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Stephen J. Pearton
Researcher at University of Florida
Publications - 1988
Citations - 62995
Stephen J. Pearton is an academic researcher from University of Florida. The author has contributed to research in topics: Dry etching & Etching (microfabrication). The author has an hindex of 104, co-authored 1913 publications receiving 58669 citations. Previous affiliations of Stephen J. Pearton include Kyungpook National University & University of Southern California.
Papers
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Transport properties of phosphorus-doped ZnO thin films
TL;DR: The doping behavior of phosphorus in ZnO thin films grown by pulsed laser deposition is examined in this article, showing that the phosphorus-related donor defect is relatively unstable and suggests the formation of a deep level upon annealing.
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2300V Reverse Breakdown Voltage Ga2O3 Schottky Rectifiers
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Carbon nanotube films for room temperature hydrogen sensing
Jennifer Sippel-Oakley,Hung-Ta Wang,B. S. Kang,Zhuangchun Wu,Fan Ren,Andrew G. Rinzler,Stephen J. Pearton +6 more
TL;DR: Thin, uniform, single-walled carbon nanotube films, made by a simple filtration process, subsequently coated with palladium, are shown to be promising detectors of hydrogen, and strong evidence was obtained indicating that sputter deposition of metal onto the nanotubes, even under very low power, short exposure time conditions, does damage to the Nanotubes.
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Donor-hydrogen complexes in passivated silicon.
TL;DR: The authors' results suggest that H is bonded to Si rather than the donor directly, and thermal annealing experiments confirm that donor passivation is due to complex formation, and yield the stability of the complexes.
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Hydrogenation of shallow‐donor levels in GaAs
Stephen J. Pearton,William Cross Dautremont-Smith,J. Chevallier,Charles W. Tu,K. D. Cummings +4 more
TL;DR: In this article, the neutralization depth of the donors is proportional to the inverse square root of the donor concentration, and this depth is given as a function of plasma exposure temperature (100 −350 ) and bonding site density (8×1013 −1.5×1018 cm−3).