Journal of Bio-Environment Control (생물환경조절학회지)

The Korean Society for Bio-Environment Control (한국생물환경조절학회)
권호 표지

Development of Optimal Nutrient Solution of Tomato(Lycopercicon esculentum Mill.) in a Closed Soilless Culture System

순환식 수경재배에 적합한 토마토 배양액 개발

  • Yu, Sung-Oh (Division of Plant and Resource Science, Wonkwang Univ.) ;
  • Bae, Jong-Hyang (Division of Plant and Resource Science, Wonkwang Univ.)
  • 유성오 (원광대학교 식물자원과학부(생명자원과학연구소)) ;
  • 배종향 (원광대학교 식물자원과학부(생명자원과학연구소))
  • Published : 2005.09.01
Download PDF
⟨ Previous Next ⟩

Abstract

The experiment was conducted to investigate the nutrition absorption pattern in the growth stages and develope the optimal nutrient solution hydroponically grown the tomato in closed substrate culture system with the nutrient solution of National Horticultural Research Station in Japan into 1/2S, 1 S, and 2S. When plant was grown in 1/2 S, the growth and yield were high and the pH and EC in the rooting zone were stable. Suitable composition of nutrient solution for tomato was $NO_3-N$ 7.1, $PO_{4}$-P 2.1, K 4.0, Ca 3.1, Mg 1.2, and $SO_{4}-S\;1.2\;me{\cdot}L^{-1}$ in the early growth stage and $NO_3-N$ 6.5, $PO_4-P$ 2.3, K 3.4, Ca 3.1, Mg 1.1, and $SO_4-S\;1.1\;me{\cdot}L^{-1}$ in the late growth stage by calculating a rate of nutrient and water uptake. To estimate the suitability for the nutrient solution of tomato in a development of optimum nutrient solution of tomato developed by Wonkwang university in korea (WU), plant was grown in perlite substrate supplied with different solution and strengths(S) by research station for greenhouse vegetable and floricultuin in the Netherlands (Proefstation voor tuinbouw onder glas te Naaldwijk; PTG) of 1/2 S, 1 S and 2 S, respectively, The growth was good at the PTG and WU of 2 S in early growth stage, and at the WU 2S in late growth stage. The highest yield of tomato obtained in the WU of 2 S, although blossom-end rot was appeared in all treatments. pH and EC in root zone of WU of 2 S were stable during the early and late growth stage. Therefore when plant was grown in WU of 2 S, N and P content in the nutrient solution need to low, according N and P content of their leaves were high in WU of 2 S.

토마토 순환식 고형배지경 시스템에서 생육단계별 작물의 양분 흡수율을 밝히고 최적 배양액을 개발하고자 일본야채시험장 표준액($NO_3-N$ 16.0, $NH_4-N$ 1.3, $PO_4-P$ 4.0, K 8.0, Ca 8.0, Hg 4.0 $me{\cdot}L^{-1}$)을 1/2, 1 및 2배액의 3수준 농도로 조성하여 실험을 수행하였다. 생육초기와 후기 모두 1/2배액 처리에서 생육이 양호하고, 근권 내 pH와 EC의 변화도 적었으며, 식물체내 무기이온 함량도 적정치로 나타났다. 따라서 생육단계별 양${\cdot}$수분 흡수(n/w)율에 의해 개발된 토마토 순환식 배양액 조성은 생육초기에는 $NO_3-N,\;PO_4-p$, K, Ca, Mg 및 $SO_4-S$ 농도가 각각 7.1, 2.1, 4.0, 3.1, 1.2 및 1.2 $me{\cdot}L^{-1}$, 생육후기에는 각각 6.5, 2.3, 3.4, 3.1, 1.1 및 1.1 $me{\cdot}^L^{-1}$로 나타났다. 개발된 배양액의 적합성 검정을 위하여 네델란드 온실작물연구소의 순환식 PTG(Proefstation voor tuinbouw onder glas te Naaldwijk) 배양액으로 비교 실험을 하였다 초기 생육은 PTG와 WU 배양액의 2배액 처리에서, 후기 생육은 WU 2배액 처리에서 가장 좋았다. 정식 후 72일째까지의 수량은 WU 2배액 처리에서 가장 높았으며, 배꼽썩음과는 PTG와 WU 배양액의 모든 농도에서 나타났다. WU 2배액의 EC와 pH변화는 재배되는 동안 안정적이었다. 생육이 높았던 WU 2배액의 식물체내 무기성분 함량 N과 P 함량이 높음에 따라 배양액 조성시 N, P 함량을 낮추어 공급하는 것이 바람직한 것으로 판단된다.

Keywords

References

  1. Adams, P. and L.C. Ho. 1995. Uptake and distribution of nutrients in relation to tomato fruit quality. Acta Hort. 412:374-387
  2. Adams, P. and G.W. Winsor. 1973. The effects of nitrogen, potassium and sub-irrigation on the yield, quality and composition of single-truss tomatoes. J. Hort. Sci. 48:123-133
  3. Bartosik, M.L., K. Salonene, R. Jokinen, and K.R. Hukknen. 1993. Comparison of open and closed growing methods on peat and rockwool and the leaching of nutrients. Acta Hort. 342:303-305
  4. Bohme, M. 1995. Effects of closed systems in substrate culture for vegetable production in greenhouses. Acta Hort. 396:45-54
  5. Choi, E.Y., Y.B. Lee, and J.Y. Kim. 1998. Development of optimal nutrient solution for tomato substrate culture in closed system. J. Bio. Fac. Env. 7(1):43-54
  6. Choi, E.Y., Y.B. Lee, and J.Y. Kim. 2001. Nutrient uptake, growth and yield of cucumber cultivated with different growing substrates under a closed and an open system. Acta Hort. 548:543-549
  7. De Kreij, C. 1990. Norman Voor Gehalten Ann Voedingselenmenten Van Groenten En Bloemen Onder Glas(Guide values for nutrient element contents of vegetables and flower under glass). Voeding Soplossingen Glastuinbouw No. 15. p. 13. Crops. Agr. and Hort. 61 :205-210
  8. Gericke, W.E 1929. Aquaculturem a means of crop production. Amer. J. Bor. 16:826
  9. Ikeda, A. 1986. Control of nutrient solution by nutrient absorption characteristic of Jensen, M.H. 1997. Hydroponics. HortScience 32(6): 1018-1021
  10. Jones, Jr., J. Benton, B. Wolf, and H. mills. 1991. The essential elements. Plant analysis handbook. p. 6-17. Micro-Macro pullishing. Onc., Georgia
  11. 板東一宏. 1991.トマトの循環式ロックウル栽培(1). 農業および園藝 66(6):731-735
  12. Kim, H.J. 2001. Modeling nustrient uptake of tomato (Lycopersicon esculentum Mill.) and cucumber (Cucumis sativus L.) for closed substrate culture system. PhD Diss., The Chungbuk National University
  13. Kim, Y.C. 1998. Development of Korean type nutrient solution, medium and automatic control system in horticultural crops. Rural Development Administration
  14. Kim, Y.C. and G. Y. Kim. 2002. Fertigation techniques done by fertilizers for hydroponics and reuse of waste solution. Kor. Res. Soc. Protected Hort. 15:20-26
  15. 日本施設園藝協會. 1991.施設園藝における養液栽培の 手引. p.34-37.日本施設園藝協會
  16. Ohta, K. 1991. Influence of the concentrations of nutrient solution and salt supplement on quality and yield of cherry tomato grown hydroponically. J. Japan Soc. Hort. Sci. 60(1):89-95 https://doi.org/10.2503/jjshs.60.89
  17. Roh, M.Y, Y.B. Lee, H.S. Kim, K.B. Lee, and J.H. Bae. 1997. Development of nutrient solution suitable for closed system in substrate culture of cucumber. J. Bio-Env. Con. 6(1):1-14
  18. Rural Development Administration. 2003. Statistical data of soilless culture area in Korea. RDA
  19. Schwarz, M. 1995. Soilless culture management. p.98-102. In B.L. McNeal, F. Tardieu, H. Van Keulen, and D. Van Velck(ed.). 1st ed. Springer-Verlag, Berlin, Heidelberg, New York. Sonneveld, C. 1993. Hydroponic growing in closed systems to safeguard the environment. Australia Hydroponic Conference - Hydroponics and the Environment. Monash Univ. Melbourne Australia, p.21-36
  20. Sonneveld, C. 1993. Hydroponic growing in closed systems to safeguard the environment. Australia Hydroponic Conference Hydroponics and The Environment. Monash University Melbourne Australia 1719, February. p. 21-36
  21. Yamasaki, K. 1981. The problem and present state of hydroponic culture (I). Nutrient solution management of hydroponic culture-nutritive characteristic of each crop by nutrient/water. Agr. and Hort. 56(4):563-568
  22. Zekki, H., L. Gauthier, and A. Gosselin. 1996. Growth, productivity and mineral composition of hydroponically cultivated greenhouse tomatoes with or without nutrient solution recycling. J. Amer. Soc. Hort. Sci. 121 (6): 1082-1088