Filamentary Transport and Thermoelectric Effects in Mushroom Phase Change Memory Cells

Abstract

We performed a 2D finite-element electrothermal computational study of thermoelectric effects and filamentary electronic transport in Ge2Sb2Te5 mushroom phase change memory cells during Reset and Set operations, accounting for spatial activation energy variations in amorphous Ge2Sb2Te5 and phase-change dynamics. Reset operations with current going from the top electrode to the narrow 4 nm bottom electrode require 3x less energy and power, and 2x lower current to achieve the same Reset resistance, compared to the opposite polarity, due to thermoelectric effects. Filamentary conduction, electrical breakdown, thermal runaway, and local crystallization of amorphous Ge2Sb2Te5 depend on current polarity and thermal boundary conditions, and determine the location, shape, and volume of the programming region, which may be significantly smaller than the semi-cylindrical mushroom region. The programming volume does not scale with contact dimensions larger than 10 nm. Larger contact areas introduce increased device-to-device and cycle-to-cycle variability due to filamentary conduction but are expected to lead to higher reliability and endurance.