about
Self-powered system with wireless data transmission.Pyroelectric nanogenerators for harvesting thermoelectric energy.Segmentally structured disk triboelectric nanogenerator for harvesting rotational mechanical energy.Triboelectric nanogenerator built on suspended 3D spiral structure as vibration and positioning sensor and wave energy harvester.Gigantic enhancement in response and reset time of ZnO UV nanosensor by utilizing Schottky contact and surface functionalization.Theory of sliding-mode triboelectric nanogenerators.Temperature dependence of the piezotronic effect in ZnO nanowires.Machine-Washable Textile Triboelectric Nanogenerators for Effective Human Respiratory Monitoring through Loom Weaving of Metallic Yarns.High-Performance Carbon Nanotube Complementary Electronics and Integrated Sensor Systems on Ultrathin Plastic Foil.Piezo-phototronic effect on electroluminescence properties of p-type GaN thin films.Progress in Piezo-Phototronic-Effect-Enhanced Light-Emitting Diodes and Pressure Imaging.Gallium nitride nanowire based nanogenerators and light-emitting diodes.Hybridizing triboelectrification and electromagnetic induction effects for high-efficient mechanical energy harvesting.Wafer-Scale Fabrication of Ultrathin Flexible Electronic Systems via Capillary-Assisted Electrochemical DelaminationDevelopment and progress in piezotronicsTemperature Dependence of the Piezophototronic Effect in CdS NanowiresPerformance Boosting of Flexible ZnO UV Sensors with Rational Designed Absorbing Antireflection Layer and Humectant EncapsulationObservation of a 2D Electron Gas and the Tuning of the Electrical Conductance of ZnO Nanowires by Controllable Surface Band-BendingVisible Light Response of Unintentionally Doped ZnO Nanowire Field Effect TransistorsQuantitative Study on the Effect of Surface Treatments on the Electric Characteristics of ZnO NanowiresDoping-Free Fabrication of Carbon Nanotube Based Ballistic CMOS Devices and CircuitsAn elastic-spring-substrated nanogenerator as an active sensor for self-powered balanceKirigami-Inspired Deformable 3D Structures Conformable to Curved Biological Surface.Ultrahigh Sensitive Piezotronic Strain Sensors Based on a ZnSnO3 Nanowire/MicrowireHigh-output nanogenerator by rational unipolar assembly of conical nanowires and its application for driving a small liquid crystal displayHigh output nanogenerator based on assembly of GaN nanowiresReplacing a battery by a nanogenerator with 20 V outputDesigning the electric transport characteristics of ZnO micro/nanowire devices by coupling piezoelectric and photoexcitation effectsConverse piezoelectric effect induced transverse deflection of a free-standing ZnO microbeltSupersensitive, fast-response nanowire sensors by using Schottky contactsOptimizing the power output of a ZnO photocell by piezopotentialA nanogenerator for energy harvesting from a rotating tire and its application as a self-powered pressure/speed sensorTunable, Ultrasensitive, and Flexible Pressure Sensors Based on Wrinkled Microstructures for Electronic SkinsQuantitative fitting of nonlinear current-voltage curves and parameter retrieval of semiconducting nanowire, nanotube and nanoribbon devices
P50
Q33908979-D6C7F75D-70EB-4FF0-ABB7-9808D4D75DFCQ34271851-4ABB4964-C595-4D9B-A84F-DCBA85A91B47Q34343537-D97C7D7E-9AAA-412E-ADB9-276312DBE1AFQ38403581-DACE83BE-6592-4F4C-9633-D6497E36E10EQ41980153-0C49333D-2660-4A2D-95D8-AACD216E94BEQ44739447-09FAB72A-C11B-478F-83D3-D35E8563E723Q44945133-E0C5A6A3-E6A2-463E-9FE6-79391A235872Q47270381-0CF9577C-05D4-4574-8AD8-32C4AECDB448Q48149407-ECCF37DA-5592-4B64-9FDE-1338B05C6C5EQ50245535-7BD2BC84-5A13-4170-9DF7-372C22C59F05Q51603336-0BBB5E03-19FD-4793-83EA-A0BAEEE5FE16Q53099833-366D56EE-597A-4FB2-881A-C920D6ADAA0CQ53526924-648D7B28-A788-41EA-8F6B-7178BAB3FCDFQ57473681-6E52EFEE-4663-4BE4-8491-562FB167A9E9Q59755163-A8C12C31-5D11-4CFD-9A89-3ED94D66280AQ59755167-31084074-0AD8-4B84-8C14-29958A21176FQ62097642-6DF9BD81-535E-4726-8C26-E836BC736433Q62097721-8CDFBAA4-84ED-4C3D-BE1C-51AC6F986479Q62097726-F7A9B5A0-A93F-4F00-9A3B-0B689BC62076Q62097734-EDF5E5C9-B9C8-46ED-9A68-76FB36EA8D98Q62097738-6A45E861-BD67-40E2-A905-6B02D67A6D00Q63381402-AA6522F6-B16A-44B3-A5BA-0DF38517AE06Q64937670-F226FAD7-29E1-4237-A35F-923370D39BD7Q67229651-A32E84F2-D2B6-45FB-A837-821EEA1F5B16Q82292510-0441CDC0-1BAF-4FB9-A00B-2AC6EA4D606BQ82313675-E95E5AE9-1AAD-497C-8EFF-2FED0786A5ADQ82371101-87954122-3F23-41AE-9115-9499E3942E37Q82531320-3FFA5CAE-94B5-437D-8CEE-9BFA6FB59111Q84049045-40C85CDB-E685-4751-9625-A0EC39F4EFCFQ84341518-211AF77A-D9DF-4E15-A5CD-96B3D93E4CC2Q84349862-5B2D291C-D385-4ECB-ABD1-9B296178EB6BQ84661396-B8E11A24-6C32-4E89-B2CD-8BC851EE39E5Q92105328-ED5C96AC-E33F-44D7-83FD-995582EC51A7Q95820380-0888918D-B897-46A8-B343-E3131730675E
P50
description
researcher
@en
wetenschapper
@nl
հետազոտող
@hy
name
Youfan Hu
@ast
Youfan Hu
@en
Youfan Hu
@es
Youfan Hu
@nl
type
label
Youfan Hu
@ast
Youfan Hu
@en
Youfan Hu
@es
Youfan Hu
@nl
prefLabel
Youfan Hu
@ast
Youfan Hu
@en
Youfan Hu
@es
Youfan Hu
@nl
P106
P31
P496
0000-0001-9798-1631