posted on 2018-06-29, 00:00authored bySaiful
M. Islam, Lintao Peng, Li Zeng, Christos D. Malliakas, Duck Young Chung, D. Bruce Buchholz, Thomas Chasapis, Ran Li, Konstantinos Chrissafis, Julia E. Medvedeva, Giancarlo G. Trimarchi, Matthew Grayson, Tobin J. Marks, Michael J. Bedzyk, Robert P. H. Chang, Vinayak P. Dravid, Mercouri G. Kanatzidis
The
phase-change (PC) materials in the majority of optical data
storage media in use today exhibit a fast, reversible crystal →
amorphous phase transition that allows them to be switched between
on (1) and off (0) binary states. Solid-state inorganic materials
with this property are relatively common, but those exhibiting an
amorphous → amorphous transition called polyamorphism are exceptionally rare. K2Sb8Se13 (KSS) reported here is the first example of a material that has
both amorphous → amorphous polyamorphic transition and amorphous
→ crystal transition at easily accessible temperatures (227
and 263 °C, respectively). The transitions are associated with
the atomic coordinative preferences of the atoms, and all three states
of K2Sb8Se13 are stable in air at
25 °C and 1 atm. All three states of K2Sb8Se13 exhibit distinct optical bandgaps, Eg = 1.25, 1.0, and 0.74 eV, for the amorphous-II, amorphous-I,
and crystalline versions, respectively. The room-temperature electrical
conductivity increases by more than 2 orders of magnitude from amorphous-I
to -II and by another 2 orders of magnitude from amorphous-II to the
crystalline state. This extraordinary behavior suggests that a new
class of materials exist which could provide multistate level systems
to enable higher-order computing logic circuits, reconfigurable logic
devices, and optical switches.