What is he best known for?
The fields of study he is best known for:
- Quantum mechanics
- Electron
- Semiconductor
His primary areas of study are Optoelectronics, Nanotechnology, Photodetector, Chemical engineering and Ultraviolet.
Weihua Tang focuses mostly in the field of Optoelectronics, narrowing it down to topics relating to Thin film and, in certain cases, Molecular beam epitaxy and Amorphous solid.
His research in Nanotechnology intersects with topics in Carbon and Photoluminescence.
His biological study spans a wide range of topics, including Schottky diode and Depletion region.
His Chemical engineering research is multidisciplinary, incorporating perspectives in Photocatalysis, Inorganic chemistry and Carbothermic reaction.
His Ultraviolet research includes themes of Substrate, p–n junction and Laser.
His most cited work include:
- First principles study of structural, vibrational and electronic properties of graphene-like MX2 (M=Mo, Nb, W, Ta; X=S, Se, Te) monolayers (431 citations)
- Fabrication of β-Ga_2O_3 thin films and solar-blind photodetectors by laser MBE technology (212 citations)
- Oxygen vacancy tuned Ohmic-Schottky conversion for enhanced performance in β-Ga2O3 solar-blind ultraviolet photodetectors (208 citations)
What are the main themes of his work throughout his whole career to date?
Weihua Tang mainly focuses on Optoelectronics, Thin film, Nanotechnology, Crystallography and Condensed matter physics.
His Optoelectronics study is mostly concerned with Photodetector, Heterojunction, Ultraviolet, Responsivity and Band gap.
His Photodetector study incorporates themes from Light intensity and Photoelectric effect.
Weihua Tang combines subjects such as Doping, Molecular beam epitaxy, Epitaxy, Analytical chemistry and Substrate with his study of Thin film.
The various areas that Weihua Tang examines in his Nanotechnology study include Chemical engineering and Photoluminescence.
His Crystallography study combines topics in areas such as Solid solution and Intermetallic.
He most often published in these fields:
- Optoelectronics (39.05%)
- Thin film (24.80%)
- Nanotechnology (21.37%)
What were the highlights of his more recent work (between 2018-2021)?
- Optoelectronics (39.05%)
- Photodetector (14.51%)
- Heterojunction (11.08%)
In recent papers he was focusing on the following fields of study:
Weihua Tang mostly deals with Optoelectronics, Photodetector, Heterojunction, Thin film and Responsivity.
His study involves Photodetection, Ultraviolet, Chemical vapor deposition, Schottky barrier and Band gap, a branch of Optoelectronics.
He combines subjects such as Amorphous solid, p–n junction, Semiconductor, Nanorod and Electrode with his study of Photodetector.
His study on Heterojunction also encompasses disciplines like
- Electron which connect with Contact resistance and Absorption spectroscopy,
- X-ray photoelectron spectroscopy which connect with Crystallography.
His Thin film research integrates issues from Thermal conductivity, Thermal, Dopant and Epitaxy.
His Responsivity research includes themes of Dark current, Photoconductivity and Quantum efficiency.
Between 2018 and 2021, his most popular works were:
- Review of Ga2O3-based optoelectronic devices (44 citations)
- Ultrasensitive, Superhigh Signal-to-Noise Ratio, Self-Powered Solar-Blind Photodetector Based on n-Ga2O3/p-CuSCN Core–Shell Microwire Heterojunction (30 citations)
- Review of gallium oxide based field-effect transistors and Schottky barrier diodes (25 citations)
In his most recent research, the most cited papers focused on:
- Quantum mechanics
- Electron
- Semiconductor
Weihua Tang spends much of his time researching Optoelectronics, Photodetector, Responsivity, Heterojunction and Schottky diode.
Weihua Tang has included themes like Amorphous solid and Detector in his Optoelectronics study.
His research integrates issues of Band gap, Nanorod, Doping and Ultraviolet in his study of Photodetector.
His Responsivity research is multidisciplinary, incorporating perspectives in Dark current and Quantum efficiency.
His Schottky diode study combines topics in areas such as Thin film and Ohmic contact.
His work on Plasma-enhanced chemical vapor deposition as part of general Thin film study is frequently linked to Growth rate, therefore connecting diverse disciplines of science.
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