• 한국산림과학회지
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• 제103권4호
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• pp.593-598
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• 2014

본 연구는 주요 4개 난대수종에 대한 탄소배출계수를 개발하고 이를 이용하여 탄소저장/흡수량을 산정하고자 하였다. 대상 수종은 구실잣밤나무, 동백나무, 붉가시나무 및 종가시나무였으며, 이들에 대한 탄소배출계수는 다음과 같이 도출되었다. 탄소배출계수 중 하나인 목재기본밀도는 구실잣밤나무 0.583, 동백나무 0.657, 붉가시나무 0.833, 종가시나무 0.763이었으며, 이들 계수에 대한 불확도는 5.3~17.9%의 범위에 있는 것으로 나타났다. 바이오매스 확장계수는 구실잣밤나무 1.386, 동백나무 2.621, 붉가시나무 1.701, 종가시나무 2.123이었으며, 이들에 대한 불확도는 14.7~30.5%의 범위에 있었다. 또한 뿌리 함량비는 구실잣밤나무 0.454, 동백나무 0.356, 붉가시나무 0.191, 종가시나무 0.299이었으며, 이들에 대한 불확도는 19.8~35.7%의 범위에 있는 것으로 나타났다. 목재기본밀도 등 3개의 탄소배출계수는 모두 FAO에서 권장하는 40% 이하의 불확도를 갖고 있으므로 국가고유계수로 활용할 수 있을 것으로 판단된다. 난대지역에 분포하는 주요 4개 수종에 대한 탄소저장량을 산정한 결과, 구실잣밤나무 $186.10tCO_2/ha$, 동백나무 $280.63tCO_2/ha$, 붉가시나무 $344.04tCO_2/ha$, 종가시나무 $278.91tCO_2/ha$으로 나타났으며, 연간 탄소흡수량은 $6.65tCO_2/ha/yr$, $6.25tCO_2/ha/yr$, $11.70tCO_2/ha/yr$, $12.29tCO_2/ha/yr$으로 각각 나타났다. 이러한 정보는 난대지역 상록활엽수림 경영관리에 있어 중요한 정보가 될 것이며, 기후변화에 의한 산림 식생대 변화를 대비하는 정책적 자료로 활용될 수 있을 것으로 사료된다.

• 한국작물학회:학술대회논문집
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• 한국작물학회 2017년도 9th Asian Crop Science Association conference
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• pp.308-308
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• 2017

The low and unstable yield of soybean has been a major problem in Japan. Excess soil moisture conditions are one of the major factors to restrict soybean productivity. More than 80 % of soybean crops are cultivated in converted paddy fields which often have poor drainage. In central and eastern regions of Japan, the early vegetative growth of soybean tends to be restricted by the flooding damage because the early growth period is overlapped with the rainy season. Field observation shows that induced excess water stress in early vegetative stage reduces dry matter production by decreasing intercepted radiation by leaf and radiation use efficiency (RUE) (Bajgain et al., 2015). Therefore, it is necessary to evaluate the responses of soybean growth for excess water conditions to assess these effects on soybean productions. In this study, we aim to modify the soybean crop model (Sinclair et al., 2003) by adding the components of the restriction of leaf area development and RUE for adaptable to excess water conditions. This model was consist of five components, phenological model, leaf area development model, dry matter production model, plant nitrogen model and soil water balance model. The model structures and parameters were estimated from the data obtained from the field experiment in Tsukuba. The excess water effects on the leaf area development were modeled with consideration of decrease of blanch emergence and individual leaf expansion as a function of temperature and ground water level from pot experiments. The nitrogen fixation and nitrogen absorption from soil were assumed to be inhibited by excess water stress and the RUE was assumed to be decreasing according to the decline of leaf nitrogen concentration. The results of the modified model were better agreement with the field observations of the induced excess water stress in paddy field. By coupling the crop model and the ground water level model, it may be possible to assess the impact of excess water conditions for soybean production quantitatively.