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참외의 묘소질 향상을 위한 LED 보광 효과 = LED supplemental lighting effect for improvement of seedling quality of Korean melon

이지은 2018년

논문상세정보
인용/피인용
' 참외의 묘소질 향상을 위한 LED 보광 효과 = LED supplemental lighting effect for improvement of seedling quality of Korean melon' 의 주제별 논문영향력
논문영향력 선정 방법
논문영향력 요약
주제
  • 정원농작물(원예학) 채소
  • 광조사 시간
  • 광주기
  • 광질
  • 광합성유효광량자속밀도
동일주제 총논문수 논문피인용 총횟수 주제별 논문영향력의 평균
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' 참외의 묘소질 향상을 위한 LED 보광 효과 = LED supplemental lighting effect for improvement of seedling quality of Korean melon' 의 참고문헌

  • van Ieperen, W., A. Savvides, and D. Fanourakis. 2012. Red and blue light effects during growth on hydraulic and stomatal conductance in leaves of young cucumber plants. Acta Hortic. 956:223-230.
  • Zhang, S., K. Ma, and L. Chen. 2003. Response of photosynthetic plasticity of Paeonia suffruticosa to changed light environments. J. Environ. Exp. Bot. 49:121-133.
  • Zhang, C.H., I.J. Chun, Y.C. Park, and I.S. Kim. 2003. Effect of timings and light intensities of supplemental red light on the growth characteristics of cucumber and tomato plug seedlings. J. Bio-Environ. Con. 12:173-179 (in Korean).
  • Yoshida, O.K. 1966. Analytical method of root activity. J. Jpn. Soc. Soil Sci. Fert. 37:63-68.
  • Yonhap news. 2016. Korean melon is international name ‘korean melon’. http://www.yonhapnews.co.kr/bulletin/2016/05/03/0200000000AKR20160503175900017.HTML?input=1195m
  • Yeh, N. and J.P. Chung. 2009. High-brightness LEDs-energy efficient lighting sources and their potential in indoor plant cultivation. Renewable and Sustainable Energy Rev. 13:2175-2180.
  • Yanagi, T., K. Okamoto, and S. Takita. 1996. Effects of blue, red, and blue red light of two different PPF levels on growth and morphogenesis of lettuce plants. Acta Hort. 440:117-122.
  • Wu, M.C., C.Y. Hou, C.M. Jiang, Y.T. Wang, C.Y. Wang, H.H. Chen and H.M. Chang. 2007. A novel approach of LED light radiation improves the antioxidant activity of pea seedlings. Food Chem. 101: 1753-1758.
  • Wongnok, A., C. Piluek, T. Techasipitak, and S. Tantivivat. 2008. Effects of light emitting diodes on micropropagation of Phalaenopsis orchids. Acta Hort. 788:149-156.
  • Wink, M., 2010. Functions and Biotechnology of Plant Secondary Metabolites. Annual Plant Reviews, 3. Wiley-Blackwell, Oxford, p. 410.
  • Wetzstein, H.Y. and H.E. Sommer. 1983. Scanning electron microscopy of in vitro cultured Liquidambar styraciflua plantlets during acclimatization. J. Am. Soc. Hort. Sci. 108:475-480.
  • Weston, E., K. Thorogood, G. Vinti, and J.E. Lopez. 2000. Light quantity controls leaf-cell and chloroplast development in Arabidopsis thaliana wild type and blue-light perception mutants. J. Planta. 211:807–815.
  • Wentworth, M., E.H. Murchie, J.E. Gray, D. Villegas, C. Pastenes, M. Pinto, and P. Horton. 2006. Differential adaptation of two varieties of common bean to abiotic stress.Ⅱ. Acclimation of photosynthesis. J. Exp. Bot. 57:699-709.
  • 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. Photochemistry and photobiology B:Biology 96:30-37.
  • Um. E.K. 2015. Effect of light quality on red leaf expression of variegated Begonia for indoor vertical gardening system. PhD Diss., University of Seoul, Seoul. p. 73-74.
  • Um, Y.C., Y.A. Jang, J.G. Lee, S.Y. Kim, S.R. Cheong, S.S. Oh, S.H. Cha, and S.C. Hong. 2009. Effects of selective light sources on seedling quality of tomato and cucumber in closed nursery system. J. Bio-Environ. Con. 18:370-376.
  • Tibbitts, T.W., D.C. Morgan, and J.J. Warrington. 1983. Growth of lettuce, spinach, mustard and wheat plants under four combinations of high pressure sodium, metal halide and tungsten halogen lamps at equal PPFD. J. Amer. Soc. Hort. Sci. 108:622-630.
  • Terashima, I., Y.T. Hanba, Y. Tazoe, P. Vyas, S. Yano. 2006.
  • Takahashi, S. and N. Murata. 2008. How do environmental stresses accelerate photo inhibition? J. Trends Plant. 13:178–182.
  • Steinger, T., B.A. Roy, and M.L. Stanton. 2003. Evolution in stressful environments Ⅱ: adaptive value and costs of plasticity in response to low light in Sinapis arvensis. J. Evol. Biol. 16:313-323.
  • Son, K.H., J.H. Park, D.I. Kim, and M.M. Oh. 2012. Leaf shape index, growth, and phytochemicals in two leaf lettuce cultivars grown under monochromatic light-emitting diodes. Kor. J. Hort. Sci. Technol. 30:664-672.
  • Sims, D.A. and R.W. Pearcy. 1994. Scalling sun and shade photosynthetic acclimation of Alocasia macrorrhiza(Araceae) to a transfer from low to high light. Am. J. Bot. 79:449-455.
  • Shin, Y.S., H.W. Do, H.R. Sohn, J.D. Cheung, J.E. Lee, and M.K. Kim. 2015. A korean melon library. Seongju Korean Melon Fruit Vegetable Research Institute Press. pp. 41 (in Korean).
  • Shin, J. H., H.H. Jung, and K.S. Kim. 2010. Night interruption using light emitting diodes (LEDs) promotes flowering of Cyclamen persicum in winter cultivation. Hort. Enviro. Biotechnol. 51:391-395.
  • Shimazaki, K., M. Doi, S.M. Assmann, and T. Kinoshita. 2007. Light regulation of stomatal movement. Annu. Rev. Plant Biol. 58:219-247.
  • Senger, H. 1982. The effect of blue light on plants and microorganisms. Photochemistry and Photobiology. 35:911-920.
  • Salisbury, F.B., and C.W. Ross. 1992. Plant physiology, 4th edition, Wadsworth Pub. Com. Belmont, California.
  • Sakihama Y., M.F. Cohen, S.C. Grace and H. Yamasaki. 2002. Plant phenolic antioxidant and prooxidant activities: phenolics induced oxidative damage mediated by metals in plant. Toxicology. 177:67-80.
  • Saebo, A., T. Krekling, M. Appelgren. 1995. Light quality affects photosynthesis and leaf anatomy of brich plantlets in vitro. Plant cell Tissue and Org. Cult. 41:177-185.
  • Rural Development Administration (RDA), Republic of Korea. 2012. Research analysis criteria of agricultural science and technology. Fifth edition. RDA Press. pp. 508 (in Korean).
  • Re, R., N. Pellegrini, A. Proteggente, A. Pannala, M. Yang, and C. Rice-Evans. 1999. Antioxidant activity applying an improved ABTS radical cation decolorization assay. Free Radic. Biol. Med. 26:1231-1237.
  • RDA. 2013. Korean melon cultivation-agricultural technology guide (105). p. 29 (in Korean).
  • Pushnik, J.C., G.W. Miller, V.D. Jolly, J.C. Brown, T.D. Davis, and A.M. Barnes. 1987. Influences of UV-blue light radiation on the growth of cotton. Ⅱ. Photosynthesis, leaf anatomy, and iron reduction. J. Plant Nutr. 10:2283-2297.
  • Park, K.H., H.T. Park, H.S. Han, and D.P. Lee. 2011. A study on the current state and developmnet strategies of raising seedlings industry. Korea Rural Economic Institute. p. 1-163.
  • Park, J.E., Y.G. Park, B.R. Jeong, and S.J. Hwang. 2012. Growth and anthocyanin content of lettuce as affected by arificial light source and photoperiod in a closed-type plant production system. Kor. J. Hortic. Sci. Technol. 30:673-679 (in Korean).
  • Park, H.Y., K.C. Son, E.G. Gu, K.B. Lim, and B.H. Kim. 1996. Effect of different day and night temperature regimes on the growth of hot pepper plug seedlings. J. Kor. Soc. Hort. Sci. 37:617-621.
  • Paek, K.Y. and E.J. Hahn. 2000. Cytokinins, auxins and activated charcoal affect organogenesis and anatomatical characteristics of shoot tip cultures of lisianthus (Eustoma Grandiflorum). In Vitro Cell. Dev. Biol. 36:128-132.
  • Paek, K.Y. 2003. Effect of light emitting diodes (LED) on the growth and photomorphogenesis in horticultural plants. Ministry of Agriculture and Forestry. Korea.
  • Ouzounis, T., X. Frett , E. Rosenqvist, and C.O. Ottosen. 2014. Spectral effects of supplementary lighting on the secondary metabolites in roses, chrysanthemums, and campanulas. J. Plant. Physiol. 171:1491-1499.
  • Okamoto, K., T. Yanagi, S. Takita, M. Tanaka, T. Higuchi, Y. Ushida, and H. Watanabe. 1996. Development of plant growth apparatus using blue and red LED as artificial light source. Acta Hort. 440:111-116.
  • Oh, S.J., H.K. Kwon, J.Y. Jeon, and H.S. Yang. 2015. Effect of monochromatic light emitting diode on the growth of four microalgae species. Journal of the Korean Society of Marine Environment and Safety 21:1-8.
  • Nishimura, T., K. Ohyama, E. Goto, and N. Inagaki. 2009. Concentrations of perill aldehyde, limonene, and anthocyanin of Perilla plants as affected by light quality under controlled environments. Scientia Hort. 122:134-137.
  • Nanya, K., Y. Ishigami, S. Hikosaka, and E. Goto. 2012. Effects of blue and red light on stem elongation and flowering of tomato seedlings. Acta Hortic. 956:264-266.
  • Murage, E.N., Watashiro, N., Masuda, M., 1996. Leaf chlorosis and carbonmetabolism of eggplant in response to continuous light and carbon dioxide.Sci. Hortic. 67, 27–37.
  • Morais, H., Medri, M.E., Marur, C.J., Caramori, P.H., Ribeiro, A.M., Gomes, J.C. 2004. Modifications on leaf anatomy of coffea arabica caused by shade of pigeonpea(Cajanus cajan). Braz. Arch. Biol. Technol. J. 47:863-871.
  • Moon, W. and S.G. Lee. 2002. Cultivated plant physiology. Korea National Open University Press. p. 190, 215, 349 (in Korean).
  • Middleton, E.M. and A.H. Teramura. 1993. The role of flavonol glycosides and carotenoids in protecting soybean from ultraviolet-B damage. Plant Physiol. 103:741-752.
  • Meyers, K.J., C.B. Watkins, M.P. Pritts, and R.H. Liu. 2003. Antioxidant and antiproliferative activities of strawberries. J. Agric. Food Chem. 51:6887-6892.
  • Merzlyak, M.N., T.B. Melo, and K.R. Naqvi. 2008. Effect of anthocyanins, carotenoids, and flavonols on chlorophyll fluorescence excitation spectra in apple fruit: Signature analysis, assessment, modelling, and relevance to photoprotection. J Exp. Bot. 59:349-359.
  • McNellis, T.W. and X.W. Deng. 1995. Light control of seedling morphogenetic pattern. J. Plant Cell 7:1749–1761.
  • McCree, K.J. 1971. The action spertrum, absorptance and quantum yield of photosynthesis in crop plants. Agric. Meteorol. 9:191-216.
  • Matos, F.S., R. Wolfgramm, F.V. Goncalves, P.C. Cavatte, M.C. Ventrella, F.M. DaMatta. 2009. Phenotypic plasticity in response to light in the coffee tree. J. Environ. Exp. Bot. 67:421-427.
  • Massa, G.D., H.H. Kim, and R.M. Wheeler. 2008. Plant productivity in response to LED lighting. HortiScience 43:1951-1956.
  • Markovic, V., M. Djurovka, Z. Ilin, and B. Lazic. 2000. Effect of seedling quality on yield characters of plant and fruits of sweet pepper. Acta Hort. 533:113-120.
  • Liu, X.Y., T.T. Chang, S.R. Guo, Z.G. Xu, and J. Li. 2011. Effects of different light quailty of LED on growth and photosynthetic characters in cherry tomato seedlings. Acta Hortic. 907:325-330.
  • Li, Q. and C. Kubota. 2009. Effects of supplemental light quality on growth and phytochemicals of baby leaf lettuce. Environ. Exp. Bot. 67:59-64.
  • Li, H., C. Tang, and Z. Xu. 2013. The effects of different light qualities on rapeseed (Brassica napus L.) plantlet growth and morphogenesis in vitro. Scientia Horticulturae 150:117-124.
  • Lefsrud, M.G., D.A. Kopsell, R.M. Aug , and A.J. Both. 2016. Biomass production and pigment accumulation in kale grownunder increasing photoperiods. HortScience 41:603-606.
  • Lee, S.W. 2010. Plant factory and plant cultivation using LED artificial light. Optical Society of Korea. 14:12-19.
  • Lee, S.G., Y.C. Kim, T.C. Seo, Y.G. Kang, H.K. Yun, and H.D. Suh. 2003. Effects of low light intensity after fruit set on growth and quality of oriental melon(Cucumis melo var. makuwa Makion). J. Kor. Soc. Hort. Sci. 44:31-34.
  • Lee, J.S., H.I. Lee, and Y.H. Kim. 2012. Seedling quality and early yield after transplanting of paprika nursed under light-emitting diodes, fluorescent lamps and natural light. J. Bio-Environ. Con. 21:220-227 (in Korean).
  • Lee, J.E., Y.S. Shin, H.W. Do, J.D. Cheung, and Y.H Kang. 2016b. Effect of seedling quality and growth after transplanting of korean melon nursed under LED light sources and intensity. J. Bio-Environ. Con. 25:294-301 (in Korean).
  • Lee, J.E., Y.S. Shin, H.W. Do, H.R. Sohn, J.D. Cheung, S.H. Oh, and M.K. Kim. 2016a. Manual of hight quality seedling production for korean melon. Seongju Korean Melon Fruit Vegetable Research Institute Press. pp. 94 (in Korean).
  • Lee, H.J., S.K. Lee, Y.S. Shin, H.W. Do, J.M. Lee, G.J. Choi, and D.G. Park. 2014. Sweet fragrant of vegetables (korean melon-melon industry dilemma). Rural Development Administration. RDA Interrobang(No. 125).
  • Lee, B.J., M.K. Won, D.H. Lee, and D.G. Shin. 2001. Changes in SPAD chlorophyll value of chrysanthemum (Dendranthema grandiflora Tzvelev) by photoperiod and light intensity. Kor. J. Hortic. Sci. Technol. 19:555-559.
  • Landry, L.G., C.C. Chapple, and R.L. Last. 1995. Arabidopsis mutants lacking phenolic sunscreens exhibit enhanced ultraviolet-B injury and oxidative damage. Plant Physiol. 109:1159-1166.
  • Kwack, Y.R., D.S. Kim, and C.H. Chun. 2014. Optimum cultivation period and rockwool block size for paprika transplant production using a closed transplant production system. J. Bio-Environ. Con. 23:139-143 (in Korean).
  • Ku, K.M., B.S. Kim and Y.H. Kang. 2010. Antioxidant activity and quinone reductase inductive activity of pepper leaves according to leaf lengths. Kor. J. Hort. Sci. Technol. 28:120-125.
  • Kozai, T., C. Kubota, C. Chun, K. Ohyama, and F. Afreen. 2000. Necessity and concept of the closed transplant production system, in: Kubota, C. and Chun, C. (eds.), Transplant production in the 21st century. Kluwer Academic publisher, Dordrecht, pp. 3-19.
  • Kozai, T. 2007. Propagation, grafting and transplant production in closed systems with artificial lighting for commercialization in japan. Propagation of Ornamental Plants 7:145-149.
  • Kopsell, D.A. and C.E. Sams. 2013. Increases in shoot tissue pigments, glucosinolates, and mineral elements in sprouting broccoli after exposure to short-duration blue light from light emitting diodes. J. Amer. Soc. Hortic. Sci. 38:31–37.
  • Koontz, H.V. and R.P. Prince. 1986. Effect of 16 and 24 hours daily radiation (light) on lettuce growth. HortScience 21:123-124.
  • Kim, Y.H., Y.H. Choi, M.G. Lee, H.J. Kim, J.W. Lee, D.M. Park, and H.D. Suh. 2003. Yield of tuber after transplanting of potato plug seedlings produced at different light quailty. Kor. J. Hort. Sci. Technol. 21(suppl. Ⅰ): 44 (in Korean).
  • Kim, Y.H. and S.H. Lee. 2006. Variation of plant temperature at joining parts of grafted watermelon seedlings graft-taken under different light quality. Biosystems Engineering 31:449-453.
  • Kim, Y.H. and J.S. Lee. 2016. Growth and contents of anthocyanins and ascorbic acid in lettuce and affected by supplemental UV-A LED irradiation with different light quality and photoperiod. Kor. J. Hortic. Sci. Technol. 34:596-606.
  • Kim, Y.H. and H.S. Park. 2002. Growth of cucumber plug seedlings as affected by photoperiod and photosynthetic photon flux. J. Bio-Environ. Con. 11:40-44 (in Korean).
  • Kim, Y.H. and H.S. Park. 2001. Graft-taking characteristics of watermelon grafted seedlings as affected by blue, red and far-red light-emitting diodes. J. of the Korean Society for Agricultural Machinery 28:151-156 (in Korean).
  • Kim, S.J., E.J. Hahn, J.W. Heo, and K.Y. Paek. 2004b. Effects of LEDs on net photosynthetic rate, growth and leaf stomata of chrysanthemum plantlets in vitro. Scientia Horticulturae 101:143-151.
  • Kim, S.H., Y.H. Heo, H.C. Rhee, and J.S. Kang. 2013. Effect of LED light quality and supplemental time on the growth and flowering of impatiens. J. Bio-Environ. Con. 22:214-219 (in Korean).
  • Kim, S.H. 2013. Effects of LED light quality on growth and flowering of kalanchoe and impatiens. Department of Horticultural Bioscience Graduate School Pusan National University. p. 11.
  • Kim, M.K., S.W. Nam, W.M. Seo, Y.K. Yoon, S.G. Lee, and H.W. Lee. 2002. Biological environment control engineering. Cheongsol press. p. 229 (in Korean).
  • Kim, K.W., M.S. Kang, and D.H. Goo. 1991. External and Histological characteristics of organogenesis from gladiolus callus. J. Kor. Soc. Hort. Sci. 32:124-129 (in Korean).
  • Kim, K.W. and M.S. Byun. 1988. Physiological and morphological characteristics of the glaucous and vitreous carnation plantlets obtained in vitro. J. Kor. Soc. Hort. Sci. 29:216-223 (in Korean).
  • Kim, I.S., C. Zhang, H.M. Kang, and B. Mackay. 2008. Control of stretching of cucumber and tomato plug seedlings using supplemental light. Hort. Environ. Bio. 49:287-292.
  • Kim, H.S., M.K. Lee, and S.E. Yoon. 2014. Strategies and tasks of ICT convergence for the creative agriculture realization. Korea Rural Economic Institute. p. 1-171.
  • Kim, H.S. and Y.H. Kang. 2010. Antioxidant activity of ethanol extracts of non-eEdible parts (stalk, stem,leaf, seed) from Oriental melon. Korean J. Plant Res. 23:451-457 (in Korean).
  • Kim, H.M., J.H. Kang, B.R. Jeong, and S.J. Hwang. 2016. Light quality and photoperiod affect growth of sowthistle(Ixeris dentata Nakai) in a closed-type plant production system. Kor. J. Hortic. Sci. Technol. 34:67-76 (in Korean).
  • Kim, H.H., R.M. Wheeler, J.C. Sager, N.C. Yorio, and G.D. Goins. 2005. Light-emitting diodes as an illumination source for plants: a review of research at Kennedy space center. Habitation 10:71-78.
  • Kim, H.H., G.D. Goins, R.M. Wheeler, and J.C. Sager. 2004a. Green light supplementation for enhanced lettuce growth under red and blue light emitting diodes. Hort. Sci. 39:1617-1622.
  • Kim, H.G. 2014. Chlorophyll fluorescence, graft-take and growth characteristics of cucumber (Cucumis sativus L.) grafted seedlings as affected by light quality and light intensity of LED lamps. Chonbuk National University master degree paper. p. 1-2.
  • KREI. 2016. Agriculture outlook 2017(Ⅱ). p. 459.
  • Johkan, M., K. Shoji, F. Goto, S. Hashida, and T. Yoshihara. 2010. Blue light-emitting diode light irradiation of seedlings improves seedling quality and growth after transplanting in red leaf lettuce. HortScience 45:1809-1814.
  • Jeong, S.W., S.W. Hogewoning, and W. van Ieperen. 2014. Responses of supplemental blue light on flowering and stem extension growth of cut chrysanthemum. Scientia Horticulturae 165:69-74.
  • Jeong, S.W., S.M. Park, J.S. Jin, O.N. Seo, G.S. Kim, Y.H. Kim, H.H. Bae, G.M. Lee, S.T. Kim, W.S. Lee, and S.C. Shin. 2012. Influences of four dfferent light-emitting diode lights on flowering and polyphenol variations in the leaves of chrysanthemum. J. Agri. Food Chem. 600:9793-9800.
  • Jang, Y.A., J.H. Moon, J.W. Lee, S.Y. Kim, and C.H. Chun. 2009. The graft-take and growth of grafted Peppers (Capsicum annuum L.) affected by temperature, relative humidity, and light conditions during healing and acclimatization. J. Bio-Environ. Con. 18:385-392 (in Korean).
  • Jang, Y.A., H.J. Lee, C.S. Choi, Y.C. Um, and S.G. Lee. 2014. Growth characteristics of cucumber scion and pumpkin rootstock under different levels of light intensity and plug cell size under an artificial lighting condition. J. Bio-Environ. Con. 23:383-390 (in Korean).
  • Jang, Y.A., B.H. Mun, T.C. Seo, J.G. Lee, S.S. Oh, and C.H. Chun. 2013. Effects of light quality and intensity on the carbon dioxide exchange rate, growth, and morphogenesis of grafted pepper transplants during healing and acclimatization. Kor. J. Hort. Sci. Technol. 31:14-23.
  • Irradiance and phenotype: comparative eco-development of sun and shade leaves in relation to photosynthetic CO2 diffusion. J. Exp. Bot. 57:343-354.
  • Im, J.N., B.C. Jang, B.H. Song, and T.W. Kim. 2009. Plant nutrition. Korea J. Soil Sci. Fert. 42:153-177 (in Korean).
  • Im, J.M., Y.C. Yoon, K.W. Seo, K.H. Kim, A.K. Moon, and H.T. Kim. 2013. Effect of LED light wavelength on chrysanthemum growth. J. Bio-Environ. Con. 22:49-54 (in Korean).
  • Ikeda, A., S. Nakayama, Y. Kitaya, and K. Yabuki. 1988. Effects of photoperiod, CO2 concentration, and light intensity on growth and net photosynthetic rates of lettuce and turnip. Acta Hort. 229:273-282.
  • Hwang, Y.H., J.E. Park, Y.H. Chang, J.U. An, H.S. Yoon, and K.P, Hong. 2016. Effects of LED(Light Emitting Diode) photoperiod and light intensity on growth and yield of Taraxacum coreanum Nakai in a plant factory. J. Bio-Environ. Con. 25:232-239 (in Korean).
  • Hogewoning, S.W., G. Trouwborst, H. Maljaars, H. Poorter, W. van Ieperen, and J. Harbinson. 2010. Blue light dose-responses of leaf photosynthesis, morphology, and chemical composition of Cucumis sativus grown under different combinations of red and blue light. J. Expt. Bot. 61:3107-3117.
  • Hogewoning, S.W., G. Trouwborst, G.J. Engbers, J. Harbinson, W. van Ieperen, J. Ruijsch, and O. van Kooten. 2007. Plants physiological acclimation to irradiation by light-emitting diodes(LEDs). Acta Hort. 761:183-191.
  • Hoenecke, M.E., R.J. Bula, and T.W. Tibbitts. 1992. Importance of blue photon levels for lettuce seedlings grown under red-light-emitting diodes. HortScience 27:427-430.
  • Hirai, T., W. Amaki, and H. Watanabe. 2006. Action of blue or red monochromatic light on stem internodal growth depends on plant species. Acta Hort. 711:345-350.
  • Hern ndez, R. and C. Kubota. 2014. Growth and morphological response of cucumber seedlings to supplemental red and blue photon flux ratios under varied solar daily light integrals. Scientia Horticulturae 173:92-99.
  • Heo, J.W., Y.B. Lee, D.E. Kim, Y.S. Chang, and C.H. Chun. 2010. Effects of supplementary LED lighting on growth and biochemical parameters in Dieffenbachia amoena ‘Camella’ and Ficus elastica ‘Melany’. Kor. J. Hort. Sci. Technol. 28:51-58.
  • Heo, J.W., C.W. Lee, D. Chakrabarty, and K.Y. Paek. 2002. Growth responses of marigold and salvia bedding plants as affected by monochromic or mixture radiation provided by a Light-Emitting Diode(LED). Plant Growth Regul. 38:225-230.
  • Hahn, E.J., C.H. Bae, and Y.B. Lee. 1998. Growth and leaf-surface characteristics of chrysanthemum plantlets between micropropagation and microponic system. J. Kor. Soc. Hort. Sci. 39:838-842.
  • Givnish, T.J., R.A. Montgomery, and G. Goldstein. 2004. Adaptive radiation of photosynthetic physiology in the Hawaiian lobeliads: light regimes, static light responses, and whole-plant compensation points. American Journal Botany 91:228-246.
  • Fan, X.X., Z.G. Xu, X.Y. Liu, C.M. Tang, L.W. Wang, and X.L. Han. 2013. Effects of light intensity on the growth and leaf development of young tomato plants grown under a combination of red and blue light. Scientia Horticulturae 153:50-55.
  • Evans, J.R. and H. Poorter. 2001. Photosynthetic acclimation of plants to growth irradiance: the relative importance of specific leaf area and nitrogen partitioning in maximizing carbon gain. Plant Cell Environ. 24:755–767.
  • Evans, J.R. 1989. Photosynthesis and nitrogen relationships in leaves of C3 plants. Oecologia. J. 78:9–19.
  • Eun, J.S., Y.S. Kim, and Y.H. Ki. 2000. Effects of light emitting diodes on growth and morphogenesis of in vitro seedlings in Platycodon grandiflorum. Kor. J. Plant Tiss. Cult. 27:71-75.
  • Erwin, J.E. and R.D. Heins, and R. Moe. 1991. Temperature and photoperiod effects on Fuchsia hybrid morphology. J. Amer. Soc. Hort. Sci. 116:955-960.
  • Dorais, M., Yelle, S., Gosselin, A., 1996. Influence of extended photoperiod onphotosynthate partitioning and export in tomato and pepper plants. NewZealand J. Crop Hort. Sci. 24, 29–37.
  • Dorais, M. 2003. The use of supplemental lighting for vegetable crop production: light intensity, crop response, nutrition, crop management, cultural practices. Proc. Can. Greenh. Conference. Ontario. Canada, 9 Octover. p. 1-8.
  • Demers, D.A., and A. Gosselin. 2002. Growing greenhouse tomato and sweet pepperunder supplemental lighting: optimum photoperiod, negative effects of longphotoperiod and their causes. Acta Hort. 580, 83–88.
  • Cooper, C.S. and M. Qualls. 1967. Morphology and chlorophyll content of hade and sun leaves of two lengumes. Crop Sci. 7:672-673.
  • Chung, S.J. 1990. Light environment. J. Bio-Environ. Con. 3:29-37 (in Korean).
  • Choi, Y.H., C.K. Ahn, J.S. Kang, B.G. Son, I.S. Choi, Y.C. Kim, Y.G. Lee, K.K. Kim, and K.W. Son. 2003. Growth, photomorphogenesis, and photosynthesis of perilla grown under red, blue light emitting diodes and light intensities. J. Kor. Soc. Hort. Sci. 44:281-286 (in Korean).
  • Choi, M.K., G.Y. Baek, S.J. Kwon, Y.C. Yoon, and H.T. Kim. 2014. Effect of LED light wavelength on lettuce growth, vitamin C and anthocyanin contents. J. Bio-Environ. Con. 23:19-25 (in Korean).
  • Chi, S.H. 2003. Effect of photopheriod shortening on the nutrient uptake and carbon metabolism of tomato and hot pepper seedlings grown hydroponically. J. Bio-Environ. Con. 12:121-126 (in Korean).
  • Chatterton, N.J. and J.E. Silvius. 1979. Photosynthate partitioning into starch in soybean leaves Ⅰ. Effect of photoperiod versus photosynthetic period duration. Plant Physiol. 64:749-753.
  • Carvalho, R.F., M. Takaki, and R.A. Azevedo. 2011. Plant pigments: The many faces of light perception. Acta Physiol. Plant 33:241-248.
  • Brown, C.S., A.C. Schuerger, and J.C. Sager. 1995. Growth and photomorphogenesis of pepper plants under red light-emitting diodes with supplemental blue or far-red lighting. J. Amer. Soc. Hort. Sci. 120:808-813.
  • Britz, S.J. and J.C. Sager. 1990. Photomorphogenesis and photoassimilation in soybean and sorghum grown under broad spectrum or blue-deficient light sources. Plant Physiol. 94:448-454.
  • Boardman, N.K. 1977. Comparative photosynthesis of sun and shade plants. Ann. Rev. Physiol. 28:355-377.
  • Berkovich, Y.A., I.O. Konovalova, S.O. Smolyanina, A.N. Erokhin, O.V. Avercheva, E.M. Bassarskaya, G.V. Kochetova, T.V. Zhigalova, O.S. Yakovleva, and I.G. Tarakanov. 2017. LED crop illumination inside space greenhouses. Reach-Reviews in Human Space Exploration 6:11-24.
  • Berghage, R.D., J.E. Erwn, and R.D. Heins. 1991. Photoperiod influences leaf chlorophyll content in chrysanthemum grown with a negative DIF temperature regime. HortScience 26:708 (Abst.).
  • Bang, K.S., Y.N. Chang, J.S. Jin, S.A. Park, J.S. Lim, J.S. Park, J.S. Kim and J.H. Lee. 2015. A comparative study of physiological activity and ingredient analysis of Glycyrrhiza uralensis fischer stems and leaves cultivated with different wavelength of LED lights. Korean J. Plant Res. 28:126-134 (in Korean).
  • Azad, O.K., I.J. Chun, J.H. Jeong, S.T. Kwon, and J.M. Hwang. 2011. Response of the growth characteristics and phytochemical contents of pepper (Capsicum annuum L.) seedling with supplemental LED light in glass house. J. Bio-Environ. Con. 20:182-188.
  • Attridge, T.H. 1990. Light and plant responses. Edward Arnold, London.
  • Ali, Md. B., L. Khandaker, and S. Oba. 2009. Comparative study on functional components, antioxidant activity and color parameters of selected colored leafy vegetables as affected by photoperiods. J. Food Agric. Environ. 7:392-398.
  • Abeysinghe, D.C., X. Li, C. Sun, W. Zhang, C. Zhou, and K. Chen. 2007. Bioactive compounds and antioxidant capacities in different edible tissues of citrus fruit of four species. Food Chem. 104:1338-1344.