What is he best known for?
The fields of study he is best known for:
- Organic chemistry
- Ion
- Semiconductor
Shu Hotta mainly investigates Optoelectronics, Organic semiconductor, Thiophene, Phenylene and Field-effect transistor.
His Optoelectronics study incorporates themes from Laser application, Transistor and Single crystal.
His Organic semiconductor research incorporates elements of Electroluminescence, Stimulated emission, Organic field-effect transistor, Amplified spontaneous emission and Photoluminescence.
His Thiophene research incorporates themes from Crystallography, Crystal growth, Photochemistry and Stereochemistry.
His work carried out in the field of Phenylene brings together such families of science as Molecular physics, Substrate and Polymer chemistry.
Shu Hotta has researched Field-effect transistor in several fields, including Light emission, Epitaxy, Organic electronics, Gate dielectric and Gate oxide.
His most cited work include:
- High Mobility and Luminescent Efficiency in Organic Single-Crystal Light-Emitting Transistors (187 citations)
- Alkyl-substituted oligothiophenes: crystallographic and spectroscopic studies of neutral and doped forms (186 citations)
- Crystal structures of oligothiophenes and their relevance to charge transport (157 citations)
What are the main themes of his work throughout his whole career to date?
His primary areas of investigation include Optoelectronics, Phenylene, Thiophene, Crystal and Organic semiconductor.
His Optoelectronics research is multidisciplinary, incorporating perspectives in Field-effect transistor, Transistor, Single crystal and Ambipolar diffusion.
His Field-effect transistor research is multidisciplinary, incorporating elements of Electron mobility, Organic chemistry and Electrode.
His Phenylene research incorporates themes from Crystal growth, Analytical chemistry, Molecular physics and Laser, Lasing threshold.
Shu Hotta interconnects Crystallography, Thin film, Oligomer, Polymer chemistry and Photochemistry in the investigation of issues within Thiophene.
His work deals with themes such as Substrate, Refractive index, Optics and Emission spectrum, which intersect with Crystal.
He most often published in these fields:
- Optoelectronics (40.08%)
- Phenylene (36.03%)
- Thiophene (33.60%)
What were the highlights of his more recent work (between 2014-2020)?
- Optoelectronics (40.08%)
- Organic semiconductor (22.67%)
- Crystal (23.48%)
In recent papers he was focusing on the following fields of study:
Shu Hotta mainly focuses on Optoelectronics, Organic semiconductor, Crystal, Diffraction grating and Phenylene.
He combines subjects such as OLED, Transistor and Single crystal with his study of Optoelectronics.
Shu Hotta has included themes like Chemical physics, Microcrystalline, Acene, Crystallinity and Laser in his Organic semiconductor study.
In his study, Photoexcitation and Wave vector is strongly linked to Layer, which falls under the umbrella field of Crystal.
His Phenylene study incorporates themes from Crystallography, Crystal growth, Saturation, Thiophene and Photochemistry.
His Thiophene research includes themes of Heterojunction, Electron mobility, Chemical engineering and Substrate.
Between 2014 and 2020, his most popular works were:
- The entangled triplet pair state in acene and heteroacene materials. (72 citations)
- Highly Efficient Three Primary Color Organic Single‐Crystal Light‐Emitting Devices with Balanced Carrier Injection and Transport (35 citations)
- Intrinsic Polarization and Tunable Color of Electroluminescence from Organic Single Crystal-based Light- Emitting Devices (26 citations)
In his most recent research, the most cited papers focused on:
- Organic chemistry
- Ion
- Laser
Shu Hotta mainly investigates Optoelectronics, Single crystal, Crystal, Doping and Photoluminescence.
His research in Optoelectronics intersects with topics in OLED, Electroluminescence and Laser.
His Electroluminescence research incorporates elements of Thiophene, Phenylene and Molecule.
His study looks at the relationship between Single crystal and topics such as Polarization, which overlap with Anisotropy.
His Doping study also includes
- Electron mobility that connect with fields like Impurity, Stacking and Field-effect transistor,
- Semiconductor which is related to area like Heterojunction.
His Photoluminescence course of study focuses on Exciton and Molecular physics, Energy level splitting and Singlet state.
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