Relation between resistance drift and optical gap in phase change materials

TL;DR

This paper investigates the relationship between resistance drift and optical gap in phase change materials, linking electronic, structural, and optical properties through theoretical analysis and spectroscopy to enable optical quantification of resistance drift.

Contribution

It introduces a theoretical framework connecting optical gap, crystalline field, and resistance drift, providing a novel optical method to assess resistance drift in phase change materials.

Findings

Optical gap relates to crystalline-field energy and activation energy.

Spectroscopy indicates oscillator energy dominates optical properties.

Theoretical estimates match experimental data for structural phases.

Abstract

The optical contrast in a phase change material is concomitant with its structural transition. We connect these two by first recognizing that Friedel oscillations couple electrons propagating in opposite directions and supply an additional Coulomb energy. As the crystal switches phase, this energy acquires time dependence and the Landau-Zener mechanism operates, steering population transfer from the valence to the conduction band and vice versa. Spectroscopy suggests that the oscillator energy dominates the optical properties and a calculation involving the crystalline field and spin-orbit interaction yields good estimates for of both structural phases. Further analysis relates the optical gap with the crystalline-field energy as well as activation energy for electrical conduction. This last property characterizes the amorphous phase, thereby furnishing a link between the crystalline field and the activation energy and ultimately with the resistance drift exponent. Providing optical means to quantify resistance drift in PCMs could circumvent the need for fabricating expensive devices and performing time consuming measurements.