تعیین کارایی کود سیلیسیم و تربیت بوته بر عملکرد بادمجان (Solanum melongena) گلخانه‌ای رقم ’دنیس‘ و ماندگاری پس از برداشت میوه

نوع مقاله : مقالات پژوهشی

نویسندگان

1 دانشجوی کارشناسی ارشد علوم باغبانی، دانشگاه آزاد اسلامی واحد جیرفت

2 استادیار بخش تحقیقات علوم زراعی و باغی، مرکز تحقیقات و آموزش کشاورزی و منابع طبیعی جنوب کرمان، سازمان تحقیقات، آموزش و ترویج

چکیده

سیلیسیم عنصری ضروری برای رشد گیاه نیست اما نقش آن در بهبود عملکرد به‌واسطه کاهش تنش‌های محیطی و ماندگاری محصول بسیار حائز اهمیت است. از سویی در تولید سبزیجات گلخانه‌ای، سودآوری وابسته به عملکرد بـالا و میزان کیفیت در واحد سطح می‌باشـد کـه می‌تواند بـا مـدیریت صحیح هرس ساقه افـزایش یابد. لذا به‌منظور بررسی اثر محلول‌پاشی کود سیلیسیم از منبع کلات سیلیسیم در مراحل مختلف رشد گیاه و تربیت بوته در گیاه بادمجان، آزمایشی گلخانه‌ای در محیط خاکی به‌صورت کرت­های خرد شده در قالب طرح بلوک کامل تصادفی در 3 تکرار در منطقه میناب اجرا شد. در این آزمایش، مصرف کود سیلیسیم به‌عنوان فاکتور اصلی در 4 سطح (صفر و 2 در هزار در فاز رویشی، 2 در هزار در فاز زایشی و 2 در هزار در دو فاز رویشی و زایشی) و نوع هرس به‌عنوان فاکتور فرعی نیز در 4 سطح (بدون هرس، هرس دوشاخه، هرس سه‌شاخه و هرس چهارشاخه) اعمال شد. نتایج نشان داد که شیوه تربیت بوته با تاثیر مثبت بر طول میوه، ارتفاع بوته، وزن میوه منجر به افزایش متوسط عملکرد بوته از 720 گرم به 1300 گرم در هر چین شد. همچنین محلول‌پاشی سیلیسیم از طریق افزایش غلظت سیلیسیم موجود در گیاه و تأثیر مثبت بر تعداد میوه در بوته سبب افزایش 64 درصدی عملکرد بوته نسبت به عدم محلول­پاشی سیلیسم شد. درصد افت وزن میوه نیز از 10 درصد در شرایط بدون دریافت سیلیسیم به 1 درصد کاهش معنی‌داری یافت. اثر متقابل محلول­پاشی با سیلیسیم در دو مرحله رویشی و زایشی و تربیت بوته به­صورت چهار شاخه کاهش درصد آلودگی قارچی را به‌دنبال داشت. لذا مصرف سیلیسیم در دو مرحله رویشی و زایشی به‌ویژه در گلخانه‌های سنتی فاقد سیستم‌های تهویه مناسب همراه با هرس چهار شاخه قابل توصیه است.

کلیدواژه‌ها

موضوعات

عنوان مقاله [English]

Determining the Efficiency of Silicon Fertilizer and Branch Pruning on Greenhouse Eggplant Yield and Post-harvest Shelf Life

نویسندگان [English]

  • H. Zakeri 1
  • Z. Roudbari 2
1 MS.c student of horticultural sciences, Islamic Azad University, Jiroft Branch.
2 Assist. Prof. of Plant Breeding, Dep. of Crop and Horticultural Science Research, Southern Kerman Agricultural and Natural Resources Research and Education Center, AREEO, Jiroft, Iran.
چکیده [English]

Introduction
    Silicon (Si) is not an essential element for the growth of plants, but its role in improving the yield by reducing the environmental stresses and crop durability is very important. Despite the abundance of Si in the soil, the amount of dissolved Si available for herbal absorption might be limited. Therefore, using this useful element through foliar application can be effective in the growth of the plants such as eggplant. On the other hand, profitability is dependent on the high yield and quality per unit area in producing greenhouse vegetables.
Materials and Methods
    To study the effect of foliar application of Si fertilizer from the source of Khazra Chelated Silicon (commercial brand, contains 2% chelated silicon for plant at pH 3 to 11 and no silicate in the form of salt) in different stages of the growth of eggplant and bush pruning in hybrid eggplant, a greenhouse experiment was conducted in a soil environment as a split-plot in a randomized complete block design with 3 replications in Minab region. In this experiment, the consumption of Si fertilizer as the main factor at 4 levels (0 and 2 per thousand in the vegetative phase, 2 per thousand in the reproductive phase and 2 per thousand at the two vegetative and reproductive phases) and the type of pruning as a sub-factor in 4 levels (two-branch training system, three-branch training system, four-branch training system and no training system) were applied. Eggplant seeds were transplanted in an environment containing sphagnum in November and then at four-leaf stage they were transferred to the main field in December. The distance between the rows was one meter and the distance between the plants in the row was 45 cm. After positioning the plant in the greenhouse and reaching the appropriate growth, pruning and foliar application of Si fertilizer began and in the treatment without fertilizer, spraying with pure water was used. Silicon fertilizer was sprayed on the eggplant leaves according to the instructions recommended by the manufacturer every eight days.  Once the eggplants reached a suitable reproductive growth and started fruiting, fruit thickness, fruit length, the weight of each fruit, the number of the fruits on each plant, and finally the yield of each plant were recorded in each pick. To evaluate the effect of Si on the durability of eggplant after picking, 3 fruits harvested from each treatment were first weighed by a digital scale, and then kept at room temperature for 2 weeks and after two weeks, the weight of each fruit was measured again. Based on two recorded weights, the percentage of fruit weight loss was calculated. Furthermore, to evaluate the effect of silicon fertilizer and plant pruning on resistance to fungal diseases, scores, from 1 to 9, were given to the plants in each treatment. Plants without any fungal infection were assigned a score of 1, and completely infected plants were assigned a score of 9.
Results and Discussion
    The results showed that pruning improved the fruit length, the plant height, the fruit weight in each plant, and the plant yield and reduced the percentage of fungal infection in the plant. Moreover, the silicon foliar application positively affected the number of the fruits in each plant and increased the durability of fruits after harvesting. Silicon foliar application in the two vegetative and reproductive stages together and plant pruning in a four-branch way resulted in maximum plant yield, improved crop quality, and improved greenhouse management. The intensity of fungal infection was affected by different levels of silicon, plant pruning, and the interaction of the two factors at a probability level of five percent. Comparison of interaction averages showed that pruning and foliar application in vegetative and reproductive stages together significantly reduced fungal infection in the greenhouse. The highest intensity of fungal infection was related to plants without pruning and lack of silicon. Pruning improves airflow and modulates humidity in the plant canopy and as a result eliminates the proper conditions for fungal growth. Silicon also prevents fungal penetration into plant cells by depositing in the plant cell wall and strengthening plant tissue, and as a result inhibits fungal growth in the plant. Marschner (2012) reported that silicon would increase resistance to fungal and bacterial diseases and pests. Plant diseases are a major threat to agricultural production because they cause a serious loss of yield and quality of the crop. Numerous studies have reported that Si is effective in controlling diseases caused by fungal and bacterial pathogens in various plant species. Furthermore, given that one of the challenges for producers to deliver high-quality crops to the target market is their durability after harvesting, it seems that silicon foliar application at the two vegetative and reproductive stages might be effective to overcome such a challenge. Choosing a training system depends to a large extent on the ease of work in the greenhouse, the production system, and the superiority of the production rate. On the other hand, a significant increase in yield and crop quality was reported for barley, rice, sugarcane, tomato, cucumber, soybean, and bamboo due to Si consumption during the growth. Another important feature of silicon is that it increases plant damage under biological and non-biological stress conditions as well as resistance against stress.
Conclusion
    According to the results, four-branch training system of eggplant and also silicon foliar application in the two vegetative and reproductive phases of greenhouse eggplant improved the yield components and increased the durability after harvesting. Pruning the plant into four branches also improved yields. Therefore, using silicon with four-branch training system is recommended, especially in traditional greenhouses without proper ventilation systems. 

کلیدواژه‌ها [English]

  • Branch pruning
  • Greenhouse vegetables
  • Post-harvest shelf life
  • Useful elements

مراجع

  1. Abou-Baker, N., & Abbas, M. (2011). Use of silicate and different cultivation practices in alleviating salt stress effect on bean plants. Australian Journal of Basic and Applied Sciences 5(9): 769-78.
  2. Alsadon, A., Wahb-Allah, M., Abdei-Razzak, H., & Ibrahim, A. (2013). Effects of pruning systems on growth, fruit yield and quality traits of three greenhouse-grown bell pepper (Capsicum annuum) cultivars. Australian Journal of Crop Science 7(9): 1309-1316.
  3. Alam, A., Hariyanto, B., Ullah, H., Salin, K., & Datta, A. (2021). Effects of silicon on growth, yield and fruit quality of cantaloupe under drought stress. Silicon 13: 3153–3162. https://doi.org/1007/s12633-020-00673-1.
  4. Ambroszczyk, A.M., Cubula, S., & Sekara, A. (2007). The effect of plant pruning on yield and fruit quality of eggplant (Solanum melongena) in greenhouse cultivation. Horticulture, Environment, and Biotechnology 48(5): 277-285. https://doi.org/10.2478/fhort-2013-0109.
  5. Ambroszczyk, A.M., Cubula, S., & Sekara, A. (2008). The effect of shoot training on yield, fruit quality and leaf chemical composition of eggplant in greenhouse cultivation. Folia Horticulturae20(2): 3-15. https://doi.org/2478/fhort-2013-0109.
  6. Anonymous. (2019). Statistics of agricultural products. Volume 3. Publications of the Ministry of Jihad Agriculture. (In Persian)
  7. Ara, A., Bashar, M.K., Begum, S., & Kakon, S.S. (2007). Effect of spacing and stem pruning on the growth and yield of tomato. International Journal Sustainability Crop Production 2(3): 35-39.
  8. Arab Salmani, K., Jalali, A.H., & Jafari, P. (2021). Study of the effect of plant pruning on eggplant yield (Solanumm elongena, Bellen cultivar) in greenhouse conditions. Journal of Horticultural Science Online population. (In Persian with English abstract)
  9. Babini, E., Marconi, S., Cozzolino, S., Ritota, M., Taglienti, A., Sequi, P., & Valentini, M. (2012). Bio-available silicon fertilization effects on strawberry shelf-life. In XXVIII International Horticultural Congress on Science and Horticulture for People (IHC2010) 934: 815-818. https://doi.org/17660/ActaHortic.2012.934.107.
  10. Buczkowska, H. (2010). Effect of plant pruning and topping on yielding of eggplant in unheated foil tunnel. ActaScientiarum Polonorum Hortorum Cultus 9(3): 105-115.
  11. Chandima, T.M., Weerakkody, W.A.P., Weerasinghe, K.W.L.K., & Wahundeniya, K.B. (2006). Growth and yield performances of salad (green) cucumber (Cucumis sativus). Idaho Center for Sustainable Agriculture 18 p.
  12. Chapman, H.D., & Pratt, P.F. (1961). Methods of analysis for soils, plants and water. University California, Berkeley, CA, USA.
  13. Crucicol, C.A.C., Pulz, A.L., Lemos, L.B., Soratto, R.P., & Lima, G.P.P. (2009). Effects of silicon and drought stress on tuber yield and leaf biochemical characteristics in potato. Crop Physiology and Metabolism 49: 949-954. https://doi.org/2135/cropsci2008.04.0233.
  14. Dasgan, H.Y., Akhoundnejad, Y., & Caglayangil, H. (2016). Selenium and silicon fertilization in soilless grown eggplant. International Journal of Agriculture Innovations and Research 5(3): 417-421.
  15. Dias, J.S. (2012). Nutritional quality and health benefits of vegetables: A review. Food and Nutrition Sciences 3: 1354-1374. https://doi.org/4236/fns.2012.310179.
  16. Ghasemi, K., Ghajar Sepanlou, M., & Haddadinejad, M. (2019). Effect of silicon on nutrient concentration, photosynthetic pigments and fruit quality of strawberry cv. Camarosa. Horticultural Plants Nutrition 2(1): 85-98. (In Persian with English abstract)
  17. Hartley, A., Mclachlan, H., Hetherington, A., & Franklin, K. (2012). High temperature exposure increases plant cooling capacity. Current Biology 22(10): 396-397. https://doi.org/1016/j.cub.2012.03.044.
  18. Hu, S., Ding, Y., & Zhu, C. (2020). Sensitivity and Responses of Chloroplasts to Heat Stress in Plants. Frontiers in Plant Science 11: 375. https://doi.org/3389/fpls.2020.00375.
  19. Islam, M.Z., Mele, M.A., & Choi, K.Y. (2018). The effect of silicon and boron foliar application on the quality and shelf life of cherry tomatoes. Zemdirbyste 105: 159–164.
  20. Jovicich, E., Cantliffe, D.J., & Hochmuth, G.J. (1998). Plant density and shoot pruning on fruit yield and quality of a summer greenhouse sweet pepper crop in Northcentral Florida. Horticultural Science 28: 184-190.
  21. Marschner, P. (2012). Marschner’s mineral nutrition of higher plants. London: Academic Press.
  22. Mitani, N., Yamaji, N., Ago, Y., Iwasaki, K., & Ma, J.F. (2011). Isolation and functional characterization of an influx silicon transporter in two pumpkins cultivars contrasting in silicon accumulation. Plant Journal 66: 231– https://doi.org/10.1111/j.1365-313X.2011.04483.x.
  23. Mohaghegh, P.F., Shravani, M., & Ghasemi, S. (2010). The effect of silicon application on growth and yield of two cucumber cultivars in hydroponic system. Journal of Science and Technology of Greenhouse Culture 1(1): 39-35. (In Persian)
  24. Rodrigues, F.A., & Datnof, L.E.(2015). Silicon and plant diseases. Berlin: Springer. https://doi.org/1007/978-3-319-22930-0.
  25. Roudbari, Z., & Khoshkam, S. (2020). Pruning of plants in greenhouse vegetables. Scientific Journal of Greenhouse Vegetable Extension 3(1): 19-11. (In Persian)
  26. Savvas, D., Giotis, D., Chatzieustratiou, E., Bakea, M., & Patakioutas, G. (2009). Silicon supply in soilless cultivations of zucchini alleviates stress induced by salinity and powdery mildew infections. Environmental and Experimental Botany 65: 11–17. https://doi.org/1016/j.envexpbot.2008.07.004.
  27. Seifi, S., Nemati, S.H., Shoor, M., & Abedi, B. (2011). Effect of plant density and shoot pruning on fruit quality characteristics of two cultivars of sweet pepper. Journal of Horticultural Science 25(2): 194-200. (In Persian with English abstract)
  28. Shirahmadi, S., Barzegar, X., & Ghahremani, Z. (2016). The effect of different plant breeding systems on growth, yield and quality of greenhouse cucumber of Gohar cultivar. Journal of Science and Technology of Greenhouse Culture 7(28): 24-13. (In Persian with English abstract)
  29. Thakur, O., Kumar, V., & Singh, J. (2018). Review on advances in pruning to vegetable crops. International Journal of Current Microbiology and Applied Sciences 7(2): 3556-5365. https://doi.org/20546/ijcmas.2018.702.422.
  30. Toresano-Sanchez, F., Valverde, A., & Camacho-Ferre, F. (2012). Effect of the application of silicon hydroxide on yield and quality of cherry tomato. Journal of Plant Nutrition 35(4): 567-590. https://doi.org/1080/01904167.2012.644375.
  31. Wu, J.W., Shi, Y., Zhu, Y.X., Wang, Y.C., & Gong, H.J. (2013). Mechanisms of enhanced heavy metal tolerance in plants by silicon: a review. Pedosphere 23: 815–825. https://doi.org/1016/S1002-0160(13)60073-9.

 

 

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  • تاریخ دریافت: 23 شهریور 1400
  • تاریخ بازنگری: 19 آذر 1400
  • تاریخ پذیرش: 20 آذر 1400
  • تاریخ اولین انتشار: 20 آذر 1400

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