides

Question 2

How are Group 2 metals found?

Answer 2

They are reactive and do not occur in their elemental form naturally - found in stable compounds e.g. CaCO3

Question 3

What is a general formula for the electron configuration of Group 2 metals

Answer 3

[nearest noble gas] (period number)s2

Question 4

Explain the electron configuration of Group 2 metals

Answer 4

• Each Group 2 element has 2 outer shell electrons, two more than the electron configuration of a noble gas
• Therefore, 2 electrons are in the outer s sub-shell

Question 5

What is the electron configuration of the Group 2 ions?

Answer 5

The nearest noble gas

Question 6

What happens in redox reactions of Group 2 metals?

Answer 6

Each metal atom is oxidised, losing 2 electrons to form a 2+ ion - Group 2 element is a reducing agent
e.g. Ca = Ca2+ + 2e-

Question 7

What happens in redox reactions of Group 2 metals with oxygen?

Answer 7

They react with oxygen to form a metal oxide with the general formula MO, made up of M2+ and O2- ions
e.g. 2Mg + O2 = 2MgO (white solid)

Question 8

What happens in redox reactions of Group 2 metals with water?

Answer 8

They react with water to form an alkaline hydroxide with the general formula M(OH)2 and H2
e.g. Mg + 2H2O = Mg(OH)2 + H2 - reaction becomes more vigorous down the group

Question 9

What happens in redox reactions of Group 2 metals with dilute acids?

Answer 9

They react with dilute acids to form a salt and hydrogen

e.g. Mg + 2HCl = MgCl2 + H2

Question 10

Does reactivity increase or decrease down Group 2?

Answer 10

Increase

Question 11

Why does reactivity increase down Group 2?

Answer 11

1) The atoms of Group 2 elements react by losing electrons to form 2+ ions
2) The formation of 2+ ions from gaseous atoms requires the input of two ionisation energies
3) The ionisation energy decreases down the group because the attraction between the nucleus and outer electrons decreases as a result of increasing atomic radius and increasing shielding effect
4) Therefore, electrons are lost more easily and the Group 2 elements become more reactive and stronger reducing agents down the group

Question 12

What happens when Group 2 oxides react with water?

Answer 12

They release OH- ions and forming alkaline solutions of the metal hydroxide
e.g. CaO(s) + H2O = Ca2+(aq) +2OH-(aq)

Question 13

How soluble are the Group 2 hydroxides?

Answer 13

They are only slightly soluble in water so when the solution becomes saturated, any further metal and OH- ions form a solid precipitate
e.g. Ca2+(aq) + 2OH-(aq) = Ca(OH)2(s)

Question 14

How does the solubility of the Group 2 hydroxides change down the group?

Answer 14

• The solubility of the hydroxides in water increase down the group
• Therefore, the resulting solutions contain more OH- ions and are more alkaline

Question 15

What is the pH of Mg(OH)2 solution and why?

Answer 15

Roughly 10 - it is very slightly soluble, therefore the solution has a low concentration of OH- ions

Question 16

What is the pH of Ba(OH)2 solution and why?

Answer 16

Roughly 13 - it is much more soluble, therefore the solution has a greater concentration of OH- ions

Question 17

What is the general trend down Group 2?

Answer 17

Solubility, pH, alkalinity and reactivity increases

Question 18

What are the two main uses of Group 2 compounds as bases (oxides, hydroxides and carbonates) and why?

Answer 18

1) Agriculture
2) Medicine
- Their basic properties and ability to neutralise acids

Question 19

How are Group 2 compounds used in agriculture?

Answer 19

Ca(OH)2 is added to fields as lime by farmers to increase the pH of acidic soils - the Ca(OH)2 neutralises the acid in the soil
- Ca(OH)2(s) + 2H+ = Ca2+(aq) + 2H2O

Question 20

How are Group 2 compounds used in medicine?

Answer 20

Group 2 bases e.g. Mg(OH)2 and CaCO3 are often used as antacids in indigestion tablets for treating acid indigestion
- the acid in your stomach is mainly HCl and Mg(OH)2 and CaCO3 help to neutralise some of the acid
e.g. Mg(OH)2(s) + HCl = MgCl2(aq) + 2H2O
CaCO3(s) + 2HCl = CaCl2(aq) +H2O + CO2

Question 21

What are the halogens?

Answer 21

Group 17/7

The most reactive non-metallic group

Question 22

How do the halogens occur on earth?

Answer 22

As stable halide ions dissolved in sea water or combined with Na/K as solid deposits

Question 23

How do the halogens exist at RTP?

Answer 23

As diatomic molecules

Question 24

What do the halogens form in their solid states?

Answer 24

Lattices with simple molecular structures

Question 25

What does fluorine look like at RTP?

Answer 25

Pale yellow gas

Question 26

What does chlorine look like at RTP?

Answer 26

Pale green gas

Question 27

What does bromine look like at RTP?

Answer 27

Red-brown liquid

Question 28

What does iodine look like at RTP?

Answer 28

Shiny grey-black solid

Question 29

Why is there an increase in the boiling point down the group of halogens?

Answer 29

• More electrons therefore stronger London forces
• Therefore more energy is required to break/overcome the intermolecular forces
• Therefore boiling point increases

Question 30

What is the general formula for the end of the electron configuration of the halogens?

Answer 30

(period number)s2(period number)p6

Question 31

Explain the electron configuration of the halogens

Answer 31

Each halogen has 7 outer shell electrons

- therefore, 2 electrons in the outer s sub-shell and 5 electrons in the outer p sub-shell

Question 32

What is the electron configuration of a halide ion?

Answer 32

[nearest noble gas]

Question 33

What happens in redox reactions of the halogens?

Answer 33

Each halogen atom is reduced, gaining one electron to form a 1- halide ion - the halogen is the oxidising agent
- e.g. Cl2 + 2e- = 2Cl-

Question 34

What do the results of halogen-halide displacement reactions show?

Answer 34

That the reactivity of halogens decreases down the group

Question 35

Describe how you would carry out a halogen-halide displacement reaction

Answer 35

1) A solution of each halogen is added to aqueous solutions of the other halides e.g. Cl2(aq) is added to Br-(aq) and I-(aq)
2) Add an organic non-polar solvent e.g. cyclohexane and shake the mixture

Question 36

Why do you add cyclohexane to the reaction mixture?

Answer 36

• Because solutions of iodine and bromine in water an appear a similar orange-brown colour
• The non-polar halogens dissolve more readily in cyclohexane than water
• In cyclohexane the colours are easier to tell apart

Question 37

What colours are bromine and iodine in cyclohexane?

Answer 37

Bromine: orange
Iodine: violet

Question 38

What are the results of the halogen-halide displacement reactions?

Answer 38

1) Chlorine reacts with BOTH Br- and I-
2) Bromine only reacts with I-
3) Iodine does not react

Question 39

What is the equation of the reaction of chlorine with bromide ions?

Answer 39

Cl2(aq) + 2Br-(aq) = 2Cl-(aq) + Br2(aq)

- Chlorine is reduced, bromine is oxidised

Question 40

Do the halogens become more or less reactive down the group?

Answer 40

Less reactive

Question 41

Why does reactivity decrease down the group of halogens?

Answer 41

1) In redox reactions, halogens react by gaining an electron
2) Down the group, atomic radius increases
3) There are more inner shells so therefore shielding increases
4) Therefore there is less nuclear attraction between the nucleus and the outer shell to capture an electron from another species
5) Therefore down the group, reactivity decreases and the halogens become weaker oxidising agents

Question 42

Why don’t we really consider fluorine and astatine?

Answer 42

Fluorine is very reactive with almost any substance it comes into contact with
Astatine is very rare because it is radioactive and decays rapidly

Question 43

What is a disproportionation reaction?

Answer 43

A redox reaction in which the same element is both oxidised and reduced
e.g. chlorine + water/cold, dilute NaOH

Question 44

Describe the disproportionation reaction of chlorine and water

Answer 44

• When small amounts of chlorine are added to water, a disproportionation reaction takes place
• For each chlorine molecule, one atom is oxidised and the other is reduced
• Cl2(aq) + H2O = HClO(aq) + HCl

Question 45

What is the oxidation number of chlorine in HClO?

Answer 45

+1

Question 46

What is the name of HClO?

Answer 46

Chloric (I) acid

Question 47

What kills the bacteria, if not chlorine?

Answer 47

Chloric (I) acid and chlorate (I) ions (ClO-)

Question 48

What is chloric acid?

Answer 48

A weak bleach (bleaches indicator paper after turning it red)

Question 49

What is the disproportionation reaction of chlorine with water limited by?

Answer 49

The low solubility of chlorine in water

Question 50

What makes the chlorine more soluble?

Answer 50

If the water contains dissolved NaOH, much more chlorine dissolves

Question 51

Describe the disproportionation reaction of chlorine and NaOH

Answer 51

Cl2(aq) + 2NaOH(aq) (cold and dilute) = NaClO(aq) + NaCl(aq) + H2O
- The resulting solution contains a large concentration of ClO- ions

Question 52

What is the name of NaClO?

Answer 52

Sodium chlorate (I)

Question 53

What is NaClO used as?

Answer 53

Household bleach

Question 54

What is the main use of chlorine?

Answer 54

In water purification (sterilisation)
- It is used as a disinfectant for drinking water treatment so reduces the incidence of water-borne diseases as it kills harmful bacteria

Question 55

What are the risks of chlorine use?

Answer 55

1) Chlorine is an extremely toxic gas
2) It is a respiratory irritant in small concentrations and in large concentrations it can be fatal
3) Chlorine in drinking water can react with organic hydrocarbons e.g. methane, formed from decaying vegetation - the chlorinated hydrocarbons formed are suspected of causing cancer

Question 56

What are the benefits of chlorine use?

Answer 56

1) It ensures that our water is fit to drink and that bacteria are killed - without chlorine, the quality of drinking water would be compromised and diseases e.g. typhoid and cholera might break out
2) Safe drinking water is essential - first concern after natural disasters
3) Therefore the benefits outweigh the risks

Question 57

Describe the precipitation reactions of halide ions

Answer 57

• Aqueous halide ions react with aqueous silver ions to form precipitates of silver halides
• Ag+(aq) + X(aq) = AgX(s)
• This reaction forms the basis for a test for the presence of halides