에너지시스템공학부_세미나.pdf
Speaker : Prof.
Engineering
Date : 17:00, Friday,
Host : Department of
Place : Room 301, Building 2, DGIST
Abstract
Organic semiconductors have great potential as active materials in next
flexible electronic and energy devices. To make full use of organic circuitry, it is
essential to combine p
of organic complementary circuits which offer lower power dissipation and greater
operating speed. Furthermore, the development of novel acceptor materials is currently
being recognized as a new way to achieve high efficiency organic solar cells. Less th
five years ago n
channel materials. In recent years, however, there has been a remarkable progress in
the molecular design, device performance and air
organic semiconductors. In this talk, I would like to present recent progress in materials
design for high
process strategies, mainly focusing on the development of most
channel semiconductors, i.e., perylene diimide (PDI) and naphthalene diimide (NDI)
derivatives.
.
INVITED
Prof. Joon Hak Oh
Engineering and Interdisciplinary School of Green Energy
:00, Friday, September
Department of Energy Systems Engineering
Place : Room 301, Building 2, DGIST
Organic semiconductors have great potential as active materials in next
flexible electronic and energy devices. To make full use of organic circuitry, it is
essential to combine p-channel transistors with n
of organic complementary circuits which offer lower power dissipation and greater
operating speed. Furthermore, the development of novel acceptor materials is currently
being recognized as a new way to achieve high efficiency organic solar cells. Less th
five years ago n-channel semiconductors were far less developed compared with p
channel materials. In recent years, however, there has been a remarkable progress in
the molecular design, device performance and air
nic semiconductors. In this talk, I would like to present recent progress in materials
design for high-performance air
process strategies, mainly focusing on the development of most
semiconductors, i.e., perylene diimide (PDI) and naphthalene diimide (NDI)
INVITED
Joon Hak Oh, School of Nano
Interdisciplinary School of Green Energy
September 16th, 2011
Energy Systems Engineering
Place : Room 301, Building 2, DGIST
Organic semiconductors have great potential as active materials in next
flexible electronic and energy devices. To make full use of organic circuitry, it is
channel transistors with n
of organic complementary circuits which offer lower power dissipation and greater
operating speed. Furthermore, the development of novel acceptor materials is currently
being recognized as a new way to achieve high efficiency organic solar cells. Less th
channel semiconductors were far less developed compared with p
channel materials. In recent years, however, there has been a remarkable progress in
the molecular design, device performance and air
nic semiconductors. In this talk, I would like to present recent progress in materials
performance air-stable n-channel organic semiconductors and their
process strategies, mainly focusing on the development of most
semiconductors, i.e., perylene diimide (PDI) and naphthalene diimide (NDI)
Contact : 053)785
ENERGY SYSTEMS ENGINEERING
INVITED SEMINAR
School of Nano-Bioscience
Interdisciplinary School of Green Energy
, 2011
Energy Systems Engineering
Organic semiconductors have great potential as active materials in next
flexible electronic and energy devices. To make full use of organic circuitry, it is
channel transistors with n-channel transistors for the fabricatio
of organic complementary circuits which offer lower power dissipation and greater
operating speed. Furthermore, the development of novel acceptor materials is currently
being recognized as a new way to achieve high efficiency organic solar cells. Less th
channel semiconductors were far less developed compared with p
channel materials. In recent years, however, there has been a remarkable progress in
the molecular design, device performance and air-stability enhancement of n
nic semiconductors. In this talk, I would like to present recent progress in materials
channel organic semiconductors and their
process strategies, mainly focusing on the development of most
semiconductors, i.e., perylene diimide (PDI) and naphthalene diimide (NDI)
Contact : 053)785-6402, energy@dgist.ac.kr
ENERGY SYSTEMS ENGINEERING
SEMINAR
ioscience and Chemical
Interdisciplinary School of Green Energy, UNIST
Organic semiconductors have great potential as active materials in next-generation
flexible electronic and energy devices. To make full use of organic circuitry, it is
channel transistors for the fabricatio
of organic complementary circuits which offer lower power dissipation and greater
operating speed. Furthermore, the development of novel acceptor materials is currently
being recognized as a new way to achieve high efficiency organic solar cells. Less th
channel semiconductors were far less developed compared with p
channel materials. In recent years, however, there has been a remarkable progress in
stability enhancement of n-channel
nic semiconductors. In this talk, I would like to present recent progress in materials
channel organic semiconductors and their
process strategies, mainly focusing on the development of most-commonly used n
semiconductors, i.e., perylene diimide (PDI) and naphthalene diimide (NDI)
6402, energy@dgist.ac.kr
ENERGY SYSTEMS ENGINEERING
SEMINAR
and Chemical
generation
flexible electronic and energy devices. To make full use of organic circuitry, it is
channel transistors for the fabrication
of organic complementary circuits which offer lower power dissipation and greater
operating speed. Furthermore, the development of novel acceptor materials is currently
being recognized as a new way to achieve high efficiency organic solar cells. Less than
channel semiconductors were far less developed compared with p-
channel materials. In recent years, however, there has been a remarkable progress in
channel
nic semiconductors. In this talk, I would like to present recent progress in materials
channel organic semiconductors and their
commonly used n-
semiconductors, i.e., perylene diimide (PDI) and naphthalene diimide (NDI)
6402, energy@dgist.ac.kr
ENERGY SYSTEMS ENGINEERING
2024-02-28