posted on 2023-08-03, 19:03authored byHao Liu, Huang Gong, Kai Liu, Keyuan Ding, Jintao Chen, Zhaoyang Liu, Feng Rao
Ovonic threshold switching in chalcogenide glasses is
a crucial
physical phenomenon behind state-of-the-art memory chip technologies.
Binary tellurides are one of the emerging candidates that deliver
excellent properties, notably the large driving current and fast accessing
speed, for volatile selector applications; however, the underlying
switching mechanism remains poorly understood. To tackle this issue,
we targeted the prototypical boron tellurides, further elevating the
selector performances. Via ab initio simulating the electronic excitation
process in the amorphous boron tellurides, we observed reversible
semiconductor-metal transitions that can reflect the switching principles
of the selectors. The transient switching in conductance originates
from fine structural tunings, namely, the changes of constraint surrounding
the big boron clusters and conversions between covalent and hypervalent
bonding schemes throughout the entire tellurium network. Our work
provides much-needed atomistic insight into the ovonic threshold switching
mechanisms that may enlighten the material design to enable superior
selector devices.