Abstract

Porous zinc tin sulfide aerogel materials were constructed by metathesis reactions between Zn(acac)2·H2O and tetrahedral thiostannate cluster salts containing discrete [SnS4]4-, [Sn2S6]4-, and [Sn4S10]4- units. Self-assembly reactions of the Zn2+ linker and anionic thiostannate clusters yielded polymeric random Zn/Sn/S networks with gelation properties. Supercritical drying of the gels and solvent/counterion removal resulted in a metal sulfur framework. Zn2SnxS2x+2 (x = 1, 2, 4) aerogels showed high surface areas (363−520 m2/g) and pore volumes (1.1−1.5 cm3/g), and wide bandgap energies (2.8−3.2 eV). Scanning and transmission electron microscopy studies show the pores are micro- (d < 2 nm), meso- (2 nm < d < 50 nm), and macro- (d > 50 nm) regions. The zinc chalcogenide aerogels also possess high affinities toward soft heavy metals and reversible absorption of strong electron-accepting molecules.