What is he best known for?
The fields of study Kazunari Matsuda is best known for:
- Electron
- Semiconductor
- Photon
Trion and Biexciton are the areas that his Exciton study falls under.
His work on Trion is being expanded to include thematically relevant topics such as Condensed matter physics.
He combines topics linked to Band gap with his work on Condensed matter physics.
Kazunari Matsuda carries out multidisciplinary research, doing studies in Band gap and Exciton.
His research on Metallurgy often connects related areas such as Metal and Oxide.
Kazunari Matsuda applies his multidisciplinary studies on Metal and Metallurgy in his research.
Optoelectronics connects with themes related to Heterojunction in his study.
His study ties his expertise on Optoelectronics together with the subject of Heterojunction.
Kazunari Matsuda performs integrative Nanotechnology and Nanocrystal research in his work.
His most cited work include:
- Tunable Photoluminescence of Monolayer MoS2 via Chemical Doping (1122 citations)
- Photocarrier relaxation pathway in two-dimensional semiconducting transition metal dichalcogenides (359 citations)
- Gigantic Photoresponse in ¼-Filled-Band Organic Salt (EDO-TTF) 2 PF 6 (312 citations)
What are the main themes of his work throughout his whole career to date
His multidisciplinary approach integrates Nanotechnology and Chemical physics in his work.
He conducted interdisciplinary study in his works that combined Chemical physics and Nanotechnology.
His studies link Doping with Optoelectronics.
His Doping study frequently draws parallels with other fields, such as Optoelectronics.
Kazunari Matsuda merges many fields, such as Condensed matter physics and Exciton, in his writings.
Kazunari Matsuda combines Exciton and Photoluminescence in his studies.
He merges many fields, such as Photoluminescence and Spectroscopy, in his writings.
Kazunari Matsuda integrates Spectroscopy with Molecular physics in his study.
Kazunari Matsuda performs multidisciplinary study on Molecular physics and Atomic physics in his works.
Kazunari Matsuda most often published in these fields:
- Nanotechnology (75.78%)
- Optoelectronics (73.44%)
- Condensed matter physics (50.00%)
What were the highlights of his more recent work (between 2019-2022)?
- Nanotechnology (68.75%)
- Condensed matter physics (56.25%)
- Optoelectronics (56.25%)
In recent works Kazunari Matsuda was focusing on the following fields of study:
Kazunari Matsuda connects relevant research areas such as Monolayer and Carbon nanotube in the realm of Nanotechnology.
His Condensed matter physics study frequently draws parallels with other fields, such as Heterojunction.
His Heterojunction study frequently links to other fields, such as Condensed matter physics.
He performs multidisciplinary studies into Optoelectronics and Band gap in his work.
He integrates Band gap and Photoluminescence in his research.
In his works, he undertakes multidisciplinary study on Quantum mechanics and Scattering.
With his scientific publications, his incorporates both Scattering and Quantum mechanics.
Kazunari Matsuda integrates Exciton and Trion in his research.
Kazunari Matsuda performs multidisciplinary studies into Trion and Exciton in his work.
Between 2019 and 2022, his most popular works were:
- Carbon Nanotube Photoluminescence Modulation by Local Chemical and Supramolecular Chemical Functionalization (44 citations)
- Observation of Drastic Electronic-Structure Change in a One-Dimensional Moiré Superlattice (22 citations)
- Recycled Utilization of a Nanoporous Au Electrode for Reduced Fabrication Cost of Perovskite Solar Cells (19 citations)
In his most recent research, the most cited works focused on:
- Band gap
- Catalysis
- Photoluminescence
His research investigates the connection between Surface modification and topics such as Physical chemistry that intersect with problems in Electrode.
His research on Electrode often connects related areas such as Physical chemistry.
The research on Superacid and Transition metal is part of his Catalysis project.
He performs multidisciplinary study in Transition metal and Catalysis in his work.
As part of his studies on Nanotechnology, he frequently links adjacent subjects like Monolayer.
Monolayer connects with themes related to Nanotechnology in his study.
Optoelectronics is frequently linked to Energy conversion efficiency in his study.
His Energy conversion efficiency study frequently links to adjacent areas such as Optoelectronics.
He undertakes interdisciplinary study in the fields of Condensed matter physics and Chemical physics through his research.
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