ES bdefghijk: Properties of the halogens; oxidation states; redox

Question 1

The halogens are the most reactive non-metal group; none are found in elemental form.

State the trends in the following properties of the halogens, going down the group:

• Reactivity/electronegativity
• Colour
• Melting/boiling point

Answer 1

• Reactivity/electronegativity decreases
• Colours darken
• Melting/boiling points increase (volatility decreases)

Question 2

Which type of intermolecular bonding occurs between halogen molecules?

Answer 2

Instantaneous dipole-induced dipole interactions.

Otherwise known as dispersion or London forces (named after German physicist Fritz London)

Question 3

Why do the melting/boiling points of the halogens increase down the group?

Answer 3

• More electrons per molecule
• Stronger instantaneous dipole-induced dipole intermolecular forces
• Require more energy to overcome

Question 4

Why is fluorine more reactive than chlorine?

Answer 4

• Outer shell closer to nucleus (less sheilding)
• Electrostatic attraction stronger
• Accepts an electron more readily to fill its outer shell

Question 5

What are the colours and physical states at room temperature of each diatomic compound?

• fluorine
• chlorine
• bromine
• iodine

Answer 5

• Fluorine: yellow gas
• Chlorine: green gas
• Bromine: red liquid (volatile)
• Iodine: grey solid (sublimes to purple vapour)

Question 6

What colour is gaseous bromine?

Answer 6

Red-brown.

Question 7

How do the halogens behave when added to water?

Answer 7

• Fluorine reacts with water
• Others are sparingly soluble (more so in organic solvents)

Question 8

What are the colours of solutions of the following halogens in water?

• Chlorine
• Bromine
• Iodine

Answer 8

• Chlorine = pale green
• Bromine = orange-brown
• Iodine = brown

Trend down group is colours darkening; same here.

Question 9

What are the colours of solutions of the following halogens in cyclohexane?

• Chlorine
• Bromine
• Iodine

Answer 9

• Chlorine = pale green
• Bromine = orange-brown
• Iodine = violet

Trend down group is colours darkening; same here.

Question 10

When cyclohexane is added to aqueous solutions of halogens, which solvent forms the upper layer?

Answer 10

Cyclohexane upper layer

Question 11

What would you add to a halide solution to precipitate it?

Answer 11

Solution of silver ions, typically silver nitrate (AgNO₃)

Ag⁺ + X^- → AgX

Question 12

What are the colours of the silver halides:

• Silver chloride
• Silver bromide
• Silver iodide?

Answer 12

• Silver chloride = white
• Silver bromide = cream
• Silver iodide = yellow

Trend down group is colours darkening; same here.

Question 13

What are the appearances of the following silver halides in ammonia?

• Silver chloride
• Silver bromide
• Silver iodide

Answer 13

• Silver chloride = colourless (completely dissolved)
• Silver bromide = cloudy (partially dissolved)
• Silver iodide = opaque (insoluble precipitate)

Question 14

How is bromine extracted from dissolved bromide ions in the lab?

Answer 14

Cl₂ solution added to Br^- solution + displaces bromine.

Question 15

In one method of manufacturing bromine from sea water:

1. Cl₂ is bubbled through sea water to produce Br₂
2. Steam is blown through to produce Br₂ vapour
3. Vapour is mixed w/ SO₂ + passed into water
4. Steam + Cl₂ are blown through to release Br₂ from HBr
5. Br₂ is dried using conc. H₂SO₄

• ​Which property of the halogens do steps 1 and 4 illustrate?
• Suggest why it is necessary to produce bromine in 1 and again in 4

Answer 15

• Chlorine is a better oxidising agent than bromine so displaces it
• Br₂ produced in step 1 is too dilute

Question 16

In one method of manufacturing bromine from sea water:

1. Cl₂ is bubbled through sea water to produce Br₂
2. Steam is blown through to produce Br₂ vapour
3. Vapours are condensed - 2 layers form
4. Dense Br₂ layer is run off from H₂O layer
5. Impure Br₂ is distilled + dried

• ​Explain why 2 layers form in step 3
• State and explain which is the upper layer in step 4

Answer 16

• Bromine has a low solubility in water
• H₂O is upper layer since bromine is denser

Question 17

Which properties of bromine make it possible to separate it from:

• Water
• Chlorine?

Answer 17

• Sparingly soluble in water, so higher density bromine layer forms. Can be run off from water, which floats on top
• Different melting points, so can be separated by distillation

Question 18

Typical oxidation state of aluminium

Answer 18

+3

Question 19

When is oxygen’s oxidation state not -2?

Answer 19

• When combined with F
• When in peroxide, H₂O₂

Question 20

When are the halogens’ oxidation states not -1?

Answer 20

• Cl: combined with O / F
• Br: combined with O / F / Cl
• I: combined with O / F / Cl / Br

Question 21

When is hydrogen’s oxidation state not +1?

Answer 21

When in metal hydrides, e.g. NaH

Question 22

Name the 2 ions:

• CrO₄^2-
• VO₃^-

Answer 22

• Chromate(VI)
• Vanadate(V)

Question 23

Both of the following chlorates have charge 1-. Write the formula for them.

• Potassium chlorate(III)
• Sodium chlorate(V)

Answer 23

• KClO₂^-
• NaClO₃^-

Question 24

Give the systematic name of:

• HClO
• KIO₃

Answer 24

• Chloric(I) acid
• Potassium iodate(V)

Question 25

Write the balanced equation for the following reaction:

H⁺ + I^- + H₂SO₄ → H₂S + H₂O + I₂

Answer 25

Balance ox states:

H⁺ + I^- + H₂SO₄ → H₂S + H₂O + I₂

H: remains +1

I: -1 → 0 (loses 1 e^-)

S: +6 → -2 (gains 8 e^-)

O: remains -2

H⁺ + 8I^- + H₂SO₄ → H₂S + H₂O + 4I₂

1 H₂SO₄ gains e^- from 8 I^-, forming 4 I₂ and 1 H₂S.

Balance rest: (what isn’t involved in redox)

8H⁺ + 8I^- + H₂SO₄ → H₂S + 4H₂O + 4I₂

Question 26

Write the balanced equation for the following reaction:

Br^- + H⁺ + H₂SO₄ → Br₂ + SO₂ + H₂O

Answer 26

Balance ox states:

Br^- + H⁺ + H₂SO₄ → Br₂ + SO₂ + H₂O

Br: -1 → 0 (loses 1 e^-)

H: remains +1

S: +6 → +4 (gains 2 e^-)

O: remains -2

2Br^- + H⁺ + H₂SO₄ → Br₂ + SO₂ + H₂O

Balance charge + rest: (what isn’t involved in redox)

2Br^- + 2H⁺ + H₂SO₄ → Br₂ + SO₂ + 2H₂O

Question 27

Balance and complete this equation:

Br₂ + SO₂ + 2H₂O → HBr + ___

Answer 27

Br₂ + SO₂ + 2H₂O → HBr + ___

Balance ratio:

Br₂ + SO₂ + 2H₂O → 2HBr + ___

Deduce other product:

4 oxygens, 2 Hs + 1 S unaccounted for:

Br₂ + SO₂ + 2H₂O → 2HBr + H₂SO₄

(Optional) Check with ox states:

Ox state of S in H₂SO₄ = +6

Br: 0 → -1 (so Br₂ gains 2 e^-)

S is only species which can be oxidised (constant ox states of O + H)

S: +4 → +6 QED