His primary scientific interests are in Optoelectronics, Quantum dot, Gallium arsenide, Quantum dot laser and Optics. His study focuses on the intersection of Optoelectronics and fields such as Absorption with connections in the field of Carrier lifetime. His studies in Quantum dot integrate themes in fields like Quantum well and Condensed matter physics.
Jamie D. Phillips combines subjects such as Self-assembly, Scanning tunneling microscope and Differential gain with his study of Gallium arsenide. His study on Grating and Plane of incidence is often connected to Planar as part of broader study in Optics. His Photodetector study combines topics from a wide range of disciplines, such as Infrared and Detector.
His scientific interests lie mostly in Optoelectronics, Quantum dot, Optics, Molecular beam epitaxy and Photoluminescence. His research in Optoelectronics intersects with topics in Thin film and Infrared. His biological study deals with issues like Dark current, which deal with fields such as Auger and Doping.
His Quantum dot study integrates concerns from other disciplines, such as Quantum well, Quantum point contact, Laser and Scanning tunneling microscope, Condensed matter physics. The various areas that Jamie D. Phillips examines in his Molecular beam epitaxy study include Solid-state physics, Pulsed laser deposition and Band gap. His Photoluminescence research incorporates elements of Luminescence, Full width at half maximum, Laser linewidth and Infrared spectroscopy.
Optoelectronics, Photovoltaic system, Optics, Photovoltaics and Electrical engineering are his primary areas of study. The study incorporates disciplines such as Infrared and Voltage in addition to Optoelectronics. The various areas that Jamie D. Phillips examines in his Photovoltaic system study include Leakage, Energy harvesting, Light intensity and Energy conversion efficiency.
His research in Optics tackles topics such as Dielectric which are related to areas like Condensed matter physics. Jamie D. Phillips has included themes like Wireless power transfer and Light-emitting diode in his Photovoltaics study. The concepts of his Band gap study are interwoven with issues in Quantum dot, Absorption, Order of magnitude and Quantum efficiency.
His main research concerns Optoelectronics, Photovoltaic system, Energy conversion efficiency, Energy harvesting and Photovoltaics. His is involved in several facets of Optoelectronics study, as is seen by his studies on Band gap and Quantum dot. His Quantum dot research includes elements of Thin film and Epitaxy.
His research investigates the connection between Photovoltaic system and topics such as Gallium arsenide that intersect with problems in Scale, Engineering physics, Chip and Millimeter. His Energy harvesting research incorporates elements of Light intensity, Electronic engineering and Capacitor. His Photovoltaics research is multidisciplinary, incorporating perspectives in Crystalline silicon, Silicon, Passivation and Leakage.
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Evaluation of the fundamental properties of quantum dot infrared detectors
Journal of Applied Physics (2002)
Far-infrared photoconductivity in self-organized InAs quantum dots
J. Phillips;K. Kamath;P. Bhattacharya.
Applied Physics Letters (1998)
Self-assembled InAs-GaAs quantum-dot intersubband detectors
J. Phillips;P. Bhattacharya;S.W. Kennerly;D.W. Beekman.
IEEE Journal of Quantum Electronics (1999)
Room-temperature operation of In0.4Ga0.6As/GaAs self-organised quantum dot lasers
K. Kamath;P. Bhattacharya;T. Sosnowski;T. Norris.
Electronics Letters (1996)
Intermediate-band photovoltaic solar cell based on ZnTe:O
Weiming Wang;Albert S. Lin;Jamie D. Phillips.
Applied Physics Letters (2009)
Absorption, carrier lifetime, and gain in InAs-GaAs quantum-dot infrared photodetectors
B. Kochman;A.D. Stiff-Roberts;S. Chakrabarti;J.D. Phillips.
IEEE Journal of Quantum Electronics (2003)
Symmetry-protected mode coupling near normal incidence for narrow-band transmission filtering in a dielectric grating
J. M. Foley;S. M. Young;J. D. Phillips.
Physical Review B (2014)
Sub-bandgap photoconductivity in ZnO epilayers and extraction of trap density spectra
K Moazzami;T E Murphy;J D Phillips;M C-K Cheung.
Semiconductor Science and Technology (2006)
ZnO thin-film transistors with polycrystalline (Ba,Sr)TiO3 gate insulators
J. Siddiqui;E. Cagin;D. Chen;J. D. Phillips.
Applied Physics Letters (2006)
Mid-wave infrared HgCdTe nBn photodetector
Anne M. Itsuno;Jamie D. Phillips;Silviu Velicu.
Applied Physics Letters (2012)
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