High-Pressure Structural Evolution of Disordered Polymeric CS2

Abstract

Carbon disulfide, CS2, is an archetypal double-bonded molecular system belonging to the rich class of group IV-group VI, AB2 compounds. It is widely and since long time believed that upon compression at several GPa a polymeric chain of type (-(C=S)-S-)n named Bridgman's black polymer will form. By combining optical spectroscopy and synchrotron X-ray diffraction data with ab initio simulations, we demonstrate that the structure of the Bridgman's black polymer is remarkably different. Solid molecular CS2 undergoes a pressure-induced structural transformation at around 10-11 GPa, developing a disordered polymeric system. The polymer consists of 3-fold and 4-fold coordinated carbon atoms with an average carbon coordination continuously increasing upon further compression to 40 GPa. Polymerization also gives rise to some C=C double bonds. Upon decompression, the structural changes are partially reverted, a very small amount of molecular CS2 is recovered, while the sample undergoes partial chemical disproportionation. Our work uncovers the non-trivial high-pressure structural evolution in one of the simplest molecular systems exhibiting molecular as well as polymeric phases.