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Kim, Taesung (김태성)

Department
Department of Mechanical Engineering(기계공학과)
Website
http://www.ufnm.unist.ac.kr/
Lab
Microfluidics & Nanomechatronics Lab. (미세유체 및 나노메카트로닉스 연구실)
Research Keywords
미세유체역학, 바이오멤스, 나노메카트로닉스, Microfluidics, BioMEMS, Nanomechanics
Research Interests
The long term research goal of MicroFluidics and NanoMechatronics (uFNM) lab. is to create novel micro-/nanofluidic technologies that develop a broad spectrum of interdisciplinary research fields. Currently, of uFNM lab. focuses on four research fields such as Microfluidics (Fluid Mechanics at Micro/Nano-scale), NanoMechatronics (Automation of Micro-/Nano scale Systems and Device), Multi-Physics simulation (Numerical Simulation of Fluids, Ions, Colloids and Devices) and Printing in 2D and 3D Manners (Micro/Nanofabrication)
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Issue DateTitleAuthor(s)TypeViewAltmetrics
2017-09Long-Term and Programmable Bacterial Subculture in Completely Automated MicrochemostatsKim, Minseok; Bae, Juyeol; Kim, TaesungARTICLE457 Long-Term and Programmable Bacterial Subculture in Completely Automated Microchemostats
2017-07A cracking-assisted micro-/nanofluidic fabrication platform for silver nanobelt arrays and nanosensorsKim, Dong-Joo; Ha, Dogyeong; Zhou, Qitao, et alARTICLE582 A cracking-assisted micro-/nanofluidic fabrication platform for silver nanobelt arrays and nanosensors
2017-06A Hierarchical Nanostructure-Based Surface-Enhanced Raman Scattering Sensor for Preconcentration and Detection of Antibiotic PollutantsQitao, Zhou; Meng, G; Liu, Jing, et alARTICLE709 A Hierarchical Nanostructure-Based Surface-Enhanced Raman Scattering Sensor for Preconcentration and Detection of Antibiotic Pollutants
2017-05Inkjet-printed Ag micro-/nanostructure clusters on Cu substrates for in-situ pre-concentration and surface-enhanced Raman scatteringZhou, Qitao; Thokchom, Ashish Kumar; Kim, Dong-Joo, et alARTICLE824 Inkjet-printed Ag micro-/nanostructure clusters on Cu substrates for in-situ pre-concentration and surface-enhanced Raman scattering
2016-11Unconventional micro-/nanofabrication technologies for hybrid-scale lab-on-a-chipHa, Dogyeong; Hong, Jisoo; Shin, Heungjoo, et alARTICLE936 Unconventional micro-/nanofabrication technologies for hybrid-scale lab-on-a-chip
2016-08Inkjet Printing Based Mono-layered Photonic Crystal Patterning for Anti-counterfeiting Structural ColorsNam, Hyunmoon; Song, Kyungjun; Ha, Dogyeong, et alARTICLE1067 Inkjet Printing Based Mono-layered Photonic Crystal Patterning for Anti-counterfeiting Structural Colors
2016-08Directional Reflective Surface Formed via Gradient-Impeding Acoustic Meta-SurfacesSong, Kyungjun; Kim, Jedo; Hur, Shin, et alARTICLE858 Directional Reflective Surface Formed via Gradient-Impeding Acoustic Meta-Surfaces
2016-05Development of a highly specific and sensitive cadmium and lead microbial biosensor using synthetic CadC-T7 genetic circuitryKim, Hyun Ju; Lim, Ji Won; Jeong, Haeyoung, et alARTICLE762 Development of a highly specific and sensitive cadmium and lead microbial biosensor using synthetic CadC-T7 genetic circuitry
2016-05Review of Microfluidic Approaches for Surface-enhanced Raman ScatteringKim, Taesung; Zhou, QitaoARTICLE612 Review of Microfluidic Approaches for Surface-enhanced Raman Scattering
2016-05Cracking-assisted Fabrication of Nanoscale Patterns for Micro/Nanotechnological ApplicationsKim, Minseok; Kim, Dong-Joo; Ha, Dogyeong, et alARTICLE804 Cracking-assisted Fabrication of Nanoscale Patterns for Micro/Nanotechnological Applications
2016-05A Microfluidic Platform for High-Throughput Screening of Small Mutant LibrariesLim, Ji Won; Shin, Kwang Soo; Moon, Jaemin, et alARTICLE719 A Microfluidic Platform for High-Throughput Screening of Small Mutant Libraries
2016-03Self-assembled particle membranes for in situ concentration and chemostat-like cultivation of microorganisms on a chipLee, Jongwan; Kim, Minseok; Park, Jungyul, et alARTICLE696 Self-assembled particle membranes for in situ concentration and chemostat-like cultivation of microorganisms on a chip
2015-11Crack-photolithography for Membrane-free Diffusion-based Micro/Nanofluidic DevicesKim, Minseok; Kim, TaesungARTICLE759 Crack-photolithography for Membrane-free Diffusion-based Micro/Nanofluidic Devices
2015-05Review of micro/nanotechnologies for microbial biosensorsLim, Ji Won; Ha, Dogyeong; Lee, Jongwan, et alARTICLE687 Review of micro/nanotechnologies for microbial biosensors
2015-03Chemostat-like microfluidic platform for highly sensitive detection of heavy metal ions using microbial biosensorsKim, Minseok; Lim, Ji Won; Kim, Hyun Ju, et alARTICLE1574 Chemostat-like microfluidic platform for highly sensitive detection of heavy metal ions using microbial biosensors
2015-02Microfluidic static droplet array for analyzing microbial communication on a population gradientJeong, Heon-Ho; Jin, Si Hyung; Lee, Byung Jin, et alARTICLE679 Microfluidic static droplet array for analyzing microbial communication on a population gradient
2015-02Cracking-assisted photolithography for mixed-scale patterning and nanofluidic applicationsKim, Minseok; Ha, Dogyeong; Kim, TaesungARTICLE933 Cracking-assisted photolithography for mixed-scale patterning and nanofluidic applications
2014-10Aptamer-functionalized microtubules for continuous and selective concentration of target analytesKim, Minseok; Kim, TaesungARTICLE905 Aptamer-functionalized microtubules for continuous and selective concentration of target analytes
2014-10Multiphysics Simulation of Ion Concentration Polarization Induced by a Surface-Patterned Nanoporous Membrane in Single Channel DevicesJia, Mingjie; Kim, TaesungARTICLE739 Multiphysics Simulation of Ion Concentration Polarization Induced by a Surface-Patterned Nanoporous Membrane in Single Channel Devices
2014-08Multiphysics simulation of ion concentration polarization induced by nanoporous membranes in dual channel devicesJia, Mingjie; Kim, TaesungARTICLE697 Multiphysics simulation of ion concentration polarization induced by nanoporous membranes in dual channel devices

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