414 THE TRANSITION ELEMENTS
Oxidation state +1In contrast to the +2 state, copper(I) compounds are less frequently
coloured and are diamagnetic, as expected since the 3d level is full.
However, the copper(I) ion, unlike copper(II), is unstable in aqueous
solution where it disproportionates into copper(II) and copper(O)
(i.e. copper metal).
Consider the half-reactions in aqueous solution:Cu+(aq) + e' -> Cu(s): E* = +0.52 V
Cu^2 +(aq) + e~ -> Cu+(aq): £^ = + 0.15V
We see that the Cu+(aq) ion (in the first equation) can oxidise the
Cu+(aq) ion (in the second equation), and hence
Cu+(aq) + Cu+(aq) -> Cu + Cu^2 +(aq)i.e. 2Cu + (aq)--» Cu + Cu2+(aq), i.e. disproportionation.
In the presence of appropriate ligands, the E^ values may be
affected sufficiently to make Cu(I) stable; but since the likely aquo-
complex which Cu(I) would form is [Cu(H 2 O) 2 ]*, with only two
water ligands, the (hypothetical) hydration energy of Cu* is there-
fore much less than that of the higher charged, more strongly
Equated [Cu(H 2 O) 6 ]^2 +.Copper{I) oxide, Cu 2 O, occurs naturally as the red cuprite. It is
obtained as an orange-yellow precipitate by the reduction^of a
copper(II) salt in alkaline solution by a mild reducing agent, for
example glucose, hydroxylamine or sodium sulphite:
2Cu^2 + + SOf~ + 4OH~ -> Cu 2 Oi + SOJ- + 2H 2 OIt dissolves in oxo-acids with disproportionation, for example
Cu 2 O + H 2 SO 4 -> CuSO 4 -f Cu| -f H 2 OCopper(I) chloride, CuCl, is a white solid, insoluble in water. It is
prepared as follows:
- By warming either copper(I) oxide or a mixture of copper(II)
chloride and copper with concentrated hydrochloric acid, until a
deep brown solution is formed.
Cu 20 -f 2HC1 -» 2CuCl + H 2 OCuCl 2 -f Cu ^2CuClIn both cases the copper(I) chloride dissolves in the acid to form
the complex [CutlJ^3 ~. On pouring the brown solution into water,