James S. Horwitz focuses on Thin film, Pulsed laser deposition, Optoelectronics, Substrate and Indium tin oxide. James S. Horwitz combines subjects such as Film plane, Condensed matter physics, Electrical resistivity and conductivity and Nuclear magnetic resonance with his study of Thin film. His Pulsed laser deposition research includes elements of Epitaxy, Lattice constant, Mineralogy, Dielectric and Analytical chemistry.
His Optoelectronics research is multidisciplinary, incorporating elements of OLED and Anode. His research in Substrate intersects with topics in Light-emitting diode and Quantum efficiency. His research integrates issues of Excimer laser and Electroluminescence in his study of Indium tin oxide.
His scientific interests lie mostly in Thin film, Pulsed laser deposition, Analytical chemistry, Optoelectronics and Dielectric. His Thin film research incorporates themes from Condensed matter physics, Doping, Ferroelectricity and Mineralogy. His Pulsed laser deposition study integrates concerns from other disciplines, such as Excimer laser, Epitaxy, Lattice constant, Amorphous solid and Substrate.
His biological study spans a wide range of topics, including Tetragonal crystal system, Magnetic anisotropy, Scanning electron microscope and Fluence. His work in Optoelectronics addresses issues such as Laser, which are connected to fields such as Polymer. The concepts of his Dielectric study are interwoven with issues in Capacitance and Capacitor.
His primary areas of investigation include Thin film, Pulsed laser deposition, Analytical chemistry, Optoelectronics and Dielectric. James S. Horwitz has included themes like Excimer laser, Epitaxy, Ferroelectricity, Substrate and Microstructure in his Thin film study. His work deals with themes such as Single crystal and Doping, which intersect with Pulsed laser deposition.
His Analytical chemistry research integrates issues from Fourier transform infrared spectroscopy, Tetragonal crystal system, Mineralogy and Carbon film. James S. Horwitz has researched Optoelectronics in several fields, including Laser, Optics, Picosecond, Photon counting and Indium tin oxide. His studies in Dielectric integrate themes in fields like Crystallography, Transmission electron microscopy, Pole figure and Lattice constant.
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Electrical, optical, and structural properties of indium–tin–oxide thin films for organic light-emitting devices
H. Kim;C. M. Gilmore;A. Piqué;J. S. Horwitz.
Journal of Applied Physics (1999)
Transparent conducting aluminum-doped zinc oxide thin films for organic light-emitting devices
H. Kim;C. M. Gilmore;J. S. Horwitz;A. Piqué.
Applied Physics Letters (2000)
Laser deposition of polymer and biomaterial films.
D B Chrisey;A Piqué;R A McGill;J S Horwitz.
Chemical Reviews (2003)
Effect of aluminum doping on zinc oxide thin films grown by pulsed laser deposition for organic light-emitting devices
H Kim;A Piqué;J.S Horwitz;H Murata.
Thin Solid Films (2000)
Indium tin oxide thin films for organic light-emitting devices
H. Kim;A. Piqué;J. S. Horwitz;H. Mattoussi.
Applied Physics Letters (1999)
High-temperature thermopower in La2/3Ca1/3MnO3 films: Evidence for polaronic transport.
M. Jaime;M. B. Salamon;M. Rubinstein;R. E. Treece.
Physical Review B (1996)
Effect of film thickness on the properties of indium tin oxide thin films
H. Kim;J. S. Horwitz;G. Kushto;A. Piqué.
Journal of Applied Physics (2000)
The effect of annealing on the microwave properties of Ba0.5Sr0.5TiO3 thin films
Wontae Chang;James S. Horwitz;Adriaan C. Carter;Jeffrey M. Pond.
Applied Physics Letters (1999)
Indium tin oxide thin films grown on flexible plastic substrates by pulsed-laser deposition for organic light-emitting diodes
H. Kim;J. S. Horwitz;G. P. Kushto;Z. H. Kafafi.
Applied Physics Letters (2001)
The effect of annealing on the structure and dielectric properties of BaxSr1−xTiO3 ferroelectric thin films
L. A. Knauss;J. M. Pond;J. S. Horwitz;D. B. Chrisey.
Applied Physics Letters (1996)
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