3.3. Effects of di6erse ions and pr

3.3. Effects of di6erse ions and preliminary
separation
As the preparation reaction with TDTC is not
selective, most of other cationic species, if present,
should be removed in advance. DDTC was reported
to precipitative Sn(IV) over the whole pH
range of 2–14 [14]. It is surely invalid. As an analog
of TDTC, it has the same donor system, hence
should behave similarly. Our experiments confirmed
this since at pH]7 no precipitate was found.
Accordingly a preliminary group separation can be
made by precipitation with DDTC at pH 9 in the
presence of tartrate to remove at a single stroke:
Ag(I), Au(III), Bi(III), Cd(II), Co(II), Fe(III),
Hg(II), Mn(II), Ni(II), Pb(II), Sb(III), Te(IV), Tl(I)
and Zn [14]. Although the removal of Se(IV) and
Te(VI) is not quantitative, yet only a part of their
residual portions would react with TDTC under the
specified conditions [14]. Fortunately, they are
usually present in very small amounts, hence, their
interference might be ignored. The ionic species of
platinum metals, if present, would be removed also.
Once the filtrate is acidified to pH 2–6, the excess
of DDTC left would precipitate Sn(IV) immediately.
Therefore, it is advisable to overstep this pH
region by pouring the alkaline filtrate portionwise
to strong acids.
The possibly remaining species after this group
separation would be: (a) cationic species of alkali
and alkaline earth metals; (b) soluble tartrate
complexes of B(III), Be(II), Al(III) and Ti(IV). All
of them are tolerable even in macro amounts.
Interferents are Cr(III), Ga(III), In(III) [14]. They
can be masked, however, by EDTA, the excess of