• 대한전기학회논문지:전기물성ㆍ응용부문C
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• 제55권2호
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• pp.76-81
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• 2006

This paper analysed the characteristics of current density induced inside human body by 60 Hz extremely low frequency magnetic fields according to varying conductivities of human model. Human model was composed of several organs and other parts, whose shapes were expressed by spheroids or cylinders. Organs such as the brain, heart, lungs, liver and intestines were taken into account. Applying the boundary element method to the human model, we estimated effects on the induced current distribution due to differences of the organ conductivity and shape. We find organ conductivity influences most and a cross section area and a position of organ also gives effects.

• 대한전기학회:학술대회논문집
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• 대한전기학회 2004년도 하계학술대회 논문집 A
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• pp.581-583
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• 2004

This paper analysed the induced current density characteristics inside human body by extremely low frequency magnetic fields according to varying conductivities of human model. Human model was composed of several organs and other parts of 곳 human body, whose shapes were spheroids or cylinders. Organs taken into account were the brain, heart, lungs, liver and intestines. Applying the boundary element method to the human model, effects of the organ conductivity difference to the induced current distribution were estimated.

• 한국작물학회:학술대회논문집
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• 한국작물학회 2017년도 9th Asian Crop Science Association conference
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• pp.35-35
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• 2017

How do plants take up water from soils especially when water is scarce in soils? Plants have a strategy to respond to water deficit to manage water necessary for their survival and growth. Plants regulate water transport inside them. Water flows inside the plant via (i) apoplastic pathway including xylem vessel and cell wall and (ii) cell-to-cell pathway including water channels sitting in cell membrane (aquaporins). Water transport across the root and leaf is explained by a composite transport model including those pathways. Modification of the components in those pathways to change their hydraulic conductivity can regulate water uptake and management. Apoplastic barrier is modified by producing Casparian band and suberin lamellae. These structures contain suberin known to be hydrophobic. Barley roots with more suberin content from the apoplast showed lower root hydraulic conductivity. Root hydraulic conductivity was measured by a root pressure probe. Plant root builds apoplastic barrier to prevent water loss into dry soil. Water transport in plant is also regulated in the cell-to-cell pathway via aquaporin, which has received a great attention after its discovery in early 1990s. Aquaporins in plants are known to open or close to regulate water transport in response to biotic and/or abiotic stresses including water deficit. Aquaporins in a corn leaf were opened by illumination in the beginning, however, closed in response to the following leaf water potential decrease. The evidence was provided by cell hydraulic conductivity measurement using a cell pressure probe. Changing the hydraulic conductivity of plant organ such as root and leaf has an impact not only on the speed of water transport across the plant but also on the water potential inside the plant, which means plant water uptake pattern from soil could be differentiated. This was demonstrated by a computer simulation with 3-D root structure having root hydraulic conductivity information and soil. The model study indicated that the root hydraulic conductivity plays an important role to determine the water uptake from soil with suboptimal water, although soil hydraulic conductivity also interplayed.

• 한국약용작물학회지
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• 제24권3호
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• pp.198-206
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• 2016

Background: Electrical conductivity (EC) and pH are important features of nutrient solution, affecting both growth and quality of crops by altering nutrient uptake. Methods and Results: The pH values of nutrient solutions were controlled at 5.0, 5.5, 6.0, 6.5 and EC values were controlled at 0.68, 0.84, 1.23, 1.41 dS/m. Gingesng root weights were higher during the initial growth period when the plants were treated with low pH and low EC nutrient solutions. However, the higher pH and EC levels, the greater the increase in the rate of root weight between the initial and middle growth periods. The highest ginsenoside amount changed during growth period. The total ginsenoside amount was highest in the root, and the lowest in leaves at 45 and 90 days after treatment, respectively, with solution at a pH of 6.0. After 135 days of treatment, the highest total ginsenoside amount was detected in root treated with soluton with EC values of 1.23 dS/m. Conclusions: For the cultivation of ginseng using a nutriculture system, the pH and EC values of nutrient solutions should to be controlled based on the stage of growth and targeted plant organ (root or leaves).

• 생태와환경
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• 제45권2호
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• pp.218-231
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• 2012

본 연구는 2005~2007년까지 3년에 걸쳐 폐광산 수계의 유출수에 의해 직접적으로 영향 받는 하천 및 대조군(Control, $C_o$) 하천에서 이 화학적 수질특성, 수질 내성도 및 트로픽 길드 특성, 다변수 생태모형(Multimetric Health Model)을 이용한 생태 건강도 평가 및 물리적 건강도 평가 모형(QHEI model)을 이용한 생물 서식지 평가를 실시하였다. 또한, 폐광산의 유출수에 대한 생태독성 평가를 위해 버들치(Rhynchocypris oxycephalus)를 이용하여 현장 Enclosure 노출시험(In situ Enclosure Bioassay)을 실시하였고, 해부학적 장기 조직의 평가지수 모형(Necropy-based Health Assessment Index, $N_b$-HAI)을 이용하여 대조군($C_o$)과 처리군(T)의 광산폐수의 영향을 평가하였다. 이들에 대한 장기 조직의 영향평가는 각 Enclosure에 10 개체씩 투입하여 지라(Spleen), 신장(Kidney), 아가미(Gill), 간(Liver), 눈(Eyes), 지느러미(Fins)의 조직분석(Tissue analysis)을 실시하였다. 대조군과의 비교평가에 따르면, 폐광산의 유출수는 하천수를 pH 3.2까지 떨어뜨려 강한 산성폐수와 유사한 특성을 보였고, 급격한 수소이온 증가 및 총용존물질(Total Dissolved Solid, TDS)의 증가를 가져왔다. 서식지 평가의 QHEI 모델 값은 지점별 유의한 차이(p>0.05)를 보이지 않은 반면, 다변수 생태모형(Multimetric Health Model)을 이용한 생태 건강도는 3년 동안 대조군($C_o$)에서 $M_m$-EH 모델 값은 16~20, 처리군($M_w$)에서는 0으로 폐광 유출수의 영향을 받는 지점에서는 "악화상태(P)"로 나타났다. 또한, Enclosure 노출평가 따르면, $N_b$-HAI 모델값은 3년 기간 동안 대조군에서 0~3으로 나타나 "최적~양호상태" (Ex~G)로 나타난 반면, 폐광 유출수의 Enclosure에 포함된 처리군(Treatment)에서 모델값은 모두 100 이상(범위: 100~137)을 상회하여 "악화상태(P)"로 평가되었으며, 크게 손상된 장기조직은 간(Liver), 신장(Kidney), 아가미(Gill)로 나타나 향후 폐광산 유출지역의 수질 및 생태관리가 시급한 것으로 사료되었다.