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조우석,정유희,김보경,서수정,고완수,최성화,Cho, Woo-Suk,Chung, Yu-Hee,Kim, Bo-Kyung,Suh, Su-Jeoung,Koh, Wan-Soo,Choe, Sung-Hwa 한국식물생명공학회 2007 식물생명공학회지 Vol.34 No.2
가속도가 붙은 지구온난화 문제와 수 십년 이내로 예상되는 화석연료의 고갈은 지속가능하면서도 환경친화적인 새로운 형태의 에너지 출현을 필요로 하고 있다. 이러한 추세에 맞추어 태양광, 조력, 지열, 풍력, 수소 에너지와 더불어 바이오에너지가 대체에너지로서 주목받고 있다. 바이오에너지는 태양에너지를 유기물로 변환하는 식물을 재료로 하여 바이오 에탄올이나 바이오디젤 등을 생산하여 사용하는 것으로 대체 에너지가 갖춰야 할 조건을 두루 갖춘 최적의 신재생에너지로 고려되고 있다. 하지만 바이오에너지가 진정한 의미에서의 환경친화적이면서 지속가능성을 갖추기 위해서는 아직 기술적으로 해결해야할 문제점들이 많다. 최근 미국에서 바이오에탄올 생산을 위한 옥수수 소비량이 늘어 곡물 및 사료 가격의 급등 현상으로 이어지고 있다. 또한 이러한 현상은 개발도상국 식량자원의 선진국 유입 등으로 빈곤의 심화 등이 새로운 문제점으로 지적되고 있다. 따라서 곡물이 아닌 비식용 부위를 이용한 에탄올 생산이 대안으로 여겨지고 있는 바 셀룰로스 에탄올은 이러한 문제점을 극복할 수 있는 대체에너지로서 자리매김하고 있다. 셀룰로스 바이오에탄올은 사람 등의 동물이 소화하지 못하는 바이오매스의 대부분을 차지하는 식물 세포벽을 곰팡이 등에서 분리한 효소로 분해한 후 여기서 생성되는 당을 발효과정을 통해 생산되는 에탄올로서 전술한 바와 같은 문제점을 해결할 수 있는 유망한 대안 에너지로 고려되고 있다. Global warming crisis due primarily to continued green house gas emission requires impending change to renewable alternative energy than continuously depending on exhausting fossil fuels. Bioenergy including biodiesel and bioethanol are considered good alternatives because of their renewable and sustainable nature. Bioethanol is currently being produced by using sucrose from sugar beet, grain starches or lignocellulosic biomass as sources of ethanol fermentation. However, grain production requires significant amount of fossil fuel inputs during agricultural practices, which means less competitive in reducing the level of green house gas emission. By contrast, cellulosic bioethanol can use naturally-growing, not-for-food biomass as a source of ethanol fermentation. In this respect, cellulosic ethanol than grain starch ethanol is considered a more appropriate as a alternative renewable energy. However, commercialization of cellulosic ethanol depends heavily on technology development. Processes such as securing enough biomass optimized for economic processing, pretreatment technology for better access of polymer-hydrolyzing enzymes, saccharification of recalcitrant lignocellulosic materials, and simultaneous fermentation of different sugars including 6-carbon glucose as well as 5-carbon xylose or arabinose waits for greater improvement in technologies. Although it seems to be a long way to go until commercialization, it should broadly benefit farmers with novel source of income, environment with greener and reduced level of global warming, and national economy with increased energy security. Mission-oriented strategies for cellulosic ethanol development participated by government funding agency and different disciplines of sciences and technologies should certainly open up a new era of renewable energy.
고화도 발색세라믹잉크를 이용한 잉크젯프린팅 도자타일 연구동향
김진호,노형구,김응수,조우석,최정훈,이용욱,Kim, Jin-Ho,Noh, Hyung-Goo,Kim, Ung-Soo,Cho, Woo-Suk,Choi, Jung-Hoon,Lee, Yong-Ouk 한국세라믹학회 2013 한국세라믹학회지 Vol.50 No.6
Over the past decade, the feasibility of using ink-jet printing for the decoration of porcelain tiles has been explored, and significant advances have been made regarding the technologies underlying printing system and materials. An ink-jet printing system for porcelain tiles has many advantages compared with a conventional printing system, including the following: (1) it is a digital process; (2) it uses non-contact printing; (3) it allows random image generation; (4) it is a highly efficient process (reduced production cost); (5) it offers massive and continuous production; and (6) it uses inorganic pigment colorants. For these reasons, ink-jet printing systems for porcelain tiles have been commercialized and are at present rapidly spreading toceramics-leading countries such as Spain, Italy, China and Japan. We also developed a proprietary system involving a piezo-electric drop-on-demand method and an ink-circulation step. The resolution of this system is greater than 360 dpi after a heat treatment and the maximum printable width is 600 mm, even when setting the printing head unit with four digital colors (cyan, magenta, yellow, and black). In addition, we systematically developed ceramic colorant-containing inks and tile-printing technology applicable to our ink-jet printing system.
착체중합법을 이용한 (Co,Mg)Al<sub>2</sub>O<sub>4</sub> 및 (Ni,Mg)Al<sub>2</sub>O<sub>4</sub> 청색 나노 무기안료 합성
손보람,윤대호,김진호,한규성,조우석,황광택,Son, Bo-Ram,Yoon, Dea-Ho,Kim, Jin-Ho,Han, Kyu-Sung,Cho, Woo-Suk,Hwang, Kwang-Taek 한국세라믹학회 2013 한국세라믹학회지 Vol.50 No.6
In this study, the properties of blue inorganic nano-pigments with a spinel structure were systematically investigated. We report the preparation of a blue ceramic nano-pigment and the Co and Ni substitutional effects on the blue color. $MgAl_2O_4$ was selected as the crystalline host network for the synthesis of cobalt and nickel-based blue ceramic nano-pigments. Various compositions of $Co_xMg_{1-x}Al_2O_4$ and $Ni_xMg_{1-x}Al_2O_4$ ($0{\leq}x{\leq}1$) powders were prepared using apolymerized complex method. The obtained powder was preheated at $400^{\circ}C$ for 5 h and then calcined at $1000^{\circ}C$ for 5 h. XRD patterns of the (Co,Mg)$Al_2O_4$ and (Ni,Mg)$Al_2O_4$ samples showed a single phase of the spinel structure in all compositions. TEM results indicated nano-sized pigments for (Co,Mg)$Al_2O_4$ and (Ni,Mg)$Al_2O_4$ with a particle size ranging from 20 to 50 nm. The characteristics of the color tones of (Co,Mg)$Al_2O_4$ and (Ni,Mg)$Al_2O_4$ were analyzed by CIE $L^*a^*b^*$ measurements. In addition, the thermal stability and the binding characteristics of (Co,Mg)$Al_2O_4$, (Ni,Mg)$Al_2O_4$ are discussed in terms of the TG-DSC and FT-IR results, respectively.
착체중합법을 이용한 (Ni,Mg)Al<sub>2</sub>O<sub>4</sub> Cyan 나노 무기안료 합성
손보람,윤대호,한규성,조우석,황광택,김진호,Son, Bo-Ram,Yoon, Dea-Ho,Han, Kyu-Sung,Cho, Woo-Suk,Hwang, Kwang-Taek,Kim, Jin-Ho 한국세라믹학회 2013 한국세라믹학회지 Vol.50 No.3
Here, we report preparation of cyan ceramic nano-pigment for inkjet printing and the Ni substitutional effects on the cyan color. $MgAl_2O_4$ was selected as the crystalline host network for the synthesis of nickel-based cyan ceramic nano-pigments. Various compositions of $Ni_xMg_{1-x}Al_2O_4$ ($0{\leq}x{\leq}1$) powders were prepared using the polymerized complex method. The powder was then preheated at $400^{\circ}C$ for 5 h and finally calcined at $1000^{\circ}C$ for 5 h. XRD patterns of $Ni_xMg_{1-x}Al_2O_4$ showed a single phase of the spinel structure in all the compositions. The particle sizes ranged from 20 to 50 nm in TEM observations. The characteristics of the color tones of $Ni_xMg_{1-x}Al_2O_4$ were analyzed by UV-Visible spectroscopy and CIE $L^*a^*b^*$ measurement. CIE $L^*a^*b^*$ measurement results indicate that the pigment color changes from light cyan to deep cyan due to the decrease of the $a^*$ and $b^*$ values with an increase of an Ni substitutional amount. In addition, the thermal stability and the binding nature of $Ni_xMg_{1-x}Al_2O_4$ are also discussed using TG-DSC and FT-IR results respectively.
제강분진을 활용한 고온발색 청색무기안료 합성 및 특성에 관한 연구
손보람,김진호,한규성,조우석,황광택,Son, Bo-Ram,Kim, Jin-Ho,Han, Kyu-Sung,Cho, Woo-Suk,Hwang, Kwang-Taek 한국세라믹학회 2014 한국세라믹학회지 Vol.51 No.3
Electric arc furnace dust (EAFD) is a solid waste generated by the steel-scrap recycling process. It mainly consists of zinc oxides (ZnO), alumina ($Al_2O_3$), iron oxides ($Fe_2O_3$), and silica ($SiO_2$). Here we report the preparation and characterization of blue ceramic pigments using EAFD powder as a starting material. $(Zn(EAFD),Co)Al_2O_4$ blue ceramic pigment was prepared by the solid-state reaction method. The color characteristics of the pigment obtained were compared with those of pure $CoAl_2O_4$. The new pigment was characterized using XRD, CIE-$L^*a^*b^*$ color-measurements, SEM, and EDX. The XRD analysis revealed that the $(Zn(EAFD),Co)Al_2O_4$ pigment was composed of mainly the spinel phase of $(Zn,Co)Al_2O_4$. The $Zn(EAFD)_{0.25}Co_{0.75}Al_2O_4$ pigments showed a vivid blue color with a $b^*$ value of -28.64 and a good glaze stability with a transparent glaze.