Wu-Qiang Wu

What is he best known for?

The fields of study he is best known for:

• Semiconductor
• Solar cell
• Nanotechnology

Energy conversion efficiency, Nanowire, Nanotechnology, Dye-sensitized solar cell and Perovskite are his primary areas of study. His research on Energy conversion efficiency concerns the broader Optoelectronics. His research in Nanowire focuses on subjects like Nanostructure, which are connected to Solar cell and Nanocrystal.

His Nanotechnology study combines topics from a wide range of disciplines, such as Photocurrent and Anode. Wu-Qiang Wu conducts interdisciplinary study in the fields of Dye-sensitized solar cell and Anatase through his research. His Perovskite study integrates concerns from other disciplines, such as Thin film, Passivation, Halide and Grain boundary.

His most cited work include:

• Hydrothermal fabrication of hierarchically anatase TiO2 nanowire arrays on FTO glass for dye-sensitized solar cells. (263 citations)
• Multistack Integration of Three-Dimensional Hyperbranched Anatase Titania Architectures for High-Efficiency Dye-Sensitized Solar Cells (199 citations)
• Molecular doping enabled scalable blading of efficient hole-transport-layer-free perovskite solar cells (143 citations)

What are the main themes of his work throughout his whole career to date?

His primary scientific interests are in Perovskite, Optoelectronics, Energy conversion efficiency, Nanotechnology and Nanowire. His Perovskite study incorporates themes from Photovoltaics, Thin film, Passivation and Halide. In his study, Quantum tunnelling is inextricably linked to Layer, which falls within the broad field of Optoelectronics.

His Energy conversion efficiency research incorporates elements of Substrate, Hydrothermal circulation and Nanosheet. His work on Nanorod, Nanostructure and Quantum dot as part of general Nanotechnology research is frequently linked to Auxiliary electrode, bridging the gap between disciplines. Wu-Qiang Wu integrates many fields, such as Nanowire, Anatase and Specific surface area, in his works.

He most often published in these fields:

• Perovskite (87.91%)
• Optoelectronics (74.73%)
• Energy conversion efficiency (47.25%)

What were the highlights of his more recent work (between 2019-2021)?

• Perovskite (87.91%)
• Optoelectronics (74.73%)
• Passivation (25.27%)

In recent papers he was focusing on the following fields of study:

His primary areas of study are Perovskite, Optoelectronics, Passivation, Halide and Energy conversion efficiency. The Perovskite study combines topics in areas such as Photovoltaics, Diode, Light-emitting diode, Photocurrent and Engineering physics. Wu-Qiang Wu has included themes like Layer and Surface modification in his Optoelectronics study.

His Passivation study integrates concerns from other disciplines, such as Crystal, Grain boundary and Crystallite. While the research belongs to areas of Halide, Wu-Qiang Wu spends his time largely on the problem of Photodetector, intersecting his research to questions surrounding Nanowire, Quantum dot and Nanotechnology. His Energy conversion efficiency research focuses on Electron mobility and how it relates to Copolymer.

Between 2019 and 2021, his most popular works were:

• Resolving spatial and energetic distributions of trap states in metal halide perovskite solar cells (90 citations)
• Reducing Surface Halide Deficiency for Efficient and Stable Iodide-Based Perovskite Solar Cells. (50 citations)
• Reducing Surface Halide Deficiency for Efficient and Stable Iodide-Based Perovskite Solar Cells. (50 citations)

In his most recent research, the most cited papers focused on:

• Semiconductor
• Solar cell
• Crystal

His primary areas of investigation include Perovskite, Halide, Optoelectronics, Photocurrent and Passivation. His research in Perovskite intersects with topics in Iodide, Coating and Band gap. His studies examine the connections between Coating and genetics, as well as such issues in Engineering physics, with regards to Doping.

His Band gap research includes elements of Crystal growth, Formamidinium and Grain boundary. His studies in Passivation integrate themes in fields like Molecular physics, Nanocrystal and Crystallite. Many of his High fever research pursuits overlap with Nanowire, Photodetector, Fabrication and Quantum dot.

This overview was generated by a machine learning system which analysed the scientist’s body of work. If you have any feedback, you can contact us here.