Cations of Group II PDF

Summary

This document provides detailed information about the identification of cations group II. It explains the procedures involved in identifying and separating metal ions through chemical reactions, including the use of reagents like hydrogen sulfide and different tests to confirm the presence of specific metal ions.

Full Transcript

Cations of Group II
 Cations Group I brings together eight cations that subdivided into
the copper group consisting of (mercuric, bismuth, cadmium, copper
and lead)
and the arsenic group consisting of (arsenic, antimony and tin)
 The group reagent is hydrogen sulphide in acid medium (0.3 M
HCl).

 The subdivision to II-a and II-b subgroups is based on:
The solubility in excess of sodium sulphide Na2S or Sodium
Hydroxide NaOH to form thioanions and oxyanions.

20
Cations of Group II
 The group reagent is hydrogen sulphide in acid medium (0.3 M
HCl).
The real significance of the [H+] as a control of [S2-] can be seen
by examining the ionization of H2S.

Due to common ion effect,
 Increasing the concentration of H+ ions in solution of H2S in water, shift
the equilibrium to the left, that decrease the sulphide ion concentration.
 Addition of strong base shifts this equilibrium to the right with a
resultant increase the [S2-].

21
Cations of Group II
 The metal will precipitate when the product of [M2+] and [S2-] exceeds
the solubility product. This means that the limiting factor in precipitation
is the sulphide ion concentration which is controlled by the pH (the
hydrogen ion conc.).

 Therefore, to precipitate cations of group II (having lower solubility
product than those of group IIIB), we need relatively small amount of
sulphide ion.

 If the [H+ ] is controlled to become 0.3 M, the [S2-] will be 1.5 x
10-19 M. This is sufficient to precipitate the sulphides of the
elements of cation group II only.

22
Cations of Group II
Adjustment of the acidity
An increase in [S2-] by decreasing the acidity (< 0.3 M HCl) results
in:
 a) Precipitation of sulphides of group IIIB.
 b) Dissolution of sulphides of group IIB as thioanions (see group IIB).

A decrease in [S2-] by increasing the acidity (> 0.3 M HCl) results
in :
 a) Prevention of the precipitation of CdS, PbS, SnS2 (have higher solubility
products).
 b) Formation of stable soluble complexes as [CdCl4]2-, [SnCl62-], [SbCl4]-,
so they cannot precipitate by addition of H2S.

23
Cations of Group II

24
Cations of Group II
 N.B. :

 (1) Unless Hg2+ is an element of group IIA, but it appears in both IIA and
IIB subgroups because its precipitate HgS in group IIA is partially soluble
in alkali sulphide (Na2S) and pass with group IIB

 (2) Stannous sulphide SnS is incompletely soluble in either NaOH or
Na2S. Therefore, to separate stannous with the subgroup IIB cation
sulphides, we have to oxidize stannous (Sn2+) to stannic (Sn4+) by boiling
with hydrogen peroxide.

 The excess H2O2 must be decomposed by boiling, otherwise it will
oxidize the H2S reagent to colloidal sulphur which is difficult to separate.

25
Cations of Group II
Group II A
 Mercuric Hg2+

 Bismuth Bi3+

 Copper Cu2+

 Cadmium Cd2+

 Lead Pb2+

26
Cations of Group II (A)
1- Mercuric (II) ion (Hg2+)
 Group Precipitation
0.3 M H+
Hg2+ + H2S ↔ HgS ↓ Black

Confirmatory Test
With ammonium hydroxide
HgCl2 + 2 NH4OH ↔ Hg (NH2)Cl↓
white mercuric amino chloride
With Stannous chloride (SnCl2)
HgCl2 + SnCl2 → Hg2Cl2 ↓ white + [SnCl6]2-
Hg2Cl2 + xss SnCl2 → Hgo ↓ black + [SnCl6]2-

With potassium iodide (KI)
Hg2+ + KI ↔ HgI2 ↓ Scarlet Red
HgI2 ↓ + xss KI ↔ [HgI4]2- soluble complex
27
Cations of Group II (A)
2- Bismuth (III) ion (Bi3+)
 Group Precipitation
0.3 M H+
Bi3+ + H2S ↔ Bi2S3 ↓ dark brown

Confirmatory Test
With excess water (Oxysalt formation)
BiCl3 + H2O ↔ BiOCl ↓ + 2H+
large xss white turbidity
bismuth oxychloride
With Sodium Stannite ([HSnO2]-)
Bi3+ reacts with Sodium Stannite fresh solution (prepared by
reaction of stannous chloride with xss NaOH till dissolution of the
formed white ppt)
Bi3+ + [HSnO2]- ↔ Bio ↓ black + [SnCl6]2-

28
Cations of Group II (A)
3- Copper (II) ion (Cu2+)
 Group Precipitation
0.3 M H+
Cu2+ + H2S ↔ CuS ↓ black

Confirmatory Test
With ammonium hydroxide
Cu2+ + 4 NH4OH ↔ [Cu(NH3)4]2+ deep blue colour

With potassium iodide (KI)
Cu2+ + KI ↔ Cu2I2 ↓ + I2
White Brown
Cuprous iodide
With potassium ferrocyanide [Fe(CN)6]4-
HAC
Cu2+ + [Fe(CN)6]4- ↔ Cu2[Fe(CN)6]↓
Chocolate brown
29
Cations of Group II (A)
4- Cadmium (II) ion (Cd2+)
 Group Precipitation
0.3 M H+
Cd2+ + H2S ↔ CdS ↓ yellow

Confirmatory Test
With ammonium hydroxide
CdS is insoluble in excess S2- and in NaOH

30
Cations of Group II
Group II B
 Arsenious As3+

 Arsenic As5+

 Antimonous Sb3+

 Antimonic Sb5+

 Stannic Sn4+

31
Cations of Group II
Group II B
Group II is boiled with H2O2, the acidity is adjusted at 0.3 M HCl and H2S
or thioacetamide is added, the following sulphide precipitates of subgroup
IIB are formed.
 Arsenious As3+ → As2S3 yellow
 Arsenic As5+ → As2S5 yellow
 Antimonous Sb3+ → Sb2S3 orange
 Antimonic Sb5+ → Sb2S5 orange
 Stannic Sn4+ → SnS2 brown

These precipitates are soluble in NaOH or Na2S (separation of
subgroups IIA & IIB)

32
Cations of Group II (B)
1- Arsenious (III) ion and Arsenic (V) ion,
As3+, As5+
 Group Precipitation
0.3 M H+
2As3+ + 3H2S ↔ As2S3 ↓ yellow
2As5+ + 5H2S ↔ As2S5 ↓ yellow

 Confirmatory Test
Soluble in xss Na2S or in NaOH

33
Cations of Group II (B)
1- Arsenious (III) ion and Arsenic (V) ion,
As3+, As5+

Discard

The arsenious sulphide and arsenic sulphide are insoluble in 12 M HCl (differ from
sulphides of antimony and tin), but by boiling they are partially soluble. Then
arsenious sulphide and arsenic sulphide are dissolved by conc HNO3

34
Cations of Group II (B)
1- Arsenious (III) ion and Arsenic (V) ion,
As3+, As5+
Confirmatory Test
After dissolution with conc. HNO3 on H3AsO4
Ammonium molybdate Test

35
Cations of Group II (B)
2- Antimonous (III) ion and Antimonic (V)
ion , Sb3+, Sb5+
 Group Precipitation
0.3 M H+
2Sb3+ + 3H2S ↔ Sb2S3 ↓ orange
2Sb5+ + 5H2S ↔ Sb2S5 ↓ orange
 Confirmatory Test

Soluble in xss Na2S or in NaOH to form thio and oxyanions

36
Cations of Group II (B)
2- Antimonous (III) ion and Antimonic (V)
ion , Sb3+, Sb5+
Confirmatory Test
After dissolution with 12M HCl
Oxysalt formation

Sodium thiosulphate Test

37
Cations of Group II (B)
2- Antimonous (III) ion and Antimonic (V)
ion , Sb3+, Sb5+
 Confirmatory Test
After dissolution with 12M HCl
Test for Sb3+ in presence of Sn4+
Addition of oxalic acid which forms two complexes with Sb3+ and Sn4+. The
complex with Sn4+ is stable, while that with Sb3+ is unstable, so on passing
H2S, orange ppt of Sb2S5 is formed.

38
Cations of Group II (B)
3- Stannic (IV) Ion Sn4+
 Group Precipitation
0.3 M H+
Sn4+ + 2H2S ↔ SnS2 ↓ brown
 Confirmatory Test
Soluble in xss Na2S or in NaOH to form thio and oxyanions

Test for Sn4+ in presence of Sb3+
We have to boil with iron wire (Feo) in acid medium for two reasons:

Then Sn2+ react with HgCl2

39
Cations of Group II (B)
3- Stannic (IV) Ion Sn4+
Then Sn2+ react with HgCl2
The test may give white ppt (Hg2Cl2) or grey ppt (Hg2Cl2 + Hgo) or finally
black ppt (Hgo) (oxidation-reduction reaction).

40