IBM / Cambridge University Press / John Wiley and Sons / /
Country
United States / United Kingdom / / /
Facility
University of Oklahoma Graduate College / University of Oklahoma / The University of Oklahoma / /
IndustryTerm
fermionic systems / actual device / energy conservation / room-temperature device / lowest subband energy / junction devices / electron gas / characteristic energy / low-energy electrons / simplest such device / confinement energy / electronic chemical potential / plus-junction device / semiconductor devices / energy flux / given device / energy passes / chemical potential / higher-energy subband scatter / mesoscopic solid-state device / gas phase transitions / thermal energy / T-junction device / higher-energy electrons / dimensionless total electron energy / higher-energy states / input-lead chemical potential / threshold energy / energy difference / longitudinal kinetic energy / chemical potentials / electron energy / energy / chemical potential equal / subband energy / high-energy electrons / prototype device / accessible low-energy / kinetic energy / incident energy / quantum-wire device / large chemical potentials / potential energy / approximate solution / electronic devices / quantum device / photodetection applications / analytic solution / energy-flux integrals / output-lead chemical potential / /
OperatingSystem
Fermi / /
Organization
Cambridge University / University of Oklahoma / U.S. National Science Foundation / Michael A. Morrison* Homer L. Dodge Department of Physics and Astronomy / U.S. Securities and Exchange Commission / Oklahoma Graduate College / /
Person
Gregory L. Snider / Homer L. Dodge / K. Mullen / Thushari Jayasekera / Kieran Mullen / Mark S. Miller / Herbert H. Callen / Michael A. Morrison / Evelyn L. Hu / /