Heterogeneous Monolithic Integration of Single-Crystal Organic Materials
2017-02-17
org.kosen.entty.User@2e39175f
박영환(yehapark)
분야
화학
개최일
6 February 2017
신청자
박영환(yehapark)
개최장소
URL
행사&학회소개
1. Introduction
2. Heterogeneous Patterning of Organic Materials
2.1. Inkjet Printing
2.2. Capillary-Pen Printing
2.3. Electrohydrodynamic Printing
2.4. Dip/Polymer-pen Nanolithography
2.5. Transfer Printing
2.6. Selective Deposition
3. Heterogeneous Integration of Organic Single Crystals
3.1. Organic Single Crystal Growth
3.2. Mechanical Manipulation
3.3. Droplet-pinned Crystallization (DPC)
3.4. Liquid-Bridge-Mediated Nanotransfer Molding
3.5. Inkjet-assisted Nanotransfer Printing
4. Summary and Future Prospects
2. Heterogeneous Patterning of Organic Materials
2.1. Inkjet Printing
2.2. Capillary-Pen Printing
2.3. Electrohydrodynamic Printing
2.4. Dip/Polymer-pen Nanolithography
2.5. Transfer Printing
2.6. Selective Deposition
3. Heterogeneous Integration of Organic Single Crystals
3.1. Organic Single Crystal Growth
3.2. Mechanical Manipulation
3.3. Droplet-pinned Crystallization (DPC)
3.4. Liquid-Bridge-Mediated Nanotransfer Molding
3.5. Inkjet-assisted Nanotransfer Printing
4. Summary and Future Prospects
보고서작성신청
유기전자의 핵심은 프린팅 기술에 기반한 저비용의 대면적 소자 제작이 가능하다는 장점이다. 본 논문은 이에 적용되는 다양한 기술들이 쉽고도 상세하게 설명되어 있다.
Manufacturing high-performance organic electronic circuits requires the effective heterogeneous integration of different nanoscale organic materials with uniform morphology and high crystallinity in a desired arrangement. In particular, the development of high-performance organic electronic and optoelectronic devices relies on high-quality single crystals that show optimal intrinsic charge-transport properties and electrical performance. Moreover, the heterogeneous integration of organic materials on a single substrate in a monolithic way is highly demanded for the production of fundamental organic electronic components as well as complex integrated circuits. Many of the various methods that have been designed to pattern multiple heterogeneous organic materials on a substrate and the heterogeneous integration of organic single crystals with their crystal growth are described here. Critical issues that have been encountered in the development of high-performance organic integrated electronics are also addressed.
Manufacturing high-performance organic electronic circuits requires the effective heterogeneous integration of different nanoscale organic materials with uniform morphology and high crystallinity in a desired arrangement. In particular, the development of high-performance organic electronic and optoelectronic devices relies on high-quality single crystals that show optimal intrinsic charge-transport properties and electrical performance. Moreover, the heterogeneous integration of organic materials on a single substrate in a monolithic way is highly demanded for the production of fundamental organic electronic components as well as complex integrated circuits. Many of the various methods that have been designed to pattern multiple heterogeneous organic materials on a substrate and the heterogeneous integration of organic single crystals with their crystal growth are described here. Critical issues that have been encountered in the development of high-performance organic integrated electronics are also addressed.