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연규복,이춘우,장영희,이석순,박연규 韓國作物學會 1991 한국작물학회지 Vol.36 No.6
총체용 보리, 밀, 신기호밀의 조사료 생산성 및 사료적 가치를 구명하고자 올보리, 그루밀, 신기호밀을 공시하여 총체수량, 기관별 구성비, 사료적 가치 및 예취적기를 조사한 바를 요약하면 다음과 같다. 1. 총체수량은 호밀>밀>보리의 순으로 많았으며 총체수량이 가장 많은 시기는 보리, 밀은 출수후 14일, 신기호밀은 21일이었다. 2. 기관별 구성비는 세 품종 공히 출수후 일수가 경과할수록 이삭의 비율이 늘고 줄기와 잎은 감소하였다. 보리의 이삭 비율은 황숙기에 56 1%로 밀과 신기호밀에 비하여 월등히 높았다. 3. 사일레지 제조 적정 수분에 도달하는 시기는 보리가 출수후 24-31일, 밀은 출수후 24-35일, 신기호밀은 출수후 25-34일 이었다. 4. 보리의 황숙기 때 조단백, 조지방의 각 10.7%, 4.7%로 밀, 신기호밀에 비하여 높았으며 반면에 보리의 조섬유는 낮았다. 5. 총체수량, 수분함량, 사료가치 및 수도이앙 등을 고려할 때 총체용 맥류의 수확적기는 출수후 23-24일 이었다. 6. 중북부지역에서 답이작 총체용으로는 보리가 가장 적합한 맥종으로 사료되었다. To obtain information on the forage yield and quality of barley, wheat and triticale, fresh and dry yields and chemical components of respective local varieties for each species were measured at heading stage, 7th day after heading (DAH), 14th DAH, 21st DAH and yellow ripe stage. Fresh yield of triticale was higher than those of barley and wheat at all stages. The time of optimum forage moisture for silage was 24-31 DAH in barley, 24-35DAH in wheat and 25-34 in triticale, The percentage content of protein and fat of barley were higher than those of wheat and triticale. Optimum cutting time for silage as proposed with the observa. tions that for barley and wheat it was at 23DAH, and for triticale at 24DAH. In relation to the optimum transplanting time of rice, barley was considered the most suitable species for whole crop silage in the central region of Korea.
남윤일,연규복,구본철 한국작물학회 1989 Korean journal of crop science Vol.34 No.2
There are several meterorolgical stresses in the winter cereal crops. Among these stresses, cold injury is one of the most important stresses for wheat and barley production in Korea. The reduction in grain yield of the wheat and barley due to cold injury has occurred almost every year in Korea. The objective of the study was to get the basic information in relation to the cold injury and to detect the method minimizing the damage of cold injury. When the air temperature was the ranges of -13$^{\circ}C$ to -15$^{\circ}C$, the soil temperature at the crown part of the plant was very stable, whereas in the ranges of -2$^{\circ}C$ to -3$^{\circ}C$ the soil surface temperature was more unstable and cold than air and subterranean temperatures. The different parts of the plant in wheat and barley possess the different levels of cold hardiness. In comparison to the cold hardiness of plant parts, the leaf and crown are the less sensitive to cold injury than root and vascular transitional zone. The type and extent of stress is determined by the redistribution pattern of water during freezing. These types from freezing processes were three types: a) Equilibrium freezing pattern b) Non -equilibrium freezing pattern, c) Non-equilibrium freezing pattern typical of tender tissues. Cold hardiness in wheat plants were more harder than barley plants at vegitative stage, but inverted at the reproductive stage. Injuries by low temperature during the seasons of barley cultivation in Korea were occured mainly in four stage; in the first and third stage, frost injury occurs, the second stage, freezing injury, and the fourth stage, chilling injury.