What is he best known for?
The fields of study he is best known for:
- Electrical engineering
- Artificial intelligence
- Mechanical engineering
His primary scientific interests are in Optoelectronics, Electrical engineering, Nanotechnology, Voltage and Microelectromechanical systems.
His study in Optoelectronics is interdisciplinary in nature, drawing from both Gyroscope, Nanoscopic scale, Fluorescence and Scanning electron microscope.
Wen J. Li has included themes like Generator, Vibration and Electric power in his Electrical engineering study.
He studies Nanotechnology, namely Carbon nanotube.
His Voltage research is multidisciplinary, relying on both Electrophoresis, Electrokinetic phenomena, Single-cell analysis, Dielectric and Dielectrophoresis.
His research in Microelectromechanical systems intersects with topics in Electronic engineering, Actuator, Artificial intelligence and Deflection.
His most cited work include:
- A laser-micromachined multi-modal resonating power transducer for wireless sensing systems (223 citations)
- MEMS Accelerometer Based Nonspecific-User Hand Gesture Recognition (147 citations)
- Haptic information in Internet-based teleoperation (125 citations)
What are the main themes of his work throughout his whole career to date?
His main research concerns Nanotechnology, Optoelectronics, Carbon nanotube, Microelectromechanical systems and Dielectrophoresis.
His studies in Nanotechnology integrate themes in fields like Nano- and Polymer.
His Optoelectronics research includes themes of Substrate, Electrohydrodynamics and Voltage.
Within one scientific family, Wen J. Li focuses on topics pertaining to Microelectrode under Carbon nanotube, and may sometimes address concerns connected to Analytical chemistry.
His Microelectromechanical systems research includes elements of Electronic engineering and Actuator.
His biological study spans a wide range of topics, including Electrokinetic phenomena, Nanoparticle and Electrophoresis.
He most often published in these fields:
- Nanotechnology (42.65%)
- Optoelectronics (25.83%)
- Carbon nanotube (19.67%)
What were the highlights of his more recent work (between 2016-2021)?
- Nanotechnology (42.65%)
- Optoelectronics (25.83%)
- Microfluidics (12.56%)
In recent papers he was focusing on the following fields of study:
His primary areas of investigation include Nanotechnology, Optoelectronics, Microfluidics, Optics and Optical microscope.
His Nanotechnology study frequently links to adjacent areas such as Self-healing hydrogels.
His work on Superlens, Dielectric and Visible light communication as part of general Optoelectronics study is frequently connected to Sensor array, therefore bridging the gap between diverse disciplines of science and establishing a new relationship between them.
His Microfluidics research incorporates elements of Electrokinetic phenomena, Artificial tissue, Optical tweezers and Self locking.
His study looks at the relationship between Optical microscope and fields such as Lens, as well as how they intersect with chemical problems.
His work deals with themes such as Dielectrophoresis and Voltage, which intersect with Conductive atomic force microscopy.
Between 2016 and 2021, his most popular works were:
- Fingertip‐skin‐inspired highly sensitive and multifunctional sensor with hierarchically structured conductive graphite/polydimethylsiloxane foams (52 citations)
- Light-sheet microscopy in the near-infrared II window. (48 citations)
- Light-sheet microscopy in the near-infrared II window. (48 citations)
In his most recent research, the most cited papers focused on:
- Electrical engineering
- Mechanical engineering
- Artificial intelligence
The scientist’s investigation covers issues in Nanotechnology, Optics, Dielectrophoresis, Finite-difference time-domain method and Laser.
His Nanotechnology research integrates issues from Alginate hydrogel, Porosity and 3D bioprinting.
Many of his research projects under Dielectrophoresis are closely connected to Cancer cell with Cancer cell, tying the diverse disciplines of science together.
His Finite-difference time-domain method study combines topics from a wide range of disciplines, such as Nanoscopic scale, Full width at half maximum, Superlens and Ray.
His research in Laser intersects with topics in Stereolithography, Visible spectrum and Cell spreading.
He interconnects Conductive atomic force microscopy, Nanoparticle, Voltage, Substrate and Indium tin oxide in the investigation of issues within Nanostructure.
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