The Periodic Table
The organisation of elements in the Periodic Table according to their proton numbers and electronic structures. The terms group and period. The trends in the physical properties across the period sodium to argon limited to melting points, electrical conductivity, first ionisation energies and atomic radii.
Group VII (fluorine, chlorine, bromine and iodine)
Practical work restricted to chlorine, bromine and iodine and their compounds.
Trends within the group limited to colour, physical state, melting and boiling points, atomic and
ionic radii, first ionisation energies, bond energies of halogen molecules, hydrogen halides and carbon-halogen bonds; electronegativies.
GROUP VII Halogen
(Halogens : restricted to chlorine, bromine and iodine)
Valid deductions may be expected about other elements in the group.
Physical properties of halogens, limited to colour and physical state at room temperature.
The halogens are a group of reactive non-metals, which are essentially similar to each other with only gradual changes as the atomic number increases.
Physical properties of the halogens
Property
Fluorine
F
Chlorine
Cl
Bromine
Br
Iodine
I
Number of protons
(atomic number)
9
17
35
53
Outer electron configuration
2s22p5
3s23p5
3d104s24p5
4d105s25p5
Atomic radius/ nm
0.064
0.099
0.111
0.128
Ionic radius/ nm
0.133
0.181
0.196
0.219
Melting point / oC
-220
-101
-7
114
Boiling point / oC
-188
-34
58
183
Bond energy /
kJ mol-1
158
242
193
151
Electron affinity/ kJ mol-1
-361
-388
-365
-332
Standard electrode potential/ V
+2.87
+1.36
+1.09
+0.54
Electronegativity
4.00
2.85
2.75
2.20
Oxidation states
- 1
-1,1,3,5,7
-1,1,3,5,7
-1,1,3,5,7
Standard enthalpy of formation of NaX/ kJ mol-1
-573
-414
-361
-288
Standard lattice enthalpy of NaX/ kJ mol-1
902
771
733
684
They are all p-block elements with a simple molecular structure consisting of covalently bonded diatomic molecules, X2.
o o o o
o o o
o X o X o X X
o o o o
There are only weak Van der Waals forces between the molecules. The strength of the forces increases as the number of electrons (Mr) in the molecule increases.
F2<> Br2 > I2 as the atoms get larger and the attraction of the nucleus for the shared electrons decreases (electronegativity decreases).
There is a slight tendency to metallic character with increasing atomic number. The halogens complete their octet by gaining one electron forming a halide ion, X- (see electron affinity values) or by sharing one electron. Fluorine is restricted to an oxidation state of -1 but the remaining elements have empty d orbitals and can promote electrons to give oxidation states of +1, +3, +5 and +7.
They are all oxidising agents and combine readily with metals and hydrogen.
Chlorine is a greenish-yellow gas.
Bromine is a red-brown volatile liquid.
Iodine is a black shiny solid, which sublimes on heating to produce a purple vapour.
Solubility in water and non-aqueous solvents eg hexane.
Chemical trends: reactivity with hydrogen, sodium and phosphorus.
Reactions of the elements illustrated by use of chlorine gas (or chlorine water), bromine water and aqueous iodine (in potassium iodide) with water, aqueous alkalis, other halides in solution and iron (11) and iron (111) ions as appropriate.
Disproportionation.
Reaction of halides with elements
Metals
The halogens combine readily with most metals forming the metal halides.
The vigour of the reaction decreases from chlorine to iodine.
Group I and II halides are ionic.
2Na (s) + Cl2 (g) 2Na+Cl- (s)
Mg (s) + Cl2 (g) Mg2+2Cl- (s)
The halides of Group III are predominantly covalent.
2Al (s) + 3Cl2 (g) 2AlCl3 (s)
Non-metals
The elements react directly with many non-metals the oxidising power decreasing from chlorine to iodine.
The elements combine directly with phosphorus, the oxidation state of the product depending on the oxidising power of the halogen.
2P (s) + 5Cl2 (g) 2PCl5 (s)
2P (s) + 3Br2 (l) 2PBr3 (l)
Solubility of the elements
All three elements are only slightly soluble in water because of the relatively strong hydrogen-bonding between the water molecules, which does not exist between the halogen molecules
i.e. solvent-solvent attractions > solute-solvent attractions > solute-solute
attractions.
Cl2> Br2>I2
solubility decreasing
They are soluble in non-polar organic solvents such as toluene and TCE.
(Why?)
Chlorine reacts slowly with water forming hydrochloric acid and chloric(I) acid. This reaction involves disproportionation:- a change in which one particular molecule, atom or ion is simultaneously both oxidised and reduced.
reduction
Cl2 (g) + H2O (l) HCl (aq) + HClO (aq) (chlorine water)
o.n. 0 -1 +1
oxidation
Bromine and iodine disproportionate in a similar way but to a lesser extent.
Reaction of chlorine with aqueous sodium hydroxide.
Chlorine reacts faster with dilute sodium hydroxide than with water.
When chlorine is added to cold dilute alkali it disproportionates to chloride and chlorate(l).
(i) reduction
Cl2 (g) + 2NaOH (aq) NaCl (aq) + NaOCl (aq) + H2O
o.n. 0 -1 +1
oxidation
( 2OH- + Cl2 Cl- + OCl- + H2O )
(ii) In hot concentrated alkali, if the solution is warmed to 70oC, the chlorate(I) disproportionates further to chlorate(V).
reduction
3NaOCl (aq) 2NaCl (aq) + NaClO3 (aq)
o.n. +1 -1 +5
oxidation
If chlorine is bubbled directly into hot conc. alkali then
(iii) reduction
3Cl2 (g) + 6NaOH(aq) 5NaCl (aq) + NaClO3 (aq)
o.n. 0 -1 +5
oxidation
( 6OH- + 3Cl2 5Cl- + ClO3- + 3H2O )
For bromine, both reactions (i) and (ii) are fast at 15oC.
For iodine, decomposition of IO- occurs rapidly at 0oC so it is difficult to prepare NaIO free from NaIO3.
NaClO is a mild antiseptic (Milton).
NaClO3 powerful weed killer.
Thermal stability of hydrogen halides related to bond enthalpies. The relative strength of the acids, HF, HCI, HBr and HI.
Ionic halides. The identification of halide ions in solution by use of silver ions followed by aqueous ammonia. The effect of light on silver halides. Presence of halide ions in sea water. The reaction of solid halides with concentrated sulphuric acid to illustrate the relative reducing ability of halides ions and hydrogen halide. The effects of fluoridation of public water supplies on dental health and an appreciation of the debate between public health policy and practice and the rights of the individual.
Reaction of the halide ions in solution, X-(aq)
Most metal halides are soluble except lead and silver halide. Therefore solutions of lead and silver ions are used to test for the presence of halide ions in solution.
Reagent
F- (aq)
Cl- (aq)
Br- (aq)
I- (aq)
Pb(NO3)2 (aq)
Pb2+(aq) + 2X-(aq) PbX2(s)
White precipitate of PbF2
White precipitate of PbCl2
Cream precipitate of PbBr2
Yellow precipitate of PbI2
AgNO3 (aq)
Ag+ (aq) + X- (aq) AgX (s)
No reaction AgF soluble in water
White precipitate AgCl
Cream precipitate AgBr
Yellow precipitate AgI
Solubility of silver halide in
(a) dil. NH3 (aq)
(b) conc. NH3
(c) dil.HNO3 (aq)
soluble
soluble
insoluble
insoluble soluble
insoluble
insoluble insoluble
insoluble
Effect of sunlight
White ppt. turns purple/grey
Cream ppt. turns green/ yellow
No effect
Exercise 2
Write an equation for the reaction of sodium chloride solution with
(a) lead nitrate solution and
(b) silver nitrate solution followed by the addition of ammonia.
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