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김정환,이응숙,황경현,유영은,윤재성,Kim, Jeong Hwan,Lee, Eung-Sug,Whang, Kyung-Hyun,Yoo, Yeong-Eun,Yoon, Jae-Sung 대한기계학회 2015 대한기계학회 논문집. Transactions of the KSME. C, 산업기술과 혁신 Vol.3 No.4
이온 및 분자 이송제어를 위한 기능성 나노채널의 구현을 통하여 이온/분자의 상대적 크기에 의존하는 기존 분리 및 이송 기술의 선택효율, 투과도, 에너지 소비 측면에서의 기존 분리 기술의 한계를 극복하기 위한 새로운 개념의 분리 기술을 제시 하고자 하였다. 이를 위해 나노채널 플랫폼 가공 기술 개발, 나노채널 표면 기능화 기술 개발 등의 연구를 수행하였으며, 나노채널에 대한 전압인가 및 유량 조절이 가능한 이온이송제어 측정 시스템을 제작하고, 다층 금속 멤브레인을 이용하여 선택적으로 특정 이온($Cl^-$)의 이송을 95% 이상 차단하였다. 본 연구를 통하여 세포막에 존재하며 물분자만을 매우 효율적으로 투과시키는 채널인 아쿠아포린의 기능 및 특성을 모방한 신개념의 분리기술 구현을 위한 기반 기술 개발을 수행하였으며, 향후 지속적인 연구를 통하여 차세대 정수/담수, 휴대형 인공신장, 인공 감각 기관 등의 핵심 기반 기술이 될 것으로 예상한다. Functional nanochannels were fabricated in order to control selective ion transportation with high permeability and low energy consumption. In this research, nanochannel platform fabrication process and surface functionalization process were developed. In addition, selective ion transportation and concentration measurement system was also set-up. By using fabricated multilayer metal membrane with electrical bias, 95% of ion ($Cl^-$) was blocked. This developed process is new-conceptional membrane fabrication technology and is expected to be applied to next-generation water purification/desalination, portable artifical kidney, and artificial sense organ.
빔 쉐이핑을 이용한 펨토초 레이저 ITO 박막 가공 깊이 제어에 대한 연구
김훈영,윤지욱,최원석,황경현,조성학,Kim, Hoon-Young,Yoon, Ji-Wook,Choi, Won-Seok,Stolberg, Klaus,Whang, Kyoung-Hyun,Cho, Sung-Hak 한국레이저가공학회 2014 한국레이저가공학회지 Vol.17 No.1
Indium tin oxide (ITO) is an important transparent conducting oxide (TCO). ITO films have been widely used as transparent electrodes in optoelectronic devices such as organic light-emitting devices (OLED) because of their high electrical conductivity and high transmission in the visible wavelength. Finding ways to control ITO micromachining depth is important role in the fabrication and assembly of display field. This study presented the depth control of ITO patterns on glass substrate using a femtosecond laser and slit. In the proposed approach, a gaussian beam was transformed into a quasi-flat top beam by slit. In addition, pattern of square type shaped by slit were fabricated on the surfaces of ITO films using femtosecond laser pulse irradiation, under 1030nm, single pulse. Using femtosecond laser and slit, we selectively controlled forming depth and removed the ITO thin films with thickness 145nm on glass substrates. In particular, we studied the effect of pulse number on the ablation of ITO. Clean removal of the ITO layer was observed when the 6 pulse number at $2.8TW/cm^2$. Furthermore, the morphologies and fabricated depth were characterized using a optical microscope, atomic force microscope (AFM), and energy dispersive X-ray spectroscopy (EDS).
극초단 펄스 레이저를 사용한 유리 내부의 필라멘테이션에 대한 실험적 연구
최원석,윤지욱,김주한,최지연,장원석,김재구,최두선,황경현,조성학,Choi, Won-Suk,Yoon, Ji-Wook,Kim, Joohan,Choi, Jiyeon,Chang, Won-Seok,Kim, Jae-Goo,Choi, Doo-Sun,Whang, Kyoung Hyun,Cho, Sung-Hak 한국레이저가공학회 2013 한국레이저가공학회지 Vol.16 No.1
We have successfully formed filament inside of a transparent soda-lime glass using a Ti:sapphire based femtosecond laser. To make filament form, keeping the laser intensity higher than critical intensity is essential. Also each of the machining parameters plays an important role for the formation of filament. In this paper, we study what parameter can possibly influence for formation of filament, and we introduce an application using filamentation by femtosecond laser for transparent material.
김성곤(Seong Kon Kim),서영호(Young Ho Seo),황경현(Kyung-Hyun Whang),최두선(Doo-Sun Choi) 대한기계학회 2008 大韓機械學會論文集B Vol.32 No.3
For the applications which need a micro-power supply such as thin and flat displays, micro-robot, and micro-system, it is especially necessary to integrate the passive components because they typically need more than 2/3 of the space of the conventional circuit. Therefore, we have designed and fabricated a novel piezoelectric micro transformer using the PZT thin film and MEMS technologies for application to the energy supply device of the micro-systems. The dimensions of the micro-transformer is 1000 ㎛ × 400 ㎛ × 4.8 ㎛ (length × width × thickness). The dynamic displacement of around 9.2 ± 0.064 ㎛ was observed at 10 V. The dynamic displacement varied almost linearly with applied voltage. The average voltage gain (step-up ratio) was approximately 2.13 at the resonant frequency (Fr=8.006 ㎑) and load resistance (RL) of 1 MΩ.