Ferroelectric switching of electronic properties at the picoscale: theory and computation

Abstract

Progress in the synthesis and theory of complex oxides now allows the design and realization of complex-oxide-ferroelectric heterostructures in which phase transitions in the complex oxide can be induced, through change in carrier concentration and direct atomic-scale coupling across the interface, when the ferroelectric is switched by an applied electric field. The picoscale atomic and electronic reconstructions with switching thus determine the two-state behavior of this class of devices, which we refer to as ~PicoFET~s. In this project, we combine the expertise in oxide MBE and relevant characterization of experimentalist Charles Ahn at Yale with the approaches to first-principles materials design and modeling of functional materials and heterostructures developed by theorist Karin Rabe at Rutgers. In this tightly-integrated experimental-theoretical collaboration, we will focus on understanding and optimizing the performance of PicoFETs and related devices by choice of materials and termination, with first-principles results and analysis of the underlying mechanisms informing and being informed by synthesis and characterization of carefully selected prototype systems.

Document Details

Document Type

DoD Grant Award

Publication Date

Feb 07, 2019

Source ID

N000141912073

Entities

Tags