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연구보문 : 식물환경 ; 적색 비닐멀칭과 흑색 비닐멀칭의 반사광 특성과 참외와 토마토의 품질과 수량에 미치는 영향
홍성창 ( Seung Chang Hong ),허정욱 ( Jeong Wook Heo ),이정택 ( Jeong Taek Lee ),강기경 ( Kee Kyung Kang ) 한국환경농학회 2011 한국환경농학회지 Vol.30 No.4
BACKGROUND: Plastic mulches widely used in raised-bed culture mainly to conserve water, control weeds and raise soil temperature. The most widely used plastic mulch colour is black. Reflective red and far-red light can affect on growth and yield of various vegetable crops. Objectives of this study were to investigate the characteristics of reflective light of black and red plastic mulches, and to evaluate the reflective red and far-red light on the quality characteristics and yield of the Oriental melon (Cucumis. Melo L.) and tomato (Lycopersicon esculentum L.). METHODS AND RESULTS: Oriental melon and tomato were cultivated over the reflective red and black plastic mulches in plastic house. Reflected red and far-red light over the red plastic mulch were 2.6 times higher than those of black plastic mulch. Red to F-Red ratio of black plastic mulch, red plastic mulch and sunlight were 1.14, 0.93 and 1.16 respectively. Intensity of reflected red and far-red light over red plastic mulch were highest at surface height of 30 cm. The higher the height of the surface decrease the intensity of far-red light. Accordingly, Red to F-Red ratio were increased. Reflective red plastic mulch increased the weight of fruit and content of sugar in Oriental melon and tomato. CONCLUSION(s): Yield of Oriental melon over reflective red plastic mulch was higher than that of black plastic mulch. These results suggested that reflected red and far-red light over the red plastic mulch affected allocation of photosynthate in growing Oriental melon.
홍성창 ( Hong Sung-chang ),장은숙 ( Jang Eun-suk ),허승오 ( Hur Seung-oh ),최순군 ( Chio Soon-kun ),유선영 ( Yu Sun-young ),이규현 ( Lee Gyu-hyen ),김경식 ( Kim Kyeong-sik ) 한국환경농학회 2019 한국환경농학회 학술대회집 Vol.2019 No.-
Temperature increases due to climate change are affecting various sectors of agriculture. Elevated temperatures can affect the growth and yield of crops and can also affect the utilization efficiency of nutrient input materials such as soil nutrients, chemical fertilizers, and compost. The outflow of non-point pollutant sources from farmlands is strongly influenced by physical factors such as rainfall, rainfall intensity, and slope of agricultural land. In order to simulate the outflow of non-point pollutant sources due to climate change, it is necessary to find out not only the physical factors but also the changes in the biological factors induced by the elevated temperature in detail. Temperature is one of the most important environmental factors controlling the growth and yield of plants, and the rate of reaction depends on temperature in all biological processes. Elevated temperatures increase nitrogen mineralization and net nitrification rate. The degradation, absorption, utilization, and outflow of the variety of nutrient input materials for crop cultivation can differ due to temperature rise. This study was carried out to investigate the changes of nitrogen in the nutrients of the cultivated waters by cultivating rice and maize in pots after simulating climate change and by establishing an elevated temperature environment with the chemical fertilizer and livestock compost. The elevated temperature environment was established using the modified medium open-top chamber whose width is 6m and height is 3m. The medium open-top chamber has a merit of increasing only temperature while maintaining the environmental factors such as rainfall, wind, and sunlight intensity similar as those in the field. The maximum temperature in the open-top chamber measured on the 15th of May, 2018 was higher by 2.7℃ than the field, while the average temperature was higher by 0.4℃ so that the elevated temperature could be applied to the rice and maize throughout the growth period. The rice and maize were planted in Wagner pots filled with sandy loam and clay loam, and then placed in a medium open-top chamber and grown at elevated temperatures. The analysis results of nitrogen by periodically collecting the cultivation water from the Wagner pots during the cultivation period of the rice and maize showed that the NO<sub>3</sub>―N concentration in the paddy cultivation water was decreased in the no-fertilization block, chemical fertilizer treated block, and cow dung compost treated block in the paddy cultivation sandy loam under elevated temperature compared to those in the field. Meanwhile, the NH<sub>4</sub>― N concentration was increased in the rice cultivation clay loam soil in all the treated blocks compared to the field. The NO<sub>3</sub>―N concentration in the cultivated water was decreased in all the treatment blocks in the maize cultivation clay loam soil by the elevated temperature than that of field. However, NH<sub>4</sub>―N concentration in the water from the maize cultivation sandy loam soil, as well as the clay loam soil with the chemical fertilizer, was increased by elevated temperature compared to the field. The results indicate that the nitrogen changes in the water of the paddy field and upland are induced under the elevated temperature. The outflow of the non-point pollutant sources towards the water system near the cultivation fields also can be changed by rainfall.
홍성창 ( Seung Chang Hong ),권순익 ( Soon Ik Kwon ),김민경 ( Min Kyeong Kim ),채미진 ( Mi Jin Chae ),정구복 ( Goo Bok Jung ),강기경 ( Kee Kyung Kang ) 한국환경농학회 2012 한국환경농학회지 Vol.31 No.3
적색 LED를 이용한 들깨의 개화억제를 위한 일장연장처리 기술을 개발하기 위하여 적색광에 대한 들깨의 개화와 생육반응을 검토하였다. 들깨는 적색광에 의한 일장연장 처리로 개화가 억제되었으나 초적색광 조사로 개화하여 광가역성을 나타냈다. 인공생육실 환경하에서 적색광 0.177 μmol/m2/s (PAR: 0.62 μmol/m2/s)로 일장연장 처리시 들깨의 개화가 억제되었다. 비닐하우스 시험포장에서 적색광 0.2 μmol/m2/s처리(PAR: 0.7μmol/m2/s)는 관행의 백열등 30Lux 처리와 같이 개화하지 않고 영양생장을 지속하였다. 적색 LED장치를 이용한 일장연장 처리는 관행의 백열등 처리보다 들깨의 초장은 3%, 엽수는 7%, 엽생체중은 21%, 엽면적은 19% 증가시키는 경향이었다. BACKGROUND: This experiment was conducted to investigate the effects of red light on inhibition of flowering and vegetative growth of perilla (Perilla Frutescens. L). METHODS AND RESULTS: To determine red light intensity for inhibiting floral induction of perilla 6h light plus daylength extension (17:00-23:00) with three different intensity of red lights 0.046, 0.114 and 0.177μmol/m2/s were treated respectively, and control plants were grown under 11(06:00-17:00)/13(17:00-06:00)h light/dark environment. Red (660nm) and far-red(730nm) light were irradiated for night break treatment subsequently to investigate photoreversible flowering response of perilla ``Manchu``. The flowering was inhibited by night break with red light, but sequential far-red light induced floral induction of perilla. Perilla not flowered by red light intensity over 0.177 μmol/m2/s. Red light of 0.2μmol/m2/s was irradiated for 6 hours (20:00-02:00) with LEDs device in plastic house, Perilla not flowered and continued the vegetative growth by red light treatment and the plant length, number of leaves, fresh weight, and leaf area of perilla were increased by 3%, 7%, 21%, and 19%, respectively, compared to incandescent control. CONCLUSION: These results showed that red (660nm) light for daylength extension could be used to control flowering and to enhance production of perilla leaf.
온도상승 환경 처리가 논토양과 용수에서 탄소량 변화와 벼 생육에 미치는 영향
홍성창 ( Sung-chang Hong ),허승오 ( Seung-oh Hur ),최순군 ( Soon-kun Choi ),최동호 ( Dong-ho Choi ),장은숙 ( Eun-suk Jang ),( Climate Change ) 한국환경농학회 2018 한국환경농학회지 Vol.37 No.1
상승온도 처리에 따른 논토양 탄소의 변동과 벼 생육을 조사한 결과를 요약하면 다음과 같다. 소형 상부개방형 챔버를 이용하여 대기온도 보다 0.4℃, 0.5℃, 0.9℃ 상승온도 환경을 조성하여 상승온도를 처리할 수 있었다. 사각챔버의 내부온도는 대기보다 평균온도와 최고온도가 높고 최저온도는 낮은 특징을 나타내었다. 상승온도 처리구의 포트 내 표면수의 TOC 농도는 대조구 보다 상승온도 처리구에서 높았고 시간이 경과함에 따라 점차 낮아졌다. 벼 재배후 토양의 TOC함량은 대조구 보다 상승온도 처리구에서 낮았다. 상승온도 처리로 벼 식물체의 탄소함량은 감소하고 질소함량은 증가하여 C/N 율은 감소하는 경향을 나타내었다. 상승온도 처리로 대조구 보다 벼의 줄기 길이와 줄기무게가 유의하게 증가하였으나 이삭수와 벼 낱알 무게는 유의한 차이를 나타내지 않았다. BACKGROUND: The global mean surface temperature change for the period of 2016∼2035 relative to 1986~2005 is similar for the four representative concentration pathway (RCP)’s and will likely be in the range of 0.3℃ to 0.7℃. Climate change inducing higher temperature could affect not only crop growth and yield, but also dynamics of carbon in paddy field. METHODS AND RESULTS: This study was conducted to evaluate the effect of elevated temperature on the carbon dynamics in paddy soil and rice growth. In order to control the elevated temperatures, the experiments were set up as the small scale rectangular open top chambers (OTCs) of 1 m (width)×1 m (depth)×1 m (height) (Type 1), 1 m (W)×1 m (D)×1.2 m (H) (Type 2), and 1 m (W)×1 m (D)×1.4 m (H) (Type 3). The average temperatures of Type 1, Type 2, and Type 3 from July 15 to October 30 were higher than the ambient temperatures at 0.4℃, 0.5℃, and 0.9℃, respectively. For the experiment, Wagner’s pots (1/2,000 area) were placed inside chambers. The pots were filled with loamy soil, and chemical fertilizer and organic compost were applied as recommended after soil test. The pots were flooded with agricultural water and rice (Shindongjin-byeo) was planted. It was observed that TOC (total organic carbon) of the water increased by the elevated temperatures and the trend continued until the late growth stage of the rice. Soil TOC contents were reduced by the elevated temperatures. C/N ratios of the rice plant decreased by the elevated temperature treatments. Thus, it was assumed that the elevated temperatures induced to decompose soil organic matter. Elevated temperatures significantly increased the culm length (P<0.01) and culm weight (P<0.05) of rice, but the number and weight of rice panicle did not showed significant differences. CONCLUSION: Based on the results, it was suggested that the elevated temperatures had an effect on changes of soil and water carbons under the possible future climate change environment.