• 한국분말재료학회지
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• 제16권6호
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• pp.389-395
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• 2009

A Si-CuO-graphite composite was prepared by a mechanical alloying (MA) method. The Si-CuO composite has a mixture structure, where CuO is homogeneously dispersed in Si. Also, $Cu_2O$ and $Cu_3Si$ phases were formed during MA and heat treatment. Graphite with the Si-CuO composite was mixed in the same mill for 30 minutes with weight ratio of Si-CuO composite and graphite as 1:1. The Si-CuO composite was homogeneously covered with graphite. SiC phase was not formed. Electrochemical tests of the composite have been investigated, and the first charge and discharge capacities of the material were about 870mAh/g and 660mAh/g, respectively. Those values are about 76% of the first cycle efficiency. The cycle life of the composite showed that the initial discharge capacity of 660 mAh/g could be maintained up to 92% after 20 cycles.

• 전기화학회지
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• 제13권4호
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• pp.235-239
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• 2010

The $Li_4Ti_5O_{12}$/CNT composite is prepared by ultrasound associated sol-gel method. The prepared composite is characterized by SEM, TEM, XRD and TG analysis, and their electrochemical behaviors are investigated by cyclic voltammetry, electrochemical impedance spectroscopy and charge-discharge test in 1M $LiBF_4$/PC electrolyte. From the results, it is identified that the $Li_4Ti_5O_{12}$ nanoparticles coated on CNT surface have regular size with around 10~30 nm and spinel-framework structure. At the current rate of 20C, the discharge capacities of $Li_4Ti_5O_{12}$/CNT composites with CNT contents of 15, 30 and 50 wt% are 57, 63 and $48mAhg^{-1}$, respectively, which have similar value. The improved electrochemical behavior of the $Li_4Ti_5O_{12}$/CNT composite electrode is attributed to the addition of CNT with electronic conductivity.

• 한국분말재료학회지
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• 제23권2호
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• pp.136-142
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• 2016

As precursors of cathode materials for lithium ion batteries, $Ni_{1/3}Co_{1/3}Mn_{1/3}(OH)_2$ powders are prepared in a continuously stirred tank reactor via a co-precipitation reaction between aqueous metal sulfates and NaOH in the presence of $NH_4OH$ in air or nitrogen ambient. Calcination of the precursors with $Li_2CO_3$ for 8 h at $1,000^{\circ}C$ in air produces dense spherical cathode materials. The precursors and final powders are characterized by X-ray diffraction (XRD), scanning electron microscopy, particle size analysis, tap density measurement, and thermal gravimetric analysis. The precursor powders obtained in air or nitrogen ambient show XRD patterns identified as $Ni_{1/3}Co_{1/3}Mn_{1/3}(OH)_2$. Regardless of the atmosphere, the final powders exhibit the XRD patterns of $LiNi_{1/3}Co_{1/3}Mn_{1/3}O_2$ (NCM). The precursor powders obtained in air have larger particle size and lower tap density than those obtained in nitrogen ambient. NCM powders show similar tendencies in terms of particle size and tap density. Electrochemical characterization is performed after fabricating a coin cell using NCM as the cathode and Li metal as the anode. The NCM powders from the precursors obtained in air and those from the precursors obtained in nitrogen have similar initial charge/discharge capacities and cycle life. In conclusion, the powders co-precipitated in air can be utilized as precursor materials, replacing those synthesized in the presence of nitrogen injection, which is the usual industrial practice.

• 한국분말재료학회지
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• 제23권4호
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• pp.287-296
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• 2016

$Ni_{1/3}Co_{1/3}Mn_{1/3}(OH)_2$ powders have been synthesized in a continuously stirred tank reactor via a co-precipitation reaction between aqueous metal sulfates and NaOH using $NH_4OH$ as a chelating agent. The co-precipitation temperature is varied in the range of $30-80^{\circ}C$. Calcination of the prepared precursors with $Li_2CO_3$ for 8 h at $1000^{\circ}C$ in air results in Li $Ni_{1/3}Co_{1/3}Mn_{1/3}O_2$ powders. Two kinds of obtained powders have been characterized by X-ray diffraction (XRD), scanning electron microscopy, particle size analyzer, and tap density measurements. The co-precipitation temperature does not differentiate the XRD patterns of precursors as well as their final powders. Precursor powders are spherical and dense, consisting of numerous acicular or flaky primary particles. The precursors obtained at 70 and $80^{\circ}C$ possess bigger primary particles having more irregular shapes than those at lower temperatures. This is related to the lower tap density measured for the former. The final powders show a similar tendency in terms of primary particle shape and tap density. Electrochemical characterization shows that the initial charge/discharge capacities and cycle life of final powders from the precursors obtained at 70 and $80^{\circ}C$ are inferior to those at $50^{\circ}C$. It is concluded that the optimum co-precipitation temperature is around $50^{\circ}C$.

• 한국수소및신에너지학회논문집
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• 제8권3호
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• pp.137-141
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• 1997

The effects of Ag addition to Zr-based hydrogen storage alloys ($Zr_{0.7}Ti_{0.3}V_{0.4}Ni_{1.2}Mn_{0.4}$, $Zr_{0.7}Ti_{0.3}V_{0.4}Ni_{1.2}Mn_{0.3}Cr_{0.1}$ and $Zr_{0.6}Ti_{0.4}V_{0.4}Ni_{1.2}Mn_{0.3}Fe_{0.1}$) on the electrode properties were examined. Ag-free and Ag-added Ze-based alloys were prepared by arc melting, crushed mechanically, and subjected to the electrochemical measurement. In $Zr_{0.7}Ti_{0.3}V_{0.4}Ni_{1.2}Mn_{0.4}$ alloy, 0.08 wt% Ag addition to the alloy improved the activation rate. Also Ag addition improved both activation property and discharge capacity in $Zr_{0.7}Ti_{0.3}V_{0.4}Ni_{1.2}Mn_{0.3}Cr_{0.1}$. For these Ag-added alloys, discharge capacities with the change of charge-discharge current density(10mA, 15mA and 30mA) are almost constant. Showing very high rate capability, discharge capacity of $Zr_{0.6}Ti_{0.4}V_{0.4}Ni_{1.2}Mn_{0.3}Fe_{0.1}$ alloy increased by Ag addition to the alloy. When the amount of Ag addition in $Zr_{0.7}Ti_{0.3}V_{0.4}Ni_{1.2}Mn_{0.4}$ alloy increased too much, the electrode properties became worse. Unveiling mechanism of effect of Ag addition is now progressing in our laboratory.

• 한국수소및신에너지학회논문집
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• 제26권2호
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• pp.170-178
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• 2015

In this study, we carry out a study on how to improve performance of vanadium redox flow battery (VRFB) through promoting reaction rate of rate determining vanadium reaction ($[VO]^{2+}/[VO_2]^+$). In order to do that, three different carbons like Vulcan (XC-72), CMK3 and MSU-F-C are adopted as the catalysts, while their catalytic activity and reaction reversibility are evaluated using half-cell tests. Their topological images are also measured by TEM. For estimation of the VRFB performance, multiple charge-discharge curves of VRFBs including the catalysts are measured by single cell tests. As a result of that, MSU-F-C shows relatively excellent catalytic activity and reaction reversibility as well as large surface area compared to those of Vulcan (XC-72) and CMK3. Also, in terms of the performance of VRFBs including the catalysts, VRFB including MSU-F-C indicates (i) low charging/discharging overpotentials and low internal resistance, (ii) high charge/discharge capacities and (iii) high energy efficiency. These VRFB performance data are well agreed with results on catalytic activity and reaction reversibility. The reason that MSU-F-C induces superior VRFB performances is attributed to (i) its large surface area and (ii) its hydrophilic surface functional groups that mainly consist of hydroxyl bonds that are supposed to play active surface site role for facilitaing $[VO]^{2+}/[VO_2]^+$ redox reaction. Based on the above results, it is found that adoption of MSU-F-C as catalyst for VRFB results in improvement in VRFB performance by promoting the languid $[VO]^{2+}/[VO_2]^+$ redox reaction.

• 한국전기전자재료학회논문지
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• 제30권7호
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• pp.447-453
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• 2017

In this study, $Li_2MnSiO_4$ cathode material and LiPON solid electrolyte were manufactured into thin films, and the possibility of their use in thin-film batteries was researched. When the RTP treatment was performed after $Li_2MnSiO_4$ cathode thin-film deposition on the SUS substrate by a sputtering method, a ${\beta}-Li_2MnSiO_4$ cathode thin film was successfully manufactured. The LiPON solid electrolyte was prepared by a reactive sputtering method using a $Li_3PO_4$ target and $N_2$ gas, and a homogeneous and flat thin film was deposited on a $Li_2MnSiO_4$ cathode thin film. In order to evaluate the electrochemical properties of the $Li_2MnSiO_4$ cathode thin films, coin cells using only a liquid electrolyte were prepared and the charge/discharge test was conducted. As a result, the amorphous thin film of RTP treated at $600^{\circ}C$ showed the highest initial discharge capacity of about $60{\mu}Ah/cm^2$. In cases of coin cells using liquid/solid double electrolyte, the discharge capacities of the $Li_2MnSiO_4$ cathode thin films were comparable to those without solid LiPON electrolyte. It was revealed that $Li_2MnSiO_4$ cathode thin films with LiPON solid electrolyte were applicable in thin film batteries.

• 항공우주시스템공학회지
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• 제18권4호
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• pp.53-60
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• 2024

본 연구에서는 향후 위성 구조체 적용을 위해 하중 지지와 에너지 저장을 동시에 수행하는 전지를 개발하기 위한 사전 연구로서 고강도 탄소 섬유와 유리 섬유를 이용한 코인 셀 전지를 제작하였다. 전도성 고분자가 증착된 섬유 기반 전극과 전해질을 제작하고, 코인 셀에 적용시켜 전기화학적 성능을 평가하였다. 그 결과, 연속 충·방전과 고방전율(2 C-rate)에 따른 방전 용량은 각각의 122.9, 103.5 mAh/g이 도출되어 고강도 섬유가 기존의 전지 요소를 대체할 수 있음을 확인하였다. 이는 상용 전지 대비 낮은 수준이지만 다기능성 에너지 저장장치의 구현을 위한 기초 연구로서 유의미한 결과를 보여주었으며, 향후 인공위성용 구조전지 개발에 활용될 것으로 기대한다.

• 에너지공학
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• 제22권2호
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• pp.175-183
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• 2013

차량 전기 시스템의 최적 설계를 위해 납축전지의 동적 거동을 예측하는 것은 중요하다. 동적 거동을 예측하기 위해서는 믿을만한 모델링 프로그램이 필요하다. 본 연구에서는 1차원 모델링을 통하여 12V 차량용 납축전지의 동적거동을 예측하였다. 수학적 모델에는 전기화학반응과 전지 내부에서 일어나는 이온 물질전달을 포함하였다. 모델링을 검증하기 위해 용량이 다른 2개(68Ah, 90Ah)의 납축전지 모델링 결과를 실험 결과와 비교하였다. 본 연구에서 사용한 납축전지는 현대자동차 차량에 적용되는 납축전지를 사용하였다. 방전 실험의 조건은 C/3, C/5, C/10, C/20의 방전율을 조합하여 진행하였다. 그리고 충전과 방전이 연속적으로 일어나는 동적 실험을 수행하였다. 모델링 결과와 실험 결과를 비교하여 보면 모델링 결과가 실험결과를 잘 예측하는 것을 볼 수 있다. 모델링은 고체상과 액체상에서의 전위분포와 전극 내에서 전류밀도에 근거한 모델링은 충 방전 시간의 함수로 예측할 수 있다.

• 전기화학회지
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• 제2권3호
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• pp.123-129
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• 1999

리튬이온전지용 $LiCoO_2$ 전극의 super s black 도전재료의 함량에 따른 초기 충방전 특성을 1 mol/l $LiPF_6/EC+DEC(1:3\;by\;w/w)$의 전해액에서 리튬기준전극에 대하여 4.3 V에서 2.0 V의 전위 구간에 대하여 C/4 및 C/2율로 충방전하여 측정하였다. 최초의 충전과정에서 high impedance충전 특성을 보였으며, super s black도전재료를 $3\%w/w$ 사용한 경우, $0.5 mA/cm^2$ 전류밀도의 충전에서 high impedance의 해소에 따라 $3.82\;{\Omega}\;{\cdot}\;g-LiCoCo_2$의 저항 감소를 나타내었으며, $0.728\;{\Omega}{\cdot}g-LiCoCo_2$의 전극저항과 비교하여 약 7배 높은 값을 나타내었다. 제2차 충전에의 high impedance해소는 약 $63\;{\Omega}{\cdot}g-LiCoCo_2$으로서 전극저항의 $12\%$ 정도이며, 제1차 충전의 high impedance해소에 비하여 $1.7\%$의 수준으로 감소하였다. 제1차 충전 및 방전 비용량은 C/4방전율에서 각각 160-161 및 $153\~155mAh/g-LiCoO_2$으로, 쿨롱효율은 $95.4\~96.4\%$였으며, 비가역 비용량은 약 6 mAh/g-$LiCoO_2$였다. 충전종료 지점에서 측정한 비저항은 도전재료 함량 $2\~7\%w/w$범위에서 낮은 값을 나타내어 비가역 비용량 특성의 변화와 일치하였다. 도전재료의 함량 증가에 따라 용량밀도가 감소하였으며, C/4율 방전에서 super s black함량 $2\%w/w$와 $2.9\%w/w$의 도전재료를 사용한 전극의 용량밀도는 각각 447mAh/ml 및 431 mAh/ml였다