• 한국농공학회논문집
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• 제59권6호
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• pp.39-50
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• 2017

Growth monitoring of highland Kimchi cabbage is very important to respond the fluctuations in supply and demand from middle of August to early September in Korea. For evaluating Kimchi cabbage growth, it needs to classify the transplanting period of Kimchi cabbage, preferentially. This study was conducted to estimate the transplanting period of highland Kimchi cabbage from 2015 to 2016 in the main production area of highland Kimchi cabbage, Anbandegi, Maebongsan, and Gwinemi. Correlation between NDVI (Normalized Difference Vegetation Index) from UAV images and days after transplanting of Kimchi cabbage was high in early transplanting period. But because the growth curve of Kimchi cabbage showed S-type, joint use of multi-temporal linear regression equation for estimation of transplanting period was more suitable. Using application of these equations at Anbandegi, Maebongsan, and Gwinemi, we made the map of transplanting periods of highland Kimchi cabbage. Generally, highland Kimchi cabbage is harvested in sixty days later since transplanting. As a result, we could estimate the harvest time and area of highland Kimchi cabbage.

• 한국농공학회논문집
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• 제63권3호
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• pp.75-85
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• 2021

This study evaluated variations in the paddy rice water demand based on the continuous changing in rice transplanting period and ponding depth at the four study paddy fields, which represent typical rice producing regions in Korea. Total 7 scenarios on rice transplanting periods were applied while minimum ponding depth of 0 and 20 mm were applied in accordance with maximum ponding depth ranging from 40 mm to 100 mm with 20 mm interval. The weather data from 2013 to 2019 was also considered. The results indicated that the highest rice water demand occurred at high temperature and low rainfall region. Increased rice transplanting periods showed higher rice water demand. The rice water demand for 51 transplanting days closely matched with the actual irrigation water supply. In case of ponding depth, the results showed that the minimum ponding depth had a proportional relationship with rice water demand, while maximum ponding depth showed the contrary results. Minimum ponding depth had a greater impact on rice water demand than the maximum ponding depth. Therefore, these results suggest that increasing the rice transplanting period, which reflects the current practice is desirable for a reliable estimation of rice water demand.

• 한국잡초학회지
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• 제15권2호
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• pp.105-114
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• 1995

다섯 가지의 벼 재배유형(栽培類型)[관행(慣行) 손이앙(移秧), 중묘(中苗)(30일묘(日苗))의 기계이앙(機械移秧), 어린모(10일묘(日苗))의 기계이앙(機械移秧), 최아종자(催芽種子)의 담수직파(湛水直播) 및 건종자(乾種子)의 건담직파(乾畓直播)]에 따라 잡초발생(雜草發生) 양상(樣相)과 경합특성(競合特性)을 조사(調査)하여 벼 생육(生育)과 수량변화(收量變化)를 근거(根據)로 한 각(各) 재배류형별(栽培類型別) 벼와 잡초(雜草)와의 경합(競合) 한계기간(限界期間)의 모형(模型)으로 잡초(雜草) 방제기간(防除期間)을 설정(設定)하였다. 무잡초상태(無雜草狀態)를 연장(延長)시킴에 따라 30일묘(日苗)와 10일묘(日苗) 기계이앙(機械移秧) 및 직파재배(直播栽培)는 벼의 출수(出穗)가 무잡초구(無雜草區)에 비하여 1~2일정도(日程度) 지연(遲延)되었다. 잡초발생(雜草發生) 허용기간(許容期間)을 연장(延長)시킨 경우에는 관행이앙(慣行移秧), 30일묘(日苗) 및 10일묘(日苗) 기계이앙(機械移秧)에서는 출수기(出穗期)에서 차이(差異)가 없었으나, 직파재배(直播栽培)에서는 파종후(播種後) 7~10주(週)까지의 경합연장(競合延長)으로 출수(出穗)가 4~7일정도(日程度) 지연(遲延)되었다가 더욱 경합(競合)이 길어짐에 따라 5~6일정도(日程度) 앞당겨지는 현상(現狀)을 보였다. 재배양식별(栽培樣式別) 이앙후(移秧後) 및 파종후(播種後) 무잡초(無雜草) 유지(維持) 한계기간(限界期間)이 수량구성요소(收量構成要素)에 미치는 영향(影響)은 관행이앙(慣行移秧)에서는 이앙후(移秧後) 4주이내(週以內)에 발생(發生)된 잡초(雜草)에 의하여 등숙비율(登熟比率)과 천립중(千粒重)의 감소(減少)가 나타났으며, 10일묘(日苗) 기계이앙(機械移秧)에서는 조사(調査)된 모든 수량구성요소(水量構成要素)의 감소(減少)가 있었다. 직파재배(直播栽培)에서는 단위(單位) 면적당(面積當) 수수(穗數)는 파종후(播種後) 8~9주간(週間), 수당입수(穗當粒數)는 4~5주간(週間), 등숙비율(登熟比率)은 3~4주간(週間), 천립중(千粒重)은 8~10주간(週間)의 무제초(無除草)로 인(因)하여 감소(減少)되었다. 관행이앙재배(慣行移秧栽培)는 잡초방제(雜草防除) 요구기간(要求期間)으로서 이앙직후(移秧直後) 4주간(週間)에 걸쳐 무잡초(無雜草) 상태(狀態)를 유지(維持)해 주거나 이앙(移秧) 8주후(週後)부터 무잡초(無雜草) 상태(狀態)를 유지(維持)해주는 이중(二重) 대체기간(對替期間)이 설정(設定)되었다. 30일묘(日苗) 기계이앙재배(機械移秧栽培)는 관행이앙재배(慣行移秧載培)와 같이 이앙후(移秧後) 5주간(週間)에 걸친 무잡초(無雜草) 상태(狀態) 유지(維持) 또는 이앙후(移秧後) 8주(週)부터 유지(維持)되는 무잡초(無雜草) 상태(狀態)의 이중(二重) 대체기간(對替期間)이 설정(設定)되었다. 10일묘(日苗) 기계이앙재배(機械移秧栽培)는 잡초방제(雜草防除) 요구기간(要求期間)은 이앙후(移秧後) 5주간(週間) 또는 이앙(移秧) 7주후(週後)부터 무잡초(無雜草) 상태(狀態)를 유지(維持)해주는 이중(二重) 대체기간(對替期間)으로 설정(設定)되었다. 담수직파재배(湛水直播載培)는 파종후(播種後) 5주(週)부터 7주(週)까지의 단일기간중(單一期間中)에 잡초방제(雜草防除)가 요구(要求)되어 진다. 건답직파재배(乾畓直播栽培)는 잡초방제(雜草防除) 요구기간(要求期間)은 파종후(播種後) 6주(週)부터 9주(週)까지의 단일기간(單一期間)으로 설정(設定)되었다.

• Plant Resources
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• 제3권3호
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• pp.194-199
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• 2000

The result of this experiment which are conducted, to improve the cultivation technology of Alisma plantago, to increase its quantity and to contribute for stable production with Yongiun local group by examining the optimal planting density and transplanting period of double cropping of Alisma plantago in the southern region. The characters of plant height, leaf width and length tend to be reduced as the seeding period is later by the order of the 10th, 20th and 30th of July. The period required for flowering is reduced as the transplanting period is later and dense planting is applied. Plant height, the number of leaves and yield of dry root have much quantity at the dense planting density of 20$\times$ 15cm as they are transplanted later in the 30th of August or the 10th of September, but they are rather less in sparse planting density of 20$\times$25cm or 20$\times$35cm.

• 한국작물학회지
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• 제29권3호
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• pp.209-217
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• 1984

남부 다모작지대의 도작 증수재배법을 확립하고자 이앙시기를 5월 20일부터 7월 5일까지 15일 간격, 4시기로 하여 수량 형질 및 수량변이를 검토한 결과를 요약하면 다음과 같다. 1. 엽수의 변이는 서광벼에서는 5월 20일 이앙구의 16.2매에 대하여 만식한 7월 5일 이앙구는 15.1매로 1.1매가 적었고 동진벼는 5월 20일 이앙구 14.8매에 대하여 7월 5일 이앙구는 13.1매로 1.7매가 적었다. 2. 지엽단축률은 작기가 늦어짐에 따라 커지는 경향이었다. 3. 작기 이동에 따른 출수일수의 변이는 서광벼는 5월 20일 이앙에서 약 75 일, 6월 5일은 68일, 6월 20일은 67일 정도이었으나, 7월 5일은 71일이 소요되었다. 4. 재배시기에 따른 최대수량은 서광벼는 5월 20일, 동진벼는 6월 20일 이앙이었고 수량생산기의 적산온도와의 관계는 서광벼는 1017$\pm$24$^{\circ}C$에서, 동진벼는 952$\pm$15$^{\circ}C$에서 600kg/10a 이상의 고위수량을 보였다. 5. 단위면적당 수수는 작기가 늦어짐에 따라 직선적으로 감소되는 부의 유의 상관관계(서광벼 r=-0.6768＊＊, 동진벼 r=-0.5182＊＊)가 인정되었다. 6. 작기 이동에 따른 1수 영화수는 서광벼는 작기가 늦어짐에 따라 많아졌고 동진벼는 작기가 빠르거나 늦은 경우 감소경향을 보였다.

• 한국농림기상학회지
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• 제5권3호
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• pp.191-199
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• 2003

Optimum transplanting time for extremely early rice cultivation as an after-crop of fruit and vegetables under greenhouse conditions in the southern area was determined. Rice was transplanted on March 10, March 20, March 30, April 10 and April 20 far three years from 1998 to 2000. Meteorological computations for rice production were high for heading between early May and early July, but they were too low for heading between late July and early August. Especially the expected yield predicted with 35,000 spikelets, the average spikelets per $m^2$ for extremely early transplanting. Computation for heading between late July and early August was low by 106 kg/10a compared with that yield at heading during the same period in the field. As the transplanting date in extremely early rice cultivation was earlier) rice growth at early stages was more retarded by low temperature. Rice growth at heading stage recovered with high temperature, showing less difference for the transplanting date. Abnormal tillers occurred by 15.5∼22.2%. The contribution of 1,000 grain weight${\times}$ripened grain ratio to yield of the extremely early rice cultivation in the greenhouse was 50.6%, indicating 16% hi일or than the degree of panicle per $m^2$ on yield. The estimated optimum transplanting time on the basis of yield for the extremely early greenhouse rice cultivation ranged from March 19 to April 28, and the estimated critical transplanting date on the basis of accumulated effective temperature was March 12. Rice reduced the amount of NO$_3$-N by 97.1% and EC by 90.5% in greenhouse soil with continuous fruit/vegetables fer more than a 10-year period, and completely removed the root-knot nematodes.

• 한국작물학회:학술대회논문집
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• 한국작물학회 2022년도 추계학술대회
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• pp.171-171
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• 2022

Effect of temperature during the period of 10 days from transplanting (10 DFT) on the growth and development of rice plants was investigated by transplanting semi-adult seedlings six times from 5 April to 15 May at 10-day interval in the field conditions of 2020 and 2021, with aims to investigate the critical temperature for early transplanting of temperate rice. In the two experimental years, mean temperature for 10 DFT appeared 9.1, 10.5, 11.6, 13.8, 13.9, 16.2, 16.4, 16.7, 17.1, 17.8℃ depending on the transplanting date. Mean temperature of 9.1℃ and 10.5℃ for 10 DFT appeared in the April 5 and April 15 transplants in 2020 showed negative or no effect on the increase of rice growth and acceleration of heading date when compared to those of right after transplanting treatments in the same year. Mean temperature of 11.6℃ for 10 DFT appeared in the April 5 transplant in 2021 demonstrated greater biomass from early to heading stage but the same heading date compared to April 15 transplant, indicating that 11.6℃ for 10 DFT had a positive effect on rice growth but no effect on advanced heading. Both more biomass and advanced heading stage were observed when the mean temperature for 10 DFT was 13.8℃ or higher, compared to those of right after transplanting treatments. These findings indicate that effective 10-DFT mean temperature for rice growth exists between 10.5 and 11.6℃, and that for rice development in terms of heading stage lies between 11.6 and 13.8℃ in natural condition. Further field and indoor studies are suggested to narrow down the critical temperature for early transplanting of temperate rice, which will enable to maximize the crop period in high altitude regions with low temperature.

• 한국약용작물학회지
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• 제20권5호
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• pp.365-371
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• 2012

This study was carried out to know the characteristics of flowering and bearing fruit, the optimum period, regions and methods for seed harvesting, the optimum temperatures for seed storage and germination, and the optimum period for sowing at nursery bed and seedling transplanting of Valeriana fauriei Briquet. The flowering and bearing fruit of Valeriana fauriei was developed from the before-year root. Optimum period for seed harvest of Valeriana fauriei was from late July to middle August, and optimum areas were the high elevated areas over 500 m above the sea level as Jinbu-myeon, Pyeongchang-gun, Gangwon-do. Using of net-bag for seed harvesting was the effective method to gather the full ripe seed, and bagging of net-bag was necessary from the season of middle May that was the flowering middle-stage. Germination rates don't show the difference among the different temperatures of storage as approximately 41% at $-20^{\circ}C$, $2^{\circ}C$ or $20^{\circ}C$ of seed storage temperatures. The optimum temperature range was in $15{\sim}30^{\circ}C$ for seed germination at nursery bed. The optimum period for seed sowing at nursery bed was the late February, and the optimum period for seedling transplanting was the middle April.

• 생명과학회지
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• 제8권3호
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• pp.294-297
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• 1998

본 연구는 이식시기와 물관리 방법이 율무의 수량에 미치는 영향을 아아보기 위함이었는데, 그 결과는 아래와 같이 요약된다. 1. 율무의 이식후 초기생육은 배수처리구에서 양호하였고 침수처리구는 이식 1개월 이후부터 생육이 점차 회복되었다. 2. 이식시기가 늦어질수록 이식-출수하까지의 기간이 크게 단축되었으며 율무의 제특성 발현 및 첫서리 이전에 수확을 하기 위해서는 6월 20일이 율무 이식한계기였다. 3. 율무는 침수 재배조건하에서 간장은 단축되었으나 결실립수 및 1,000립중은 증가하였으며, 엽고도 감소되어 배수처리구에 비해 종실수량이 8% 증수되었다.

• 농업과학연구
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• 제46권3호
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• pp.629-636
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• 2019

This study was conducted to investigate the growth characteristics and yield of whole green rice grains during the ripening period. These were investigated using Hopumbyeo and Unkwangbyeo at two transplanting times and with two kinds of nitrogen fertilization. The transplanting times were May 30 and June 20, respectively, using 30-day seedling culture and transplanting conducted with 3 - 4 plants per hill in planting space of $15cm{\times}30cm$. During nitrogen fertilization, 9 kg and 18 kg was used, respectively. The harvest of the green whole rice grains was carried out on the 15th, 20th, 25th, 30th, and 40th day after the heading date. The clum length was greater with later planting and with application of more nitrogen. The rice yield was higher with nitrogen fertilization of 18 kg/10 a when transplanted on May 30 for Hupumbyeo, and for Unkwangbyeo, was higher at 9 kg/10 a nitrogen fertilization when transplanted on May 30. The protein content of Hopumbyeo was higher when the nitrogen fertilizer was 18 kg/10 a, and that of Unkwangbyeo was lower than that when transplanting on June 20. The greenness was not related to the nitrogen fertilization level when transplanted on May 20 but for later transplanting, the greenness was higher when the nitrogen application was increased, and the greenness was the greatest about 30 days after the heading date.