CNBT:Research: Difference between revisions
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[[CNBT:News | <font face="trebuchet ms" style="color:#ffffff"> '''News''' </font>]] | [[CNBT:News | <font face="trebuchet ms" style="color:#ffffff"> '''News''' </font>]] | ||
[[CNBT:Links| <font face="trebuchet ms" style="color:#ffffff"> '''Links''' </font>]] | [[CNBT:Links| <font face="trebuchet ms" style="color:#ffffff"> '''Links''' </font>]] | ||
[[CNBT:Contact| <font face="trebuchet ms" style="color:#ffffff"> '''Contact''' </font>]] | |||
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=='''Carbon Nano Tube & Graphene'''== | =='''Carbon Nano Tube & Graphene'''== | ||
[[Image:CNT.JPG|left|400 px]] | |||
We are interested in every aspect of conductive materials such as electronic and mechanical properties. In addition, we want to see how they interact with other chemicals. Thus, the adsorption and mixing behavior are investigated.<br> | |||
<br><br><br><br> | |||
We | =='''Hydrogel for Biomedical Applications'''== | ||
[[Image:Hydrogel.JPG|right|500 px]] | |||
We pursue fundamental understanding of hydrogel system by characterizing the structure-property relationship of given materials. Based on such relationship, we design new hydrogel system for better properties such as excellent biocompatibility, optimal mechanical strength, proper permeation of gas & nutrition and smart response to external conditions. <br> | |||
<br><br><br><br><br><br><br><br> | |||
=='''Fuel Cell Technology'''== | |||
[[Image:Fuel_cell.JPG|left|600 px]] | |||
We are investigating the atomistic/molecular mechanisms in fuel cell system, which serves to develop better materials and better configurations.<br> | |||
For membrane, we are investigating the nanophase-segregation consisting of water phase and polymer phase in order to understand the proton conduction within that specific material. Based on such knowledge, we design new chemical structures of membrane materials.<br> | |||
For electrode, we are studying i) the interface between membrane and electrode and ii) the electrochemical events on electrode.<br> | |||
<br><br><br><br><br> | |||
=='''NanoElectronics and NanoMechanics'''== | |||
[[Image:Cyclo.JPG|right|300 px]] | |||
We are interested in nano-meter scale system consisting of organic/inorganic materials to aim at developing electronic/mechanic devices. For this, we pursue fundamental understanding of tunneling, atomic displacement and molecular deformation in molecular self-assembly at various conditions.<br> | |||
Such fundamental understandings will enable us to achieve better stability and performance.<br> | |||
<br><br><br><br><br><br><br><br><br><br><br><br><br><br><br><br> | |||
==''' | =='''Research Collaborators'''== | ||
<b>Prof. William A. Goddard, III</b> <br> | |||
California Institute of Technology <br> | |||
Materials and Process Simulation Center <br> | |||
Chemistry, Chemical Engineering, Materials Science and Engineering, Applied Physics <br> | |||
<br> | |||
<b>Prof. James R. Heath</b> <br> | |||
California Institute of Technology <br> | |||
Chemistry <br> | |||
<br> | |||
<b>Prof. J. Fraser Stoddart</b> <br> | |||
Northwestern University <br> | |||
Chemistry <br> | |||
<br> | |||
<b>Prof. Mark E. Davis</b> <br> | |||
California Institute of Technology <br> | |||
Chemical Engineering <br> | |||
<br> | |||
<b>Prof. Yushan Yan</b> <br> | |||
University of California, Riverside <br> | |||
Chemical & Environmental Engineering <br> | |||
<br> | |||
<b>Dr. Yue Qi</b> <br> | |||
General Motors <br> | |||
R&D Center <br> | |||
<br> | |||
<b>Prof. Shiang-Tai Lin</b> <br> | |||
National Taiwan University <br> | |||
Chemical Engineering <br> | |||
<br> | |||
<b>Prof. David Bucknall</b> <br> | |||
Georgia Institute of Technology <br> | |||
Polymer, Textile and Fiber Engineering <br> | |||
Materials Science and Engineering <br> | |||
<br> | |||
<b>Prof. Vladimir Tzukruk</b> <br> | |||
Georgia Institute of Technology <br> | |||
Materials Science and Engineering <br> | |||
Polymer, Textile and Fiber Engineering <br> | |||
<br> | |||
<b>Prof. Rina Tannenbaum</b> <br> | |||
Georgia Institute of Technology <br> | |||
Materials Science and Engineering <br> | |||
<br> | |||
<b>Prof. Zhong Lin Wang</b> <br> | |||
Georgia Institute of Technology <br> | |||
Materials Science and Engineering <br> | |||
<br> | |||
<b>Prof. Jaehong Kim</b> <br> | |||
Georgia Institute of Technology <br> | |||
Civil and Environmental Engineering <br> | |||
<br> | |||
<b>Dr. Gene Kim</b> <br> | |||
Cookson Electronics <br> | |||
Assembly Materials Group <br> | |||
<br> | |||
<b>Prof. Jongman Kim</b> <br> | |||
Georgia Institute of Technology <br> | |||
Electrical and Computer Engineering <br> | |||
Revision as of 20:15, 22 February 2009
Carbon Nano Tube & Graphene
We are interested in every aspect of conductive materials such as electronic and mechanical properties. In addition, we want to see how they interact with other chemicals. Thus, the adsorption and mixing behavior are investigated.
Hydrogel for Biomedical Applications
We pursue fundamental understanding of hydrogel system by characterizing the structure-property relationship of given materials. Based on such relationship, we design new hydrogel system for better properties such as excellent biocompatibility, optimal mechanical strength, proper permeation of gas & nutrition and smart response to external conditions.
Fuel Cell Technology
We are investigating the atomistic/molecular mechanisms in fuel cell system, which serves to develop better materials and better configurations.
For membrane, we are investigating the nanophase-segregation consisting of water phase and polymer phase in order to understand the proton conduction within that specific material. Based on such knowledge, we design new chemical structures of membrane materials.
For electrode, we are studying i) the interface between membrane and electrode and ii) the electrochemical events on electrode.
NanoElectronics and NanoMechanics
We are interested in nano-meter scale system consisting of organic/inorganic materials to aim at developing electronic/mechanic devices. For this, we pursue fundamental understanding of tunneling, atomic displacement and molecular deformation in molecular self-assembly at various conditions.
Such fundamental understandings will enable us to achieve better stability and performance.
Research Collaborators
Prof. William A. Goddard, III
California Institute of Technology
Materials and Process Simulation Center
Chemistry, Chemical Engineering, Materials Science and Engineering, Applied Physics
Prof. James R. Heath
California Institute of Technology
Chemistry
Prof. J. Fraser Stoddart
Northwestern University
Chemistry
Prof. Mark E. Davis
California Institute of Technology
Chemical Engineering
Prof. Yushan Yan
University of California, Riverside
Chemical & Environmental Engineering
Dr. Yue Qi
General Motors
R&D Center
Prof. Shiang-Tai Lin
National Taiwan University
Chemical Engineering
Prof. David Bucknall
Georgia Institute of Technology
Polymer, Textile and Fiber Engineering
Materials Science and Engineering
Prof. Vladimir Tzukruk
Georgia Institute of Technology
Materials Science and Engineering
Polymer, Textile and Fiber Engineering
Prof. Rina Tannenbaum
Georgia Institute of Technology
Materials Science and Engineering
Prof. Zhong Lin Wang
Georgia Institute of Technology
Materials Science and Engineering
Prof. Jaehong Kim
Georgia Institute of Technology
Civil and Environmental Engineering
Dr. Gene Kim
Cookson Electronics
Assembly Materials Group
Prof. Jongman Kim
Georgia Institute of Technology
Electrical and Computer Engineering
