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Prof. Cheolmin Park seeks to utilize the molecular self-assembly principles found in Nature to create and control new nanometer scale soft and hybrid materials for innovative electrical devices based on emerging nanotechnology. The research interest covers from molecular design, assembly to nanopatterns and devices including self-organizing polymer systems and nanostructures, with particular emphasis on functional block copolymers, supra-molecular assembled materials and hybrid assembly of carbon nanomaterials with polymers; solution-processed non-lithographic printing technologies such as nanoimprinting, ink-jet and transfer printing combined with surface engineering; various organic and polymeric devices such as ultrahigh density ferroelectric polymer memories, organic field effect transistors, solar cells and novel electroluminescent devices with networked carbon nanomaterials. The goal is to contribute to the understanding of process-structure-property relationships and to create technologically useful materials and devices.
Prof. Cheolmin Park seeks to utilize the molecular self-assembly principles found in Nature to create and control new nanometer scale soft and hybrid materials for innovative electrical devices based on emerging nanotechnology. The research interest covers from molecular design, assembly to nanopatterns and devices including self-organizing polymer systems and nanostructures, with particular emphasis on functional block copolymers, supra-molecular assembled materials and hybrid assembly of carbon nanomaterials with polymers; solution-processed non-lithographic printing technologies such as nanoimprinting, ink-jet and transfer printing combined with surface engineering; various organic and polymeric devices such as ultrahigh density ferroelectric polymer memories, organic field effect transistors, solar cells and novel electroluminescent devices with networked carbon nanomaterials. The goal is to contribute to the understanding of process-structure-property relationships and to create technologically useful materials and devices.
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论文共 425 篇作者统计合作学者相似作者
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ENERGY & ENVIRONMENTAL SCIENCEno. 1 (2024): 134-148
ADVANCED FUNCTIONAL MATERIALS (2024)
Advanced materials (Deerfield Beach, Fla.)no. 14 (2024): e2310130-e2310130
GIANT (2024): 100208-100208
MATERIALS TODAY (2023): 44-56
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