• 한국지반환경공학회 논문집
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• 제25권11호
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• pp.33-43
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• 2024

본 연구에서는 광양 지역의 가뭄 평가를 위해 광양 ASOS(Automated Synoptic Observing System) 기상관측소 자료를 활용하였다. 강수량 기반의 SPI와 강수량 및 증발산 손실을 고려한 두 가지 유형의 SPEI(SPEI_Thornthwaite 및 SPEI_Penman-Monteith)를 사용하여 가뭄 발생일수를 평가하였다. 광양 기상관측소의 SPI와 SPEI에 의해 산정된 가뭄 발생일수는 대체로 유사한 정량적 결과를 도출하였다. 그러나 물리적 기반의 Penman-Monteith 방법을 사용하는 SPEI_Penman-Monteith 지표는 SPI_Thornthwaite 지표에 비해 가뭄 발생일수가 더 높게 평가되었다. Penman-Monteith 방법에 의해 산정된 증발산량은 계절 변동성이 크고 수분 손실량도 큰 반면, Thornthwaite 방법에 의한 증발산량은 변동성이 작고 수분 손실량도 작게 평가되었다. 그 결과 SPEI_Penman-Monteith 지표에 비해 SPEI_Thornthwaite 지표가 SPI 지표와 더 높은 상관관계를 보였다. 물리적 모형 기반의 SPEI_Penman-Monteith 지표는 물의 순환에 따른 수분 손실량을 더 정확하게 산정할 수 있기 때문에 가뭄 발생일수 산정에서 더 합리적인 결과가 도출된다. 하지만 대부분의 ASOS 기상관측소에서는 일사량과 같은 고품질 기상자료가 충분하지 않기 때문에 Penman-Monteith 방법을 적용하기는 어렵다. 따라서, 이런 경우에는 월평균 기온만으로 증발산량을 추정할 수 있는 SPEI_Thornthwaite 지표가 가뭄지수 산정의 대안으로써 활용할 수 있다.

• Journal of Ecology and Environment
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• 제33권1호
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• pp.47-57
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• 2010

To understand day-to-day fluctuations in soil moisture content in Seoul, I simulated daily soil moisture content from 1908 to 2009 using long-term climatic precipitation and temperature data collected at the Surface Synoptic Meteorological Station in Seoul for the last 98 years with a hydrological simulation model, BROOK. The output data set from the BROOK model allowed me to examine day-to-day fluctuations and the severity and duration of droughts in the Seoul area. Although the soil moisture content is highly dependent on the occurrence of precipitation, the pattern of changes in daily soil moisture content was clearly quite different from that of precipitation. Generally, there were several phases in the dynamics of daily soil moisture content. The period from mid-May to late June can be categorized as the initial period of decreasing soil moisture content. With the initiation of the monsoon season in late June, soil moisture content sharply increases until mid-July. From the termination of the rainy season in mid-July, daily soil moisture content decreases again. Highly stochastic events of typhoons from late June to October bring large amount of rain to the Korean peninsula, culminating in late August, and increase the soil moisture content again from late August to early September. From early September until early October, another sharp decrease in soil moisture content was observed. The period from early October to mid-May of the next year can be categorized as a recharging period when soil moisture content shows an increasing trend. It is interesting to note that no statistically significant increase in mean annual soil moisture content in Seoul, Korea was observed over the last 98 years. By simulating daily soil moisture content, I was also able to reconstruct drought phenomena to understand the severity and duration of droughts in Seoul area. During the period from 1908 to 2009, droughts in the years 1913, 1979, 1939, and 2006 were categorized as 'severe' and those in 1988 and 1982 were categorized as 'extreme'. This information provides ecologists with further potential to interpret natural phenomenon, including tree growth and the decline of tree species in Korea.

• 한국수자원학회논문집
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• 제54권10호
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• pp.769-777
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• 2021

본 연구에서는 낙동강 유역의 수질관리에 미치는 기상학적 가뭄의 영향을 평가하였다. 3개의 가뭄지수(30일-, 60일-, 90일-표준강수지수)를 바탕으로 심한 가뭄의 발생여부를 판단하고, 생화학적산소요구량(BOD), 총유기탄소량(TOC), 그리고 총인(T-P)에 대한 목표수질 달성비율을 분석하여, 계절에 따른 중권역의 심한 가뭄 발생이 수질관리에 큰 영향을 미치는 지역을 구분하였다. 이러한 중권역에 대하여 베이지안 네트워크 모형을 이용한 가뭄-수질관리 간의 인과관계를 확률론적으로 해석하였다. 낙동강유역의 22개 중권역 중 4개의 중권역(#2005(영강), #2018(남강댐), #2021(밀양강), #2022(낙동강하구언))이 심한가뭄에 대한 수질관리에 취약성이 큰 것으로 나타났다. 또한, 봄과 가을철 수질관리에 미치는 가뭄의 영향이 가장 큰 지역은 #2021, 여름철은 #2005, 겨울철은 #2022인 것으로 나타났다. 이러한 가뭄과 수질관리 간의 인과관계에 대한 분석결과는 사전적 가뭄관리에서의 활용도가 클 것이다.

• 한국작물학회:학술대회논문집
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• 한국작물학회 2022년도 추계학술대회
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• pp.25-25
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• 2022

Drought becomes frequent and severe because of continuous global warming, leading to a significant loss of crop yield. In soybean (Glycine max [L.]), most of quantitative trait loci (QTLs) analyses for drought tolerance have conducted by investigating yield changes under water-restricted conditions at the reproductive stages. More recently, the necessity of QTL studies to use physiological indices responding to drought at the early growth stages besides the reproductive ones has arisen due to the unpredictable and prevalent occurrence of drought throughout the soybean growing season. In this study, we thus identified QTLs conferring wilting scores and moisture contents of soybean subjected to drought stress in the early vegetative stage using an recombinant inbred line (RIL) population derived from a cross between Taekwang (drought-sensitive) and SS2-2 (drought-tolerant). For the two traits, the same major QTL was located on chromosome 10, accounting for up to 11.5% of phenotypic variance explained with LOD score of 12.5. This QTL overlaps with a reported QTL for the limited transpiration trait in soybean and harbors an ortholog of the Arabidopsis ABA and drought-induced RING-D UF1117 gene. Meanwhile, one of important features of plant drought tolerance is their ability to limit transpiration rates under high vapor pressure deficiency in response to mitigate water loss. However, monitoring their transpiration rates is time-consuming and laborious. Therefore, only a few population-level studies regarding transpiration rates under the drought condition have been reported so far. Via employing an Arduino-based platform, for the reasons addressed, we are measuring and recording total pot weights of soybean plants every hour from the 1^st day after water restriction to the days when the half of the RILs exhibited permanent tissue damage in at least one trifoliate. Gradual decrease in moisture of soil in pots as time passes refers increase in the severity of drought stress. By tracking changes in the total pot weights of soybean plants, we will infer transpiration rates of the mapping parents and their RILs according to different levels of VPD and drought stress. The profile of transpiration rates from different levels of severity in the stresses facilitates a better understanding of relationship between transpiration-related features, such as limited maximum transpiration rates, to water saving performances, as well as those to other drought-responsive phenotypes. Our findings will provide primary insights on drought tolerance mechanisms in soybean and useful resources for improvement of soybean varieties tolerant to drought stress.

• Current Research on Agriculture and Life Sciences
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• 제5권
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• pp.143-157
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• 1987

In order to determine the design precipitation, the most probable daily precipitation and annual precipitation at every spot are calculated and iso - precipitation line are drawn. Probability of precipitation and drought phenomena of each gage station are analyzied by the method of frequency analysis from the statistical conceptions. The results summarized in this study are as the follows. 1. Annual mean precipitation in kyungpook area are 1044 mm, about 115 mm less than annual mean precipitation of Korea amounts to l1S9mm, and found to regionally unequal. 2. Monthly mean rainfall of July is 242.2mm, 23.2%, August 174.2mm, 16.7%, June 115mm, 11% and September 114.2mm, 10.9% and Rainfall depth of July-August are more than 40% of annual precipition. This shows notable summer rainy weather by typoon and low pressure storm and seasonal unbalance of water supply. 3. The relation among the maximum precipi.tation per day, per two continuous days and per three contnous days are caculated and the latter is found 31.0% increased rate of the first and the last 48.2% increased rate of first. 4. Probability precipitation in Kyungpook area are shown as 9.0%(5 year), 13.3%(10 year), 17.7%(20 year), 23.1%(50 year), 27.0%(100 year) and 31.1%(200 year) increased rate of each recurrence year compared with observed average annual precipitation. 5. From annual precipitation and maximum daily rainfall data probability of precipitation and precipitation isohyetal line are derived which shown as Table 11 and Fig. 8. 6. Drought days are divided 6 class and analysed results are shown on table 12. Average occurrence time of 10-14 continuous drought days are 2.3 time per year, 15-19 days are 0.9 time per year, 20-24 days are one per six years, 30-34 days are once per nine years and over than 35days are once per 25 years.