• Spatial Information Research
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• v.18 no.5
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• pp.27-36
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• 2010

This study observed distribution of vegetation to confirm change of tundra-taiga boundary. Tundra-taiga boundary is used to observe the transfer of vegetation pattern because it is very sensitive to human activity, natural disturbances and climate change. The circumpolar tundra-taiga boundary could observe reaction about some change. Reaction and confirmation about climate change were definite than other place. This study used Leaf Area Index(LAI) 8-Day data in August from 2000 to 2009 that acquire from Terra satellite MODerate resolution Imaging Spectroradiometer(MODIS) sensor and used K$\"{o}$ppen Climate Map, Global Land Cover 2000 for reference data. This study conducted analysis of spatial distribution in low density vegetated areas and inter-annual / zonal analysis for using the long period data of LAI. Change of LAI was confirmed by analysis based on boundary value of LAI in study area. Development of vegetation could be confirmed by area of grown vegetation($730,325km^2$) than area of reduced vegetation ($22,372km^2$) in tundra climate. Also, area was increased with the latitude $64^{\circ}$ N~$66^{\circ}$ N as the center and around the latitude $62^{\circ}$ N through area analysis by latitude. Vegetation of tundra-taiga boundary was general increase from 2000 to 2009. While area of reduced vegetation was a little, area of vegetation growth and development was increased significantly.

• KOREAN JOURNAL OF CROP SCIENCE
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• v.27 no.1
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• pp.94-98
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• 1982

To understand the growth pattern of ginseng plant under shading, the vertical distribution of leaf area, leaf area index (LAI) and specific leaf weight (SLW) and changes in light intensity as affected by planting position were investigated in 3 to 5 years old ginseng plant populations. Light intensity was vertically lowest at about 10cm above the ground and became low at the rear planting position in 3-year-old population. When culturing bed (96cm in width) were divided into three parts at intervals of 32cm from front to rear, the leaf area in 3-year-old population was largest in middle 1/3 part of planting bed. Light intensity affected the SLW positively, but LAI showed no distinct difference among planting positions. The light environment of 4-year-old population was worse than that of 3-year-old population and leaf area and LAI differed greatly among planting positions. In 5-year-old population, leaf dry weight and leaf area of furrow part (that is, the amount of leaves protruded from the plants which were planted in 1st, 2nd or 3rd lines into the furrow) increased. The dry weights of leaves and stem increased considerably as plant became aged, and were distributed mainly in upper layer.

• KOREAN JOURNAL OF CROP SCIENCE
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• v.34 no.4
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• pp.364-369
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• 1989

Leaf characteristics of main stem and tiller of IK type maize (IK/ /IRI/B68) were compared with those of Jinjoo Ok hybrid which are not usually tillered. A total of nine leaves from flag leaf to the third or the fourth leaf below ear-bearing node were sampled from each stem or tiller. There was no significant difference in mean leaf length between IK/ /IRI/B68 and Jinjoo Ok. But the mean leaf width of IK/ /IRI/ B68 was about 2 cm narrower than that of Jinjoo Ok. The mean leaf area of the IK/ /IRI/B68 was also smaller than that of Jinjoo Ok due to the narrower leaf width. There were not significant differences in mean leaf characteristics between main stem and tillers of IK/IRI/B68. The longest leaf was the leaf below the ear-bearing node and the widest leaf was the leaf just above the ear-bearing node. Mean length. width and area of leaf on main stem and tillers were similar. Coefficients of variation calculated for individual leaf indicated that the leaves near the ear-bearing node were more uniform than others. The leaf area measured was significantly greater than that estimated by formular, length x width x 0.75. New constant to estimate leaf area of tillering maize was derived as 0.8.

• KOREAN JOURNAL OF CROP SCIENCE
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• v.5 no.1
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• pp.65-68
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• 1969

Studies wre made to investigate the relationships obetween measurable characters of leaf tobacco such as stem length, stem daimeter, number of leaves, leaf length, leaf thickness, leaf area of biggest leaf and the dry Iield. The results are summarized as follows; n the flue cured yellow tobacco; leaf width and leaf area of biggest leaf were significantly correlated to the yield. In the light air cure type of tobacco; stem diamer, leaf width and leaf area of biggest leaf were significantly correlated to the yield. In the dark air cured type of tobacco; stem diameter, number of leaves, leaf length, leaf width, and leaf area of biggest leaf were significantly correlated to the yield. It would be noticiable that the yield was significantly correlated to the leaf width which is easily measurable in the field, and negatively correlated to the leaf thickness though not significantly.

• Asian Journal of Turfgrass Science
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• v.7 no.2_3
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• pp.95-101
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• 1993

1992년 6월부터 1993년 9월 동안에 서울에서 이루어진 바랭이와 잔디의 분지형(branching pattern)과 유효엽면적(effective leaf area)에 대한 정량적 연구 결과는 다음과 같다. 1. 분지 끝 지점의 2차원적인 위치는 수학적 방식을 이용한 이론적 모델에 의해 분지사이의 각과 분지 길이들이 상대적인 비를 이용하여 계산할 수 있다. 2. 분지각과 분지길이의 상대적인 비는 바랭이나 잔디의 개체와 군락의 전체적인 구조를 효과적으로 분석하는데 있어 매우 적절하게 사용될 수 있다. 3. 시간에 따라 변화되는 분지형을 명확히 분석하기 위해 positive feedback theory를 성장 분석 모델로 적용하였다. 4. 분지의 마디 배열은 봄에서 여름에 이르는 생장 기간동안에 변화됨을 나타내었다. 주지(mother branch)와 복지(daughter branch)사이의 각은 적정치에 수렴하는 양상을 보였으며 그 평균값은 바랭이가 50도, 잔디가 59도임을 알 수 있었다. 5. 야외에서 관찰된 실험적 측정치아 모식적 구성을 통해서 최대 물질 생산과 연관된 햇빛 흡수와 수용의 극대화를 위한 분지형과 최대 유효엽면적의 상관 관계를 분석하였다. 6. 따라서 수학적 모식을 이용한 분지형 분석은 실험적 측정치와 잘 일치하며, 이런 수관형의 형성은 유전적 요소와 환경적 요소에 의해 영향을 받을 뿐만 아니라 식물의 적응적 중요성을 지니는 유효잎면적, 관수용 및 광합성과 물질생산의 극대화를 분석하는데도 유효하게 쓰일 수 있다.

• Proceedings of the Plant Resources Society of Korea Conference
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• 2020.12a
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• pp.76-76
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• 2020

최근 안전한 먹거리 생산과 치유, 교육 등 다양한 목적으로 도시농업에 참여하는 인구가 늘어남에 따라 도시텃밭의 농약, 비료 사용 등으로 인한 환경오염과 해충 피해, 농산물의 건강성 등 다양한 문제가 제기되고 있다. 따라서 도시텃밭 작물의 생육 증진, 잔류농약 문제 해결 등 농산물 안정성 증가에 기여하고자 식물추출물을 활용한 엇갈이 배추의 생육특성을 조사하였다. 선행연구 결과를 바탕으로 자원식물류 5종(쇠비름, 소리쟁이, 명아주, 박주가리, 환삼덩굴)과 허브류 5종(메리골드, 서던우드, 캐모마일, 애플민트, 로즈마리), 식용작물류 5종(양파, 마늘, 부추, 차즈기, 들깨) 등 추출 대상 식물 15종을 60℃에서 3일간 건조시켜 마쇄하였다. 이후 각 식물체 100g을 35% 에틸알코올 1,000ml에서 7일간 추출하였다. 추출물은 30%로 희석하여 주 2회씩 총 3주간 배추에 엽면살포하였다. 엽면적, 엽수, 지상부 및 지하부 생체중 등 생육특성을 7일 간격으로 조사하였으며 그 결과는 다음과 같다. 엽면적과 엽폭은 환삼덩굴 처리구에서 104.58cm²와 9.80cm로 가장 넓었고, 엽장은 박주가리 처리구에서 25.24cm로 가장 길었으며, 지하부 생체중은 메리골드 처리구에서 6.24g으로 가장 높았다. 엽수는 애플민트와 마늘 처리구에서 6.4개로 가장 많았고, 지상부 생체중과 엽록소는 집단 간 유의한 차이가 나타나지 않았다. 전반적으로 무처리 대비 엽면적 22%, 엽폭 18%의 유의한 생장 차이를 보인 환삼덩굴 추출물과 엽면적 12%, 엽장 17%의 생장 차이를 보인 박주가리 추출물, 엽면적 10%, 엽폭 9%의 생장 차이를 보인 양파 추출물이 엇갈이 배추 생육에 효과적인 것으로 나타났다. 본 연구결과 환삼덩굴, 박주가리, 양파 등 일부 식물추출물이 엇갈이 배추의 생육을 증진시킬 수 있는 것으로 나타나 주말농장 등 도시텃밭에 활용할 수 있을 것으로 사료되었다. 향후 식물추출물의 효과성을 증진시키기 위해 추출 방법과 적정 농도, 보관 시기 등에 대한 연구와 함께 도시텃밭 해충방제 효과를 알아보기 위한 약해검정과 살충효과를 분석할 필요성이 있다.

• Journal of Sericultural and Entomological Science
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• v.8
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• pp.11-25
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• 1968

Various formulae for estimation of leaf production in mulberry trees were investigated and obtained. Four varieties of mulberry trees were used as the materials, and seven characters namely branch length. branch diameter, node number per branch, total branch weight, branch weight except leaves, leaf weight and leaf area, were studied. The formulae to estimate the leaf yield of mulberry trees are as follows: 1. Varietal differences were appeared in means, variances, standard devitations and standard errors of seven characters studied as shown in table 1. 2. Y$_1$=a$_1$X$_1$${\times}$P$_1$......(l) where Y$_1$ means yield per l0a by branch number and leaf weight determination. a$_1$.........leaf weight per branch. X$_1$.......branch number per plant. P$_1$........plant number per l0a. 3. Y$_2$=(a$_2$${\pm}$S. E.${\times}$X$_2$)+P$_1$.......(2) where Y$_2$ means leaf yield per l0a by branch length and leaf weight determination. a$_2$......leaf weight per meter of branch length. S. E. ......standard error. X$_2$....total branch length per plant. P$_1$........plant number per l0a as written above. 4. Y$_3$=(a$_3$${\pm}$S. E${\times}$X$_3$)${\times}$P$_1$.....(3) where Y$_3$ means of yield per l0a by branch diameter measurement. a$_3$.......leaf weight per 1cm of branch diameter. X$_3$......total branch diameter per plant. 5. Y$_4$=(a$_4$${\pm}$S. E.${\times}$X$_4$)P$_1$......(4) where Y$_4$ means leaf yield per 10a by node number determination. a$_4$.......leaf weight per node X$_4$.....total node number per plant. 6. Y$\sub$5/= {(a$\sub$5/${\pm}$S. E.${\times}$X$_2$)Kv}${\times}$P$_1$.......(5) where Y$\sub$5/ means leaf yield per l0a by branch length and leaf area measurement. a$\sub$5/......leaf area per 1 meter of branch length. K$\sub$v/......leaf weight per 100$\textrm{cm}^2$ of leaf area. 7. Y$\sub$6/={(X$_2$$\div$a$\sub$6/${\pm}$S. E.)}${\times}$K$\sub$v/${\times}$P$_1$......(6) where Y$\sub$6/ means leaf yield estimated by leaf area and branch length measurement. a$\sub$6/......branch length per l00$\textrm{cm}^2$ of leaf area. X$_2$, K$\sub$v/ and P$_1$ are written above. 8. Y$\sub$7/= {(a$\sub$7/${\pm}$S. E. ${\times}$X$_3$)}${\times}$K$\sub$v/${\times}$P$_1$.......(7) where Y$\sub$7/ means leaf yield estimates by branch diameter and leaf area measurement. a$\sub$7/......leaf area per lcm of branch diameter. X$_3$, K$\sub$v/ and P$_1$ are written above. 9. Y$\sub$8/= {(X$_3$$\div$a$\sub$8/${\pm}$S. E.)}${\times}$K$\sub$v/${\times}$P$_1$.......(8) where Y$\sub$8/ means leaf yield estimates by leaf area branch diameter. a$\sub$8/......branch diameter per l00$\textrm{cm}^2$ of leaf area. X$_3$, K$\sub$v/, P$_1$ are written above. 10. Y$\sub$9/= {(a$\sub$9/${\pm}$S. E.${\times}$X$_4$)${\times}$K$\sub$v/}${\times}$P$_1$......(9) where Y$\sub$7/ means leaf yield estimates by node number and leaf measurement. a$\sub$9/......leaf area per node of branch. X$_4$, K$\sub$v/, P$_1$ are written above. 11. Y$\sub$10/= {(X$_4$$\div$a$\sub$10/$\div$S. E.)${\times}$K$\sub$v/}${\times}$P$_1$.......(10) where Y$\sub$10/ means leaf yield estimates by leaf area and node number determination. a$\sub$10/.....node number per l00$\textrm{cm}^2$ of leaf area. X$_4$, K$\sub$v/, P$_1$ are written above. Among many estimation methods. estimation method by the branch is the better than the methods by the measurement of node number and branch diameter. Estimation method, by branch length and leaf area determination, by formulae (6), could be the best method to determine the leaf yield of mulberry trees without destroying the leaves and without weighting the leaves of mulberry trees.

• Applied Biological Chemistry
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• v.15 no.1
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• pp.41-47
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• 1972

Comparative study on dynamic change of canopy structure during ripening period were carried out by using newly bred high yield rice cultivar (IR 667-Suwon 213) and a commercial variety, Jinhung in relation to nitrogen nutrition. The results were as follows. 1. Canopy structure pattern (vertical distribution of dry matter density at heading)was vertical type for Jinhung and horizontal type for IR 667. 2. The vertical distribution pattern of leaf area density (or weight) in the canopy was central dominant type for IR 667 while apical dominant type for Jinhung. 3. Canopy conservation pattern and percent distribution pattern of leaf area density followed the vertical distribution pattern of leaf area density. 4. Canopy persistence was weaker in IR 667, thus they have smaller canopy conservation ratio indicating faster senescence. 5. Slow supply of nitrogen (sulfur coated urea) showed a trend to change the apical dominant pattern into the central dominant pattern by the conservation of central portion, and it-resulted in higher yield though nitrogen nutrition did little affect canopy pattern. 6. The central and apical dominant pattern appeared to be well matched to the upper leaf-dependent type and the lower leaf-dependent type of grain yield, respectively.

• Korean Journal of Breeding Science
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• v.40 no.2
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• pp.143-152
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• 2008

This study was conducted to obtain basic information on mainstem, branch and leaf characteristics related to canopy for development of high yielding cultivar using 70 Korean soybean cultivars developed from 1913 to 2000. Variations of canopy width, branch length, and canopy width/length ratio were higher compared to other characteristics among 12 mainstem and branch characters. Variations of petiole angle, leaflet width/length ratio and compound leaf dry weight were higher than other characteristics among eight leaf characters related to plant canopy. Three classifications of soybean cultivars were used based on usage: I)soy sauce and tofu, II)bean sprout, and III)cooking with rice. Canopy width/length ratio was higher in group III, cooking with rice than group I, soy sauce and tofu, and group II, bean sprout, and there was no difference between the two, group I and group II. The total branch length/main stem height ratio was higher in group II, bean sprout and group III, cooking with rice than group I, soy sauce and tofu. Mainstem and branch characteristics related to plant canopy were classified into four groups by ratio of canopy width/length and total branch length/main stem length, respectively. Soybean cultivars with narrow canopy and high dependence of mainstem were Danweonkong, Keumkangkong, Shelby, and Shinpaldalkong. Soybean cultivars with broad canopy and high dependence of mainstem were Kanglim, Keumkangdaelip, and Jinyulkong, and a cultivar with broad canopy and high dependence of branch were Geomjeongkong 2. Leaflet length/width ratio was lowest in cooking with rice and there was no difference between soy sauce and tofu and bean sprout. Compound leaf area was largest in cooking with rice and smallest in bean sprout. Leaf petiole length was short in bean sprout and there was no difference between soy sauce and tofu and bean sprout. Leaf petiole angle was highest in cooking with rice and lowest in bean sprout. Leaf type was classified into four groups based on leaflet width/length ratio and compound leaf area, respectivly. Buseok and Taekwangkong had an oval leaflet and largest area of compound leaf. Eunhakong and Sohokong had extreme narrow leaflet and smallest area of compound leaf. Leaf petiole type was classified into three and four groups based on leaf petiole length and angle, respectively. A soybean cultivar with the shortest petiole length and smallest petiole angle was Eunhakong and cultivars with short petiole length and large petiole angle were Alchankong, Muhankong, and Pureunkong. A soybean cultivar with long petiole length and small petiole angle was Sinpaldalkong 2. Among a total of 70 Korean soybean cultivars, Eunhakong had an extreme narrow type in leaf, smallest compound leaf area, shortest petiole length, and smallest petiole angle of compound leaf.

• Horticultural Science & Technology
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• v.17 no.5
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• pp.581-583
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• 1999

This experiment was conducted to investigate the effects of uniconazole drench treatment on the growth and flowering of poinsettia and to suggest proper application dosage and time. Plant height, branch length, and leaf area were significantly restricted as the concentration of uniconazole increased. Application doses of 0.05 and 0.10 mg/pot effectively controlled the growth of poinsettia 'V-10 Amy'. Earlier soil drench of uniconazole resulted in more effective reduction in plant height, branch length, and leaf area. In all cases, no noticeable phytotoxicity by plant growth retardants tested was observed.