본 시험은 온도 발육모델을 이용하여 꽃매미 알의 부화시기를 예측하고 약충과 성충 방제에 효과적인 친환경 자재선발 및 끈끈이트랩 색상별 유인효과를 찾기 위하여 수행하였다. 꽃매미 알은 15, 20, 25℃(14L:10D)에서 각각 55.9, 26.8, 21.6일 만에 부화하였고 부화율은 각각 61.9, 57.8, 30.4%로 온도가 높을수록 부화소요기간은 짧고 부화율은 낮았다. 알의 온도와 발육속도와의 관계식은 Y=0.0028X-0.0228 (R2=0.9561)이었으며, 발육영점온도는 8.14℃, 유효적산온도는 355.4일도였다. 위의 관계식에 의하여 전남지역 꽃매미 알의 부화시기는 5월 22일로 예측되었다. 꽃매미 약충방제에 효과적인 친환경자재는 제충국추출물, 고삼추출물, 데리스추출물이었고, 성충은 제충국추출물, 고삼추출물이었다. 황토색, 파랑색, 노랑색 끈끈이트랩 중에서 황토색끈끈이트랩의 유인량은 2주 동안에 약충 535마리, 성충 87.7마리였다. 황토색 끈끈이트랩은 꽃매미 약충과 성충의 유인포살효과가 우수하였다.
본 연구는 유기 벼 재배시 주로 이용되는 유기질비료가 토양화학성과 벼의 생장 및 수량에 미치는 영향을 구명하기 위해 수행되었다. 전남지역 벼 유기재배지에서 많이 이용되고 있는 유기질비료를 Organic fertilizer(이하 OF) I, 식물성 성분이 많이 함유된 비료(쌀겨 위주)를 OF II, 동물성 성분이 많이 함유된 비료를 OF III, 그리고 식물성과 동물성이 혼합된 비료를 OF IV로 나누어서, 벼 이앙 전에 전층시비로 토양에 골고루 처리하였다. 유기질비료내의 탄질율이 상대적으로 낮았던 OF I과 III이 OF II와 IV에 비교하여 시기별로 유기질비료의 질소 무기화가 빠르게 진행되었다. 토양의 시기별 유기물 함량은 유기질비료 투입량이 많았던 OF II와 IV에서 높게 나타났으며, 수확 후 토양의 화학성은 대체적으로 OF II와 IV에서 높게 나타났다. 벼 생장특성은 처리에 따른 차이는 나타나지 않았다.
The purpose of this study was to establish the optimal growth temperature and to select genetic resources for production of cowpea sprouts. Seowon was treated between 15°C and 30°C at intervals of 3°C to investigate growth temperature. Twelve resources, including Seowon, IT154149, IT154153, Tvu7426, and Tvu7778, were used for cultivating sprouts at a temperature of 27°C. The yield ratio of cowpea sprouts was highest at 27°C (657%), and was reduced when growth temperature was decreased. The hard seed rate was lower when the growth temperature was increased. Vitamin C content was highest at 24°C (2.85 mg/g), ranged between 2.15 and 2.29 mg/g at other growth temperatures, and increased with the length of the growth period. The inorganic component content of cowpea sprouts did not vary based on growth temperature, while the amino acid content increased with increasing growth temperature between 15°C and 24°C, and then subsequently decreased as growth temperature rose from 24°C to 30°C. IT154153 had the highest yield ratio of cowpea sprouts per genetic resource (647%), followed by Seowon (615%), and Tvu7426 (608%). Genetic resources with a higher yield ratio had smaller seeds, a thinner seed coat, and superior germinability. The inorganic components found at highest concentrations in the cowpea sprouts were potassium, magnesium, calcium, sodium, iron, molybdenum, and zinc (in that order). In comparison to raw seeds, the protein, calcium, zinc, molybdenum, and iron content in the cowpea sprouts was higher, while the content of aluminum and boron was lower.
The purpose of this study was to establish the proper sowing time and planting density of cowpeas for labor-saving cultivation. Experiments were carried out in Naju, Jeonnam Province (Latitude 35° 04' N, Longitude 126° 54' E) during 2012 and 2013. The intermediate-erect type strains used in this study were Jeonnam1 and Jeonnam2. Sowing was performed five times between June 25 and August 5 at approximately 10-day intervals in order to establish proper sowing time, and sowed at 5,000, 10,000, 15,000, and 20,000 plants per 10a to establish proper planting density. The days from sowing to first flowering was shortest (32 days) in plants sowed on July 25 and became longer for plants sowed on or around July 25. The days from sowing to first flowering was longest (41 days) in plants sowed on June 25. The days from first flowering to first maturing was shortest (8 days) in plants sowed on June 25 and, became considerably longer at later sowing dates. The days from first maturing to first harvesting ranged from 8 to 10 days, with little difference among the sowing periods. Plants sowed on August 5 harvested at the same time, and plants sowed between June 25 and July 25 were harvested either three or two times. The yield was highest in plants sowed on July 25: 209 kg/10a was harvested for Jeonnam1 and 221 kg/10a for Jeonnam2. Furthermore, harvested at the same time enabled when the harvesting was delayed for around 15 days because the share of the seeds first harvested was highest (91%). The proper planting density was estimated to be 15,000 plants/10a, showing the highest yields of 199 kg/10a for Jeonnam1 and 224 kg/10a for Jeonnam2.
본 연구는 국내‧외에서 수집한 동부 유전자원 245점에 대한 작물학적 특성을 조사하여 품종육성 기초자료로 활용하고자 수행하였으며 그 결과는 다음과 같다.1. 개화일수는 41∼50일(51.5%), 51∼60일(43.7%), 등숙일수는 21∼30일(53.9%), 31∼40일(23.7%), 생육일수는 71∼80일(26.9%), 81∼90일(23.4%) 순으로 많이분포하였다.2. 신육형은 무한형 72.7%, 중간형 25.7%, 및 유한형1.6%, 초형은 포복형 78.8%와 직립형 21.2%, 잎 모양은 심장형 98.4%와 피침(결각)형 1.6%, 꽃색은 보라색85.2%, 백색 13.6% 및 연주색 1.2% 씩 분포하였다.3. 성숙 꼬투리색은 갈색 54.7%와 황갈색 37.6%, 착협위치는 아래로 향함 90.6%, 중간 5.7% 및 곧추섬 3.7%씩 분포하였다.4. 종피색은 갈색 25.3%, 흑색 23.3%, 백색 20.8%, 종자모양은 계란형 66.9%, 장방형 24.9%, 신장형 8.2% 씩분포하였다.5. 협장은 10.1∼20.0 cm 89.0%, 20.1∼30.0 cm 8.6%,협당립수는 12.1∼15립 62.0%, 9.1∼12립 25.7%, 15.1∼18립 9.1% 씩 분포하였다.6. 백립중은 15.1∼20.0 g 37.6%, 10.1∼15.0 g 28.6%,주당수량은 100.1∼200.0 g 52.7%, 100.0 g 미만 22.9%,200.1∼300.0 g 15.9% 씩 분포하였다7. 선발한 7자원 종실의 전분 함량은 44.1∼57.0%, 단백질 함량은 23.3∼27.5% 범위로 유의차가 있었다. Sucrose함량은 자원에 따라 1.46∼2.03% 범위에 포함되어 유의차가 인정되었다.
This study was conducted to develop effective production system in greenhouse for leaves and stems of Angelica acutiloba by using connect pots in 2003 and 2004. Seed germination rate and plant biomass of Angelica acutiloba collected in 2004 were higher than those harvested in 2003. Germination rate of Angelica acutiloba seeds collected in 2003 was 10%, while germination rate of seeds collected in 2004 was above 90%. Especially, plant growth and yield of Angelica acutiloba grown in connect pots sized with 4 × 4 × 5cm(length × width × height) were the highest. These results indicate that leaf and stem production of Angelica acutiloba can be improved by using connect pots and optimizing seed collecting time in greenhouse.