본 논문은 한국형 무경운 재배 토양에서 유기물 투입과 분할 관수가 고추 생육 및 수량 과 토양 화학성, 생물다양성에 미치는 영향을 구명하고자 추진하였다. 시험 후 토양에 화학 성을 조사한 결과 토양 pH는 5.6~6.2, 유기물 함량은 32~42 g ㎏-1, EC는 1.0~2.7 dS m-1, 치 환성 K은 0.08~0.24 cmol+ kg-1, Ca은 9.5~12.8 cmol+ kg-1, Mg은 2.7~3.2 cmol+ kg-1 수준이었 으며, 유효인산은 1,011~1,137 mg kg-1 수준이었다. 무처리에서 토양에 미소동물은 톡토기와 응애류 등 5종 54개체가 포획되었으나, 대두박을 투입한 처리는 9종 271개체가 포획되어 되었다. 토양환경의 지표가 되는 자연도 점수가 대두박 투입 처리는 11점으로 무 투입 5점 에 비하여 2배 정도 증가되었다. 대두박 투입은 무 투입에 비하여 고추의 수확과수의 감소 로 수량이 감소되는 경향이었다. 그러나 대두박 무 투입 조건에서 표준시비량의 33~66% 수준에서고추 수량은 증수되었으며 대두박 투입에서는 표준시비량의 33% 수준에서 증수 되었다. 2회 분할관수는 1회 전량관수에 비하여 고추의 수확 과수가 12.5~34.9% 증가되었 고, 수량은 13.5~34.4% 정도 증수되었다.

두둑과 고랑을 재활용한 한국형 무경운 농업에서 유기물 투입과 관수 효과를 구명하고 자 무경운 토양에서 시험을 수행하였다. 1. 토양 미생물상 1회 전량관수 조건에서 대두박 투입 처리구의 토양 세균과 곰팡이 수는 대두박 무 투입 구에 비하여 많았다. 그리고 유기질비료 투입량이 표준시비량 66%까지 증가되면 세균과 곰팡이 수는 증가되었으나, 그 이상에서는 세균과 곰팡이 수가 감소되는 경향이었다. 곰팡 이/세균 비율은 관수 방법과 관계없이 대두박 투입 처리에서 0.6과 1.1로, 무투입 처리의 0.2와 0.5보다 2배 이상 높았다 1회 전량 관수 조건에서 유기질 비료 시비량이 증가되면 대두박을 투입한 처리는 방선균 수는 감소되는 경향이었으나, 대두박 무투입에서는 증가되었다. 2회 분할 관수는 1회 전량 관수에 비하여 대두박 무 투입 조건에서 세균과 곰팡이 수가 증가되었으나, 대두박 투입 조건에서는 방선균 수가 증가되었다. 2. 토양 효소 유기질 비료의 시비량이 증가되면 토양 내 Chitinase 활성은 대두박 투입 토양에서 감소 되고, 대두박 무 투입에서는 증가되는 경향이었다. 그러나 대두박을 투입에 관계없이 2회 분할 관수는 1회 전량관수에 비하여 Chitinase 활성이 증가되었다. 1회 전량관수 조건에서 대두박 투입 처리구의 β-Glucosidase 활성은 무투입에 비하여 높 았으며, 유기질 비료 투입량이 증가되면 표준시비량의 66%까지는 β-Glucosidase 활성이 증 가되었으나, 표준시비량에서는 감소되었다. 대두박 무투입 조건에서 2회 분할관수 토양 내 β-Glucosidase 활성은 1회 전량관수에 비하여 현저하게 증가되었다. 1회 전량관수 조건에서 대두박을 투입한 처리의 N-acetyl-β-D-glucosaminidase의 활성은 무투입구에 비하여 높았다. 대두박 투입 처리에서 유기질 비료 투입량이 표준시비량의 66 %까지 증가되면 N-acetyl-β-D-glucosaminidase의 활성은 증가되었으나, 표준시비량에서는 유의적인 차이가 없었다. 대두박 무투입 조건에서 2회 분할관수는 1회 전량관수에 비하여 N-acetyl-β-D-glucosaminidase의 활성은 증가되었다. 대두박 무투입 조건에서 유기질 비료 시비량이 표준량의 66% 수준에서는 토양 내 산성인 산가수분해효소(Acid phosphatase)의 활성 높았다. 대두박 투입 조건에서는 유기질 비료 시비 량이 증가되면 산성인산가수분해효소(Acid phosphatase)의 활성은 증가되는 경향이었다. 3. 토양 AMF 대두박 무투입 조건에서 유기질 비료의 투입량이 표준시비량의 66%까지 증가되면 토양 의 내생균근균의(AMF) 포자수는 증가되었으나, 유기질 비료 투입량이 표준시비량에서는 근균의 포자수는 감소되었다. 그러나 대두박 투입에서 근균의 포자수는 유기질 비료 투입 량에 따른 유의적인 차이가 없었다. 그리고 내생 근균의 고추 뿌리에 정착률은 대두박 투 입량에 따른 유의적인 차이가 없었으며, 2회 분할 관수도 같은 경향이었다.

Background : Acreage of rain-shelter plastic greenhouse to prevent anthrax is being gradually increased according to growing importance of safe Boxthorn production. But When Boxthorn is grown in the hot season in rain-shelter plastic greenhouse, Fertility decreases. The fertilization rate tends to be different according to cultivated variety and ventilation type of rain-shelter plastic greenhouse. Therefore it is necessary to identify cause and look for a solution. Methods and Results : In the experiment, ‘Cheongun’ cultivar was grown in the rain-shelter plastic greenhouses for the tests. Environment of rain-shelter plastic greenhouses, fertilization rate and density of flower visiting insect were investigated according to ventilation type. Pollen germination and pollen tube elongation on stigma were investigated according to temperature. In mid-July, the temperature on a clear day rose to 45℃ in rain-shelter plastic greenhouse of side vents. Pollen germination and pollen tube elongation on stigma were normal for 3 hours on 30, 35℃. Fertilization rate was somewhat reduced on 40℃ but Pollen germination and pollen tube elongation was good. On 45℃, fertilization rate was very poor and There was no pollen germination. Density of flower visiting insect in rain-shelter plastic greenhouse of roof and side vents was higher than that in rain-shelter plastic greenhouse of side vents. The fertilization rate on high temperature did not show any difference regardless of ventilation type. The rate of artificial cross-fertilization and airborne fertilization were high in rain-shelter plastic greenhouse of roof and side vents. It was necessary to improve airborne fertilization rate because airborne fertilization rate was significantly lower than artificial cross-fertilization regardless of ventilation type. Conclusion : When it was cultivated in rain-shelter plastic greenhouse, the reasons for the lowering of the fertilization rate were as follows. Density of flower visiting insect was low. Boxthorn, which was insect pollination crop, was needed sufficient flower visiting insect on flowering period. But it was insufficiency especially in rain-shelter plastic greenhouse of side vents. Another reason was decrease in pollen germination and pollen tube elongation. Pollen germination was suppressed in the high temperature.

두둑을 재활용한 무경운 재배 토양의 고추의 생육량은 관행경운 토양에 비하여 22% 정 도 증가되었고, 무경운 3년차는 12% 정도 증가되었다. 무경운 재배 2년차 토양에서 생산된 풋고추 건물중은 348.4 kg 10-1으로 관행 경운 토양에 비하여 16% 증가되었으나, 무경운 3 년차는 감소되었다. 무경운 2년차 토양의 세균은 관행 경운 토양에 비하여 유의적인 증가를 보였으나, 무경 운 3년차에서는 관행 경운 토양과 유의적인 차이가 없었다. 방선균도 경운 토양에 비하여 무경운 2년차 토양은 유의적인 증가를 보였으나 무경운 3년차는 감소되었다. 곰팡이는 경 운토양에 비하여 무경운 2~3년차 토양에서 1.3~1.7배 정도 증가되었다. 무경운 재배 토양의 CO2 발생량은 경운재배 토양에 비하여 41% 수준으로 발생량이 현저 하게 감소되었다. 고추 생육 초기 관행 경운 토양의 미소동물은 톡토기목과 응애목 2종 6개체가 포획되었 으나, 무경운 1년차 토양에서는 지네강 등 5종 11개체가 포획되었고, 무경운 2년차는 딱정 벌레와 지네강 등 3종 5개체가 포획되었다. 고추 정식 46일 후에 조사한 경운재배 토양은 보라톡토기 등 4종 40개체를 포함 큰집게벌레 등 8종 97개체가 포획되었다. 무경운 재배 토양은 9~10종 101~107개체가 포획되었다. 지표생물로서 환경의 변화의 기준이 되는 자연도 점수는 관행경운양 19점에 비하여 무 경운 토양의 자연도 점수는 33점으로 1.74배 정도 높았다. 따라서 두둑과 고랑을 재활용한 한국형 무경운 농업은 관행 경운토양에 비하여 작물의 생육과 토양 미생물, 토양 곤충을 포함한 토양생물 다양성, 온실가스 발생량 감소에 긍정적 인 역할을 하는 것으로 판단되었다.

This study was carried out to investigate the effect of no-tillage on sequential cropping supported from recycling of first crop ridge on the productivity of crop and physical properties of soil under green house condition. This study is a part of “No-tillage agriculture of Korea-type on recycled ridge”. From results for distribution of soil particle size with time process after tillage, soil particles were composed with granular structure in both tillage and no-tillage. No-tillage soil in distribution of above 2 mm soil particle increased at top soil and subsoil compared with tillage soil. Tillage and one year of no-tillage soil were not a significant difference at above 0.25 mm~below 0.5 mm, above 0.5 mm~below 1.0 mm, and above 1.0 mm of water-stable aggregate. Two years of no-tillage soil was significantly increased by 8.2%, 4.5%, and 1.7% at above 0.25 mm~below 0.5 mm, above 0.5 mm~below 1.0 mm, and above 1.0 mm of water-stable aggregate, respectively, compared with one year of no-tillage. Bulk density of top soil was 1.10 MG m3 at tillage and 1.30 MG m3 at one year of no-tillage. Bulk density of top soil was 1.14 MG m3 at two years and 1.03 MG m3 at three years of no-tillage, respectively. Bulk density of subsoil was a similar tendency. Solid phase ratio in top soil and subsoil was increased at one year of no-tillage compared with tillage soil, while soil phase ratio decreased at two and three years of no-tillage. Pore space ratio in tillage top soil (58.5%) was decreased by 8.5% at compared with no-tillage soil (51.0%). Pore space ratio was 56.9% and 61.2% at two and three years of no-tillage soil, respectively. Subsoil was a similar tendency. Gaseous phase ratio was decreased at one year of no-tillage soil, and increased at two and three years of no-tillage soil compared with tillage soil. Liquid phase ratio in top soil was increased at one year of no-tillage (28.3%), and decreased at two years (23.4%) and at three years (18.3 %) of no-tillage soil compared with tillage soil (24.2%). Subsoil was a similar tendency. Liquid phase ratio in subsoil was increased than top soil.

This study was carried out to investigate the effect of no-tillage on sequential cropping supported from recycling of first crop ridge on the growth of pepper plant and physical properties of soil under green house condition.1. Degree of crack on soil by tillage and no-tillageSoil cracks found in ridge and not found in row. At five months of tillage, crack number and crack length in length ridge were 3 and 37~51 cm in tillage. Maximum width and maximum depth in length ridge were 30 mm and 15.3cm in tillage. Crack number and crack length in width ridge were 7.5 and 7~28 cm in tillage. Maximum width and maximum depth in width ridge were 29 mm and 15.3 cm in tillage. At a year of no-tillage, crack number and crack length in length ridge were 1.0 and 140~200 cm in tillage. Maximum width and maximum depth in length ridge were 18 mm and 30 cm in a year of no-tillage. Crack number and crack length in width ridge were 11 and 6~22 cm in a year of no-tillage. Maximum width and maximum depth in width ridge were 22 mm and 18.5 cm in a year of no-tillage. Soil crack was not found at 2 years of no-tillage in sandy Jungdong series (jd) soil. Soil crack was found at 7 years of no-tillage in clayish Jisan series (ji) soil.2. Penetration resistance on soilPenetration resistance was increased significantly at no-tillage in Jungdong series (jd). Depth of cultivation layer was extended at no-tillage soil compared with tillage soil. Penetration resistance of plow pan was decreased at 1 year of no-tillage compared with than tillage soil. Penetration resistance was linearly increased with increasing soil depth at tillage in Jisan series (ji). Penetration resistance on top soil was remarkably increased and then maintained continuously at no-tillage soil.3. Drainage and moisture content of soilMoisture content of ridge in top soil was not significant difference at both tillage and no-tillage. Moisture content of ridge in 20 cm soil was 14% at no-tillage soil and 25% at tillage soil.4. Change of capacity to retain water in soilCapacity to retain water in top soil was not significant difference at 1 bar both tillage and no-tillage. Capacity to retain water in soil was slightly higher tendency in 1 year and 2 years of no-tillage soil than tillage soil. Capacity to retain water in soil was increased at 15 bar both tillage and no-tillage. Capacity to retain water in subsoil was slightly higher tendency at 1 bar and 3 bar in 2 years of no-tillage than tillage soil and a year of no-tillage soil.

Background : Acreage of rain-shelter plastic greenhouse to prevent anthrax is being gradually increased according to growing importance of safe Boxthorn production. But When Boxthorn is grown in the hot season in rain-shelter plastic greenhouse, quantity of Boxthorn decreases. therefore the research was carried out to investigate Fertilization mode. Methods and Results : Chungwoon was very strong self-incompatibility. Chengyangjaerae, Chengyang18 and CBP11542-206 was self-compatibility. Artificial fertilization rate was slightly higher in roof and side vents than in side vents of rain-shelter plastic greenhouse in hot season. Pollen sterility due to high temperature is not critical because artificial fertilization rate was high in side vents of rain-shelter plastic greenhouse in hot season. Airborne fertilization rate was significantly lower in all varieties. Open fertilization rate was higher in roof and side vents than in side vents of rain-shelter plastic greenhouse Conclusion : Roof and side vents was good in compared to side vents in rain-shelter plastic greenhouse of Boxthorn because of high Airborne and open fertilization rate. Self-compatibility varieties were better than self-incompatibility varieties in rain- shelter plastic greenhouse because of high open fertilization rate.

This study was conducted to determine the effects of organic vegetable cultivation on the soil physical properties in 33 farmlands under plastic greenhouse in Korea. We were investigated 5~8 farms per organic vegetable crops during the period from August to November 2014. The main cultivated vegetables were leafy lettuce (Lactuca sativa L.), Perilla leaves (Perilla frutescens var. Japonica Hara), cucumber (Cucumis sativus L.), strawberry (Fragaria ananassa L.) and tomato (Lycopersicon spp.). We have analyzed soil physical properties. The measured soil physical parameters were soil plough layer, soil hardness, penetration resistance, three soil phase, bulk density and Porosity. The measurement of the soil plough layer, soil hardness and penetration resistance were carried out direct in the fields, and the samples for other parameters were taken using the soil core method with approximately 20 mm diameter core collected from each organic vegetable field. Soil plough layer was average 36 cm and ranged between 30 and 50 cm, and slightly different depending on the sorts of vegetable cultivation. The soil hardness was 0.17±0.15~1.34±1.02 in the topsoil, 0.55±0.34~1.15±0.62 in the subsoil. It was not different between topsoil and subsoil, but showed a statistically significant difference between the leafy and fruit vegetables. Penetrometer resistance is one of the important soil physical properties that can determine both root elongation and yield. The increase in density under leafy vegetables resulted in a higher soil penetrometer resistance. Soil is a three-component system comprised of solid, liquid, and gas phases distributed in a complex geometry that creates large solidliquid, liquid-gas, and gas-solid interfacial areas. The three soil phases were dynamicand typically changed in organic vegetable soils under greenhouse. Porosity was characterized as range of 54.2±2.2~60.3±2.4%. Most measured soils have bulk densities between 1.0 and 1.6 g cm-3. To summarize the above results, Soil plough layer has been deepened in organic vegetable cultivation soils. Solid hardness (the hardness of the soil) and bulk density (suitable for the soil unit mass) have been lowered. Porosity (soil spatial content) was high such as a well known in organic farmlands. Important changes were observed in the physical properties according to the different vegetable cultivation. We have demonstrated that the physical properties of organic cultivated soils under plastic greenhouse were improved in the results of this study.

This study was carried out to investigate the effect of no-tillage and split irrigation on the growth of pepper plant under green house condition in Jeonnam province. Moisture content of soil at whole quantity irrigation in tillage was increased rapidly regardless of soil depth for initial irrigation and then was decreased continuously until next irrigation. Deviation of moisture content in soil was decreased with increasing depth of soil. Moisture contents of top soil and subsoil (20 cm) at whole quantity irrigation in no-tillage were increased with sunrise, and then decreased with sunset. Moisture contents of top soil in tillage, and top soil and subsoil (20 cm) in no-tillage at half quantity irrigation indicated a cyclic diurnal variation by evapotranspiration. Salinity of soil was increased after initial irrigation and then was decreased continuously until next irrigation. With increasing depth of soil, increases of salinity in soil was delayed. Salinity of top soil in no-tillage was increased between AM 11:00 and AM 12:00, and then showed the highest level between PM 2:00 and PM 6:00 on a cyclic diurnal variation by evapotranspiration. Salinity of subsoil (30 cm) in no-tillage was not measured a cyclic diurnal variation. Moisture content and salinity of soil was positive correlation regardless of tillage and no-tillage cultivation. Growth of pepper in no-tillage cultivation was higher than that in tillage cultivation. Main branch Length and stem diameter of half quantity irrigation plot was higher than that of whole quantity irrigation plot regardless of tillage and no-tillage cultivation. After harvesting, the number of pepper fruits of half quantity irrigation plot was increased remarkably by 49% and47%, in tillage and no-tillage cultivation, respectively. Pepper yield of no-tillage cultivation plot was higher by 8% than that of tillage cultivation plot. Pepper yield of half quantity irrigation plot was increased remarkably by 36% and 39%, in tillage and no-tillage cultivation, respectively.

본 연구는 하우스에서 반유한 직립형 동부 계통의 파종기 이동이 생태반응과 생육 및 수량성에 미치는 영향을 구명하 고자 전남 나주(위도 35° 04'N, 경도 126° 54'E)에서 2012 년과 2013년에 수행하였다. 시험계통으로 전남1호와 전남2 호를 이용하여 3월 중순부터 8월 중순까지 1개월 간격으로 6회 파종하였다. 1. 출현일수는 3월 중순 파종에서 12일로 길었고, 기타 파종기에서는 4~3일 이었다. 2. 개화일수는 3월 중순부터 7월 중순까지는 파종기가 지연됨에 따라 짧아지다 8월 중순 파종에서 길어졌다. 즉, 3월 중순 파종에서 75일 내외로 가장 길었고, 7월 중순 파종에서 30일로 가장 짧았다. 3. 개화시에서 수확기까지의 소요일수는 3월 중순부터 5 월 중순 파종에서 28~24일로 짧았으나, 이후 파종에서 는 38~35일로 긴 편이었다. 4. 경장과 화경장은 4월 중순과 8월 중순 파종에서 긴 편 이었고, 주경절수는 6월 중순 파종, 분지수는 3월 중순 파종에서 많았다. 5. 3월 중순 파종에서는 주당 꼬투리수가 많고 립중이 무 거워, 전남1호와 전남2호의 10a당 수량이 각각 340, 367kg로 가장 많았으며, 이후 파종이 지연됨에 따라 대체로 수량이 감소하는 경향이었다.

This study was performed to investigate the effects of sowing density and number of seeds sown on the emergence rate and growth characters of Panax ginseng C. A. Meyer under direct sowing cultivation in a blue plastic greenhouse. Ginseng seedlings, derived from seeds sown directly at different densities (90, 108, 135, and 162 seeds per 162m2), were cultivated in sandy loam soil within a blue plastic greenhouse. In contrast to the emergence rate, which decreased with an increase of sowing density, number of survival plant showed an increasing trend. Interestingly, the emergence and number of survival plant were significantly enhanced when 2 or 3 seeds were sown per hole compared with when one seed was sown per hole. Growth of the aerial parts of ginseng were not markedly influenced by sowing density or the number of seeds sown. However, chlorophyll content (SPAD values) increased with an increase in sowing density. Root parameters, such as root length, diameter, and weight, and the number of lateral roots decreased with an increase in sowing density, but were not noticeably influenced by the number of seeds sown. Total saponin content was the highest in the treatment plot containing 135 seeds. Similarly, the content of each ginsenoside was also tended to be higher in this treatment than in other treatment plots. On the basis of the results obtained in this study, it was possible to determine the optimal sowing density and seed number for the direct sowing cultivation of ginseng in blue plastic greenhouse.