Jeong Ho Cho
Yonsei University
464 Papers
2.2K Citations
Jeong Ho Cho is an academic researcher from Yonsei University. The author has contributed to research in topics: Graphene & Transistor. The author has an hindex of 58, co-authored 399 publications. Previous affiliations of Jeong Ho Cho include Northwestern University & Sungkyunkwan University.
Chat about Author
Papers
Precise control of surface wettability of mixed monolayers using a simple wiping method
TL;DR: In this article, mixed monolayers of 11-cyanoundecyltrichlorosilane (CN(CH2)11SiCl3) and dodecyl trichlorous solvents (CH3(CH 2 11SiCL3) in different ratios were fabricated using a simple wiping method.
18
On-demand doping of graphene by stamping with a chemically functionalized rubber lens.
TL;DR: Graphene doping using a stamp with a chemically functionalized rubber lens was confirmed by both Raman spectroscopy and charge transport measurements and may be applied to other emergent 2D materials to tightly modulate the electrical properties in advanced electronic devices.
18
A-D-A Type Semiconducting Small Molecules with Bis(alkylsulfanyl)methylene Substituents and Control of Charge Polarity for Organic Field-Effect Transistors.
Sung Joon Cho,Min Je Kim,Ziang Wu,Jae Hoon Son,Sang Young Jeong,Sungjoo Lee,Jeong Ho Cho,Han Young Woo +7 more
TL;DR: A simple and efficient molecular design strategy for fine tuning the charge polarity and charge transport properties of OFET devices is presented.
17
Poling effects on the performance of a lead-free piezoelectric nanofiber in a structural health monitoring sensor
TL;DR: In this article, the poling effects on the performance of a lead-free piezoelectric nanofiber module were investigated by XRD and temperature-dependence dielectric properties.
16
Rational Band Engineering of an Organic Double Heterojunction for Artificial Synaptic Devices with Enhanced State Retention and Linear Update of Synaptic Weight
TL;DR: These newly studied techniques for synaptic devices are expected to open up new possibilities for the realization of artificial synapses based on organic double-heterojunctions.
16