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http://dx.doi.org/10.12791/KSBEC.2022.31.3.204

Selection of Supplemental Light Source for Greenhouse Cultivation of Pepper during Low Radiation Period through Growth and Economic Analysis  

Hwang, Hee Sung (Division of Crop Science, Graduate School of Gyeongsang National University)
Lee, Kwang Hui (Division of Crop Science, Graduate School of Gyeongsang National University)
Jeong, Hyeon Woo (Division of Applied Life Science, Graduate School of Gyeongsang National University)
Hwang, Seung Jae (Division of Horticultural Science, College of Agriculture & Life Sciences, Gyeongsang National University)
Publication Information
Journal of Bio-Environment Control / v.31, no.3, 2022 , pp. 204-211 More about this Journal
Abstract
To produce a high quality crop, light is an essential environmental factor in greenhouse cultivation. In the winter season, solar radiation is weak than other season. Therefore, using supplemental light during a low radiation period can increase the crop growth and yield. This study was conducted to select the economical supplemental light source for greenhouse cultivation in pepper during the low radiation period. The green pepper (Capsicum annuum 'Super Cheongyang') was transplanted on 5 September 2019. Supplemental lighting treatment was conducted from 1 January 2020 to 31 March 2020. RB LED (red and blue LED, red:blue = 7:3), W LED (white LED, R:G:B = 5:3:2), and HPS (high-pressure sodium lamp) were used as the supplemental light source. Non-treatment was used as the control. The plant height, SPAD, and number of nodes of pepper plants have no significant differences by supplemental light sources. However, the number of ramifications plants was the greatest in RB LED light source. Moreover, supplemental lighting increased photosynthesis of the pepper plant, and especially, the RB LED had the highest photosynthesis rate during supplemental lighting period. Also, the yield of pepper increased in the supplemental lighting treatment than in the control, and the RB LED had the greatest yield than other light sources. The electricity consumption was the highest in W LED and the lowest in HPS light. Through the economic analysis, the RB LED had high economic efficiency. In conclusion, these results suggest that using RB LED for supplemental light source during low radiation in pepper greenhouse increase the yield and economic feasibility.
Keywords
economic feasibility; electricity consumption; high-pressure sodium lamp; RB LED; White LED;
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1 Jeong K.J., J.G. Yun, Y.S. Chon, H.S. Shin, and S.W. Lee 2018, Effect of supplementary or heating lamps on the yield, vase life, and leaf color of cut rose. Protected Hort Plant Fact 27:158-165. (in Korean) doi:10.12791/KSBEC.2018.27.2.158   DOI
2 Jeong W.J., I.K. Kang, J.Y. Lee, S.H. Park, H.S. Kim, D.J. Myoung, G.T. Kim, and J.H. Lee 2008, Study of dry and bio-mass of sweet pepper fruit and yield between glasshouse and plastic greenhouse. J Bio-Env Con 17:541-544.
3 Rural Development Administration (RDA) 2022a, Agricultural work schedule: Vegetables - pepper (normally cultivated). Available via https://www.nongsaro.go.kr/portal/ps/psb/psbl/workScheduleDtl.ps?menuId=PS00087&cntntsNo=30600 Accessed 17 May 2022.
4 Statistics Korea 2021, Crop production survey. Available via https://kosis.kr/index/index.do. Accessed 19 November 2021.
5 Wang H., M. Gu, J.X. Cui, K. Shi, Y.H. Zhou, and J.Q. Yu 2009, Effects of light quality on CO2 assimilation, chlorophyll-fluorescence quenching, expression of calvin cycle genes and carbohydrate accumulation in Cucumis sativus. J Photochem Photobiol B 96:30-37. doi:10.1016/j.jphotobiol.2009.03.010   DOI
6 Whitehead D., K.L. Griffin, M.H. Turnbull, D.T. Tissue, V.C. Engel, K.J. Brown, W.S.F. Schuster, and A.S. Walcroft 2004, Response of total night-time respiration to differences in total daily photosynthesis for leaves in a Quercus rubra L. canopy: implications for modelling canopy CO2 exchange. Glob Change Biol 10:925-938. doi:10.1111/j.1365-2486.2004.00739.x   DOI
7 Jun H.J., S.S. Liu, E.H. Jeon, G.H. Bae, and S.I. Kang 2013, Effect of low temperature-darkness treatment of floral initiation and flowering response of Korean strawberry cultivars. Korean J Hortic Sci Technol 31:726-731. (in Korean) doi:10.7235/hort.2013.13058   DOI
8 An C.G., Y.H. Hwang, J.U. An, H.S. Yoon, Y.H. Chang, G.M. Shon, and S.J. Hwang 2011, Effect of LEDs (light emitting diodes) irradiation on growth of paprika (Capsicum annuum 'Cupra'). J Bio-Env Con 20:253-257. (in Korean)
9 Carvalho R.F., M. Takaki, and R.A. Azevedo 2011, Plant pigments: The many faces of light perception. Acta Physiol Plant 33:241-248. doi:10.1007/s11738-010-0533-7   DOI
10 Gardner F.P., R.B. Pearce, and R.L. Mitchell 2020, Photosynthesis and respiration. Physiology of crop plants, Translated by S.Y. Nam. Ed 1, RGB Press Seoul, Korea, pp 101-135. (in Korean)
11 Choi J.W., H.J. Choi, J.G. Kim, J.H. Lee, C.K. Kim, I.S. Shin, and Y.P. Hong 2019, Review of postharvest management to expand the export of fresh perilla leaves. Korean J Food Preserv 26:730-739. (in Korean) doi:10.11002/kjfp.2019.26.7.730   DOI
12 Kim Y.B., J.H. Bae, and M.H. Park 2011, Effects of supplemental lighting on growth and yield of sweet pepper (Capsicum annuum L.) in hydroponic culture under low levels of natural light in winter. Korean J Hortic Sci Technol 29:317-325. (in Korean)
13 Lee Y.B., H.J. Jun, J.E. Son, H.M. Kang, Y.S. Kim, Y.H. Kim, I.S. Kim, S.W. Nam, K.W. Park et al. 2010, Light environment. Shingo Protected Horticulture, Ed 1, Hyangmoonsa, Seoul, Korea, pp 98-120. (in Korean)
14 Lee J.H., J.H. Jeong, S. Kim, W.Y. Choi, and K.B. Lee 2014, Effect of LEDs (light emitting diodes) on paprika (Capsicum annuum L.) growth and yield in glasshouse in reclaimed land. Korean J Int Agric 26:279-283. (in Korean) doi:10.12719/KSIA.2014.26.3.279   DOI
15 Marcelis L.F.M., E. Heuvelink, L.R.B. Hofman-Eijer, J.D. Bakker, and L.B. Xue 2004, Flower and fruit abortion in sweet pepper in relation to source and sink strength. J Exp Bot 55:2261-2268. doi:10.1093/jxb/erh245   DOI
16 Nongnet 2022, Wholesale and retail price analysis. Available via https://www.nongnet.or.kr/anss/wsrtPrceInfo.do Accessed 17 May 2022.
17 Choi J.H., E.S. Kang, J.S. Kim, and J.S. Eun 2015, Effect of LED lighting on growth and functional material contents in perilla (Perilla frutesens L.). J Agric Life Environ Sci 46:9-15. (in Korean)
18 Jeong W.J., J.H. Lee, H.C. Kim, and J.H. Bae 2009, Dry matter production, distribution and yield of sweet pepper grown under glasshouse and plastic greenhouse in Korea. J Bio-Env Con 18:258-265. (in Korean)
19 Khan S., A. Basit, M.B. Hafeez, S. Irshad, S. Bashir, S. Bashir, M.M. Maqbool, M.S. Saddiq, Z. Hasnain, B.S. Aljuaid, A.M. El-Shehawi, and Y. Li 2021, Moringa leaf extract improves biochemical attributes, yield and grain quality of rice (Oryza sativa L.) under drought stress. PLOS ONE 16:1-14. doi:10.1371/journal.pone.0254452   DOI
20 Kwon J.K., I.H. Yu, K.S. Park, J.H. Lee, J.H. Kim, J.S. Lee, and D.S. Lee 2018, Supplemental lighting by HPS and PLS lamps affects growth and yield of cucumber during low radiation period. Protected Hort Plant Fac 27:400-406. (in Korean) doi:10.12791/KSBEC.2018.27.4.400   DOI
21 Lucien T.T., M. Abba, S.N.Y. Christelle, and M. Clautilde 2019, Growth, fruits yield and fruits physicochemical properties of Capsicum annum L. as affected by compost and vivianite powder at dang locality in adamawa Cameroon. Haya: Saudi J Life Sci 4:318-325. doi:10.36348/SJLS.2019.v04i09.005   DOI
22 Mckee T., and J.R. Mckee 2004, Photosynthesis. Biochemistry: the molecular basis of life, Translated by I.K. Park. Ed 3, Life Science Press, Seoul, Korea, pp 313-338. (in Korean)
23 Kim J.S., G.H. Yon, B.G. Kim, J.S. Choi, E.A. Kim, Y.K. Ko, and I.Y. Lee 2020, Application of mevalocidin as a new plant growth regulator for thinning and lateral lateral shoot induction. Weed Turf Sci 9:29-42. (in Korean) doi:10.5660/WTS.2020.9.1.29   DOI
24 Rho I.R., Y.S. Cho, J.W. Cheong, H.J. Jeong, and H.B. Jeong 2007, Effect of low-temperature and short-photoperiod treatment during a high-temperature season on flower bud formation and generation acceleration of short-day strawberry. Korean J Hortic Sci Technol 25:12-16. (in Korean)
25 Myoung D.J. 2008, Correlation between climatic factors and yield of sweet pepper (Capsicum annuum L.) in glasshouse. MS Thesis, Chonnam National University, Gwangju, Korea. (in Korean)
26 Hong J.W. 2020, Study on the plant growth variation according to change of luminous flux LED light in plant factory. Journal of the Korea Academia-Industrial Cooperation Society 21:304-311. (in Korean) doi:10.5762/KAIS.2020.21.3.304   DOI
27 Park K.S., D.Y. Kwon, J.W. Lee, and J.E. Son 2018, Comparing photosynthesis, growth, and yield of paprika (Capsicum annuum L. 'Cupra') under supplemental sulfur plasma and high-pressure sodium lamps in growth chambers and greenhouses. Protected Hort Plant Fac 27:332-340 (in Korean) doi:10.12791/KSBEC.2018.27.4.332   DOI
28 Randall W.C., and R.G. Lopez 2014, Comparison of supplemental lighting from high-pressure sodium lamps and lightemitting diodes during bedding plant seedling production. HortScience 49:589-595. doi:10.21273/HORTSCI.49.5.589   DOI
29 Rural Development Administration (RDA) 2022b, Agricultural work schedule: Vegetables - pepper (forcing cultivated). Available via https://www.nongsaro.go.kr/portal/ps/psb/psbl/workScheduleDtl.ps?menuId=PS00087&cntntsNo=30601 Accessed 17 May 2022
30 Kim Y.J., H.M. Kim, and S.J. Hwang 2016, Growth and phytochemical contents of ice plant as affected by light quality in a closed-type plant production system. Korean J Hortic Sci Technol 34:878-885. (in Korean) doi:10.12972/kjhst.20160092   DOI