Comparison of Light Utilization Efficiency in terms of the Planting Distance, Orientation, and Tree Height for a High-Density Apple Orchard

IF 1 4区农林科学 Q3 HORTICULTURE Korean Journal of Horticultural Science & Technology Pub Date : 2023-06-30 DOI:10.7235/hort.20230024

Chung-Sil Kim, Byeong-Ho Choi, Young-Ju Jung, Tae-Myung Yoon

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Abstract

The Shadow patterns of various apple planting systems, and tree height are tracked using Sketch Up (Trimble, Inc. 3D Design software). A Model of a tall spindle established by combining planting distances applicable to Korea. The row orientation was set to four directions: N-S, NW-SE, NE-SW, and E-W. Each planting system simulated hours without sunlight-interference by the adjacent row and the sunlight-interference percentage in the canopy according to the adjacent tree during the growing season. The hours without sunlight-interference by adjacent rows on June 21 were N-S rows at 3.98 to 7.20 hours, NW-SE rows at 5.30 to 9.27 hours, NE-SW rows at 5.27 to 9.02 hours, and E-W rows at 10.38 to 11.78 hours. Sunlight-interference percentages in the morning and afternoon were as follows: N-S rows at 14.8% and 14.8%, NW-SE rows at 32.2% and 21.1%, NE-SW rows at 31.5% and 41.8%, and E-W rows at 53.6% and 50.4%, respectively. For the N-S rows, the overall growing season was favorable. E-W rows were unfavorable among row orientations due high interference level by adjacent trees. As the tree height increased from 2.5 to 5.0 m regardless of the row orientation, the hours without interference by adjacent trees decreased. However, an empirical test for light transmittance and radiation in the planting systems not considered in this study is additionally required.

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高密度苹果园种植距离、朝向和树高对光利用效率的比较

使用Sketch Up (Trimble, Inc. 3D设计软件)跟踪各种苹果种植系统的阴影模式和树木高度。结合种植距离建立了适用于韩国的高纺锤体模型。行向设置为N-S、NW-SE、NE-SW、E-W四个方向。每个种植系统模拟相邻行无光照干扰小时数，并根据生长季节相邻树的冠层日照干扰百分比。6月21日无相邻行日照干扰时数为南北向3.98 ~ 7.20小时，西北偏南5.30 ~ 9.27小时，东北偏南5.27 ~ 9.02小时，东西向10.38 ~ 11.78小时。上午和下午的光干扰率分别为:N-S行14.8%和14.8%，NW-SE行32.2%和21.1%，NE-SW行31.5%和41.8%，E-W行53.6%和50.4%。对于N-S行，整个生长季节是有利的。由于邻近树木的干扰程度高，东西向行对行向不利。无论行向如何，随着树高从2.5 m增加到5.0 m，不受相邻树干扰的时间减少。但是，还需要对本研究未考虑的种植系统的透光率和辐射率进行实证测试。

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来源期刊

Korean Journal of Horticultural Science & Technology 农林科学-园艺

CiteScore

2.00

自引率

0.00%

发文量

审稿时长

1 months

期刊介绍： Horticultural Science and Technology (abbr. Hortic. Sci. Technol., herein ‘HST’; ISSN, 1226-8763), one of the two official journals of the Korean Society for Horticultural Science (KSHS), was launched in 1998 to provides scientific and professional publication on technology and sciences of horticultural area. As an international journal, HST is published in English and Korean, bimonthly on the last day of even number months, and indexed in ‘SCIE’, ‘SCOPUS’ and ‘CABI’. The HST is devoted for the publication of technical and academic papers and review articles on such arears as cultivation physiology, protected horticulture, postharvest technology, genetics and breeding, tissue culture and biotechnology, and other related to vegetables, fruit, ornamental, and herbal plants.