James S. Harris
Stanford University
1152 Papers
11.1K Citations
James S. Harris is an academic researcher from Stanford University. The author has contributed to research in topics: Quantum well & Molecular beam epitaxy. The author has an hindex of 80, co-authored 1152 publications. Previous affiliations of James S. Harris include Electronics Research Center & Rockwell International.
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Papers
Growth Induced and Patterned 0-Dimensional Quantum Structures
Glenn S. Solomon,C. I. Duruöz,J. A. Trezza,R. M. Clarke,Charles Marcus,James S. Harris +5 more
- 01 Jan 1995
TL;DR: In this paper, a growth induced islanding approach is proposed to control the growth of these islands and simple optical and electronic characterization of 0-dimensionally confined quantum dot structures is presented.
Silicon Nitride Waveguide as a Power Delivery Component for Dielectric Laser Accelerators
Zhexin Zhao,Si Tan,Karel E. Urbanek,Tyler W. Hughes,Yun Jo Lee,Shanhui Fan,James S. Harris,Robert L. Byer +7 more
- 10 May 2020
TL;DR: In this article, weakly-guided silicon nitride waveguide was used to deliver sub-picosecond high power laser pulses for dielectric laser accelerators, and the damage limited deliverable fluence (0.19 J/cm2) was measured and nonlinear effects were characterized.
Tunable mid-infrared source based on difference frequency generation of a femtosecond Tm-fiber system in orientation patterned GaAs
Christopher R. Phillips,Carsten Langrock,Martin M. Fejer,J. Jiang,Ingmar Hartl,Martin E. Fermann,A. C. Lin,James S. Harris,Michael Snure,David Bliss,Miao Zhu +10 more
- 06 May 2012
TL;DR: In this paper, a mid-infrared source tunable from 6.7-12.7 μm via difference frequency generation in orientation-patterned GaAs, with 1.3 mW average output power.
Quantum interference devices fabricated using molecular-beam epitaxy and ultra-high-resolution electron-beam lithography
TL;DR: In this paper, a lateral quantum interference device (QID) was fabricated using molecular-beam epitaxy and ultra-high-resolution electron-beam lithography and the authors have observed conductance oscillations in these devices.
Enhancement of optical reflectivity of high Tc superconducting films by ion milling
TL;DR: In this paper, optical reflectivity data of several representative high Tc superconducting films before and after ion milling is reported, and it is shown that features associated with a•axis texture vanished after ion-milling, resulting in pure c•axis films.