Contact
A major obstacle for future progress in microelectronics is reducing power consumption. Devices that exploit the electron spin degree of freedom together with, or instead of, its charge, provide a pathway to meet this challenge. Solid-state spin-based devices have already entered the marketplace for nonvolatile memory applications, and the door to broader computing applications is now open. In this talk I will describe recently-discovered mechanisms, materials, and devices that offer a spin-based approach to augment conventional electronics as current technologies approach the end of their roadmap.
New architectures for computation offer performance advantages for specific applications such as optimization and machine learning. In this talk, I will discuss the potential benefits of spintronics, with a focus at the system level. Collective switching of multiple spins promises to reduce the power delay product relative to conventional field effect transistors. But spintronic phenomena can also be exploited to realize novel devices such as programmable nonlinear function evaluators and coupled oscillators, providing potential benefits beyond traditional von Neumann architectures.
Securrency: Infrastructure technology for compliance and interoperability among legacy and blockchain systems
M10: Global FMI Modernization