Scalable and Stable Ferroelectric Non-Volatile Memory at > 500 ^

Abstract

Non-volatile memory (NVM) devices that reliably operate at temperatures above 300 are currently non-existent and remains a critically unmet challenge in the development of high-temperature (T) resilient electronics, necessary for many emerging, complex computing and sensing in harsh environments. Ferroelectric AlxSc1-xN exhibits strong potential for utilization in NVM devices operating at very high temperatures (> 500 ) given its stable and high remnant polarization (PR) above 100 μC/cm2 with demonstrated ferroelectric transition temperature (TC) > 1000 . Here, we demonstrate an Al0.68Sc0.32N ferroelectric diode based NVM device that can reliably operate with clear ferroelectric switching up to 600 with distinguishable On and Off states. The coercive field (EC) from the Pulsed I-V measurements is found to be -5.84 (EC-) and +5.98 (EC+) (+/- 0.1) MV/cm at room temperature (RT) and found to decrease with increasing temperature up to 600 . The devices exhibit high remnant polarizations (> 100 μC/cm2) which are stable at high temperatures. At 500 , our devices show 1 million read cycles and stable On-Off ratio above 1 for > 6 hours. Finally, the operating voltages of our AlScN ferrodiodes are < 15 V at 600 which is well matched and compatible with Silicon Carbide (SiC) based high temperature logic technology, thereby making our demonstration a major step towards commercialization of NVM integrated high-T computers.