The Effects of Irrigation with Innovative Compost Tea from Food Waste on Some Tomato Traits
Subject Areas : Farm water management with the aim of improving irrigation management indicatorsNasim Golestanehzadeh 1 , Javad Razmi 2 , Masoud Honarvar 3
1 - MSc, Department of Food Industry Science and Engineering, Science and Research Branch, Islamic Azad University, Tehran, Iran.
2 - Assistant Professor, Department of Plant Protection, Science and Research Branch, Islamic Azad University, Tehran, Iran.
3 - Associate Professor, Department of Food Industry Science and Engineering, Science and Research Branch, Islamic Azad University, Tehran, Iran.
Keywords: Compost Tea, Soil conservation, Food Waste, tomato,
Abstract :
Background and Aim: Food waste is one of the biggest challenges in today’s modern world and leads to greenhouse gas emissions and global warming issues. Converting organic waste into vermicompost and compost tea by efficient biotechnology methods could prevent natural resources depletion and decrease carbon footprint. These soil conditioners promote soil fertility, crop yields, soil resources conservation, and community health.Method: Based on this study, organic waste of the industrial kitchen of the science and research branch university, was converted to vermicompost. The compost tea was produced by a mixture of seaweed, vermicompost, molasses, and humic acid. Greenhouse studies to compare the effect of experimental treatments including irrigation level with compost tea 25, 50, and 100% and chemical fertilizer containing calcium nitrate, potassium sulfate, and 10-52-10 fertilizer on vegetative and biochemical traits of tomato (Karun variety) in six replications were performed.Results: The results showed that irrigation with 100% compost tea and chemical fertilizer, were not significantly different from each other and had the highest effect compared to other treatments. Irrigation with 100% compost tea had the greatest effect on leaf number (66 pieces), plant height (29.8 mm), root length (660 mm), and root fresh weight (29.84 mg). The highest number of flower clusters (8.94 clusters), root diameter (8.94 mm), peroxidase enzyme (3.5 µmol mg-1 protein min-1), chlorophyll a (14.44 mg g-1 FM), and total chlorophyll content (191.91 mg g-1 FM) obtained from 25% compost tea.Conclusion: There was no difference between irrigation with 25 and 100% compost tea, and chemical fertilizers. Furthermore, they had similar effects on most of the studied traits. So, irrigation with compost tea can decrease chemical fertilizers in tomato fields and leads to soil conservation.
References:
Ahmadpour, R., & Bahrami, T. (2016). Influence foliar application of compost tea under water deficit stress of lentil plant by assessment of morphological parameters. Iranian Journal of Plant Physiology and Biochemistry, 1(2), 40-51. Retrieved from http://ijppb.lu.ac.ir/article-1-47-fa.pdf. [in persian]
Alturki, S. M., Shalaby, T. A., Almadini, A. M., & El-Ramady, H. R. (2020). The nutritional status of tomato seedlings and peroxidase activity under foliar applications of some biostimulants. Fresenius Environmental Bulletin, 29(1), 421-433.
Besharati, H., Aliasgharzad, N., Khavazi, K., & AsadiRahmani, H. (2017). A review on soil biology and biological properties of soils in Iran. Journal of Sol Biology, 4(2), 89-122. doi:10.22092/sbj.2017.109306
Cerda, A., Artola, A., Font, X., Barrena, R., Gea, T., & Sánchez, A. (2018). Composting of food wastes: Status and challenges. Bioresource technology, 248, 57-67.
Esmaeili, A., Khoram, M. R., Gholami, M., & Eslami, H. (2020). Pistachio waste management using combined composting-vermicomposting technique: Physico-chemical changes and worm growth analysis. Journal of Cleaner Production, 242, 118523.
FAO. (2019). The state of food and agriculture 2019. Moving forward on food loss and waste reduction. FAO, Rome, 2-13.
Gómez-Brandón, M., Juárez, M. F.-D., Zangerle, M., & Insam, H. (2016). Effects of digestate on soil chemical and microbiological properties: A comparative study with compost and vermicompost. Journal of Hazardous Materials, 302, 267-274.
Gutiérrez-Miceli, F. A., García-Gómez, R. C., Rosales, R. R., Abud-Archila, M., Angela, O. L. M., Cruz, M. J. G., & Dendooven, L. (2008). Formulation of a liquid fertilizer for sorghum (Sorghum bicolor (L.) Moench) using vermicompost leachate. Bioresource technology, 99(14), 6174-6180.
Hadwan, M. H. (2016). New method for assessment of serum catalase activity. Indian Journal of Science and Technology, 9(4), 1-5.
Hakim, A., Khatoon, M., & Gullo, S. (2019). Effect of compost tea and partal root zone drying on tomato productivity and quality. Advances in Horticultural Science, 33(4), 511-519.
Hatti, S., Londonkar, R., Patil, S., Gangawane, A., & Patil, C. (2010). Effect of perionyx excavatus vermiwash on the growth of plants. Journal of crop Science, 1(1), 1.
Ingham, E. (2005). The compost tea brewing manual (Vol. 728): Soil Foodweb Incorporated Corvallis, OR, USA.
Iran National Standards number; 1677, 5615, 6831, 7834, 10716, 13320, 13321-1, 13321-2, 13321-3,13724. Iran National Standards Organization (INSO). [in persian]
Izzati, M., Haryanti, S., & Setiari, N. (2019). The use of Macroalga sargassum sp. and Gracilaria verrucosa in improving Sandy and Clay Soil fertility. Paper presented at the Journal of Physics: Conference Series.
Javaheri, Sh., Abdullahian Noghabi, M., Kashani, A., Habibi, D. Vanoshad, H., 2011, Investigation of the relationship between leaf chlorophyll concentration and sugar beet yield using reluctant chlorophyll, New Agricultural Findings, 4: 365-355. [in persian]
Joe, V., Rock, C., & McLain, J. (2017). Compost tea 101: what every organic gardener should know. In: College of Agriculture, University of Arizona (Tucson, AZ).
Keeling, A., McCallum, K., & Beckwith, C. (2003). Mature green waste compost enhances growth and nitrogen uptake in wheat (Triticum aestivum L.) and oilseed rape (Brassica napus L.) through the action of water-extractable factors. Bioresource technology, 90(2), 127-132.
Khaligh, R., & Shokouhian A. (2019). Effect of vermicompost extract (Compost tea) on growth and yield of strawberry. Journal of Agroecology, Retrieved from https://www.sid.ir/en/journal/ViewPaper.aspx?ID=818682. [in persian]
Khavari-Nejad, S. (2019), A review on plant peroxidases, Nova Biologica Reperta, 5 (4): 428-437. [in persian]
Köksal, E. (2011). Peroxidase from leaves of spinach (Spinacia oleracea): partial purification and some biochemical properties. International Journal of Pharmacology, 7(1), 135-139.
Morales-Corts, M. R., Pérez-Sánchez, R., & Gómez-Sánchez, M. Á. (2018). Efficiency of garden waste compost teas on tomato growth and its suppressiveness against soilborne pathogens. Scientia Agricola, 75, 400-409.
Mousavifar, SS. Sadeghi, SHR. and Bahramifar. N. 2017. Effects of individual and combined application of vermicompost and silica nano particles on soil infiltration. Water and Soil Resources Conservation, Vol. 7, No. 1, Fall 2017. P, 49-61. [in persian]
Pane, C., Palese, A. M., Spaccini, R., Piccolo, A., Celano, G., & Zaccardelli, M. (2016). Enhancing sustainability of a processing tomato cultivation system by using bioactive compost teas. Scientia Horticulturae, 202, 117-124.
Pant, A. P., Radovich, T. J., Hue, N. V., Talcott, S. T., & Krenek, K. A. (2009). Vermicompost extracts influence growth, mineral nutrients, phytonutrients and antioxidant activity in pak choi (Brassica rapa cv. Bonsai, Chinensis group) grown under vermicompost and chemical fertiliser. Journal of the Science of Food and Agriculture, 89(14), 2383-2392.
Parry, C., Blonquist Jr, J. M., & Bugbee, B. (2014). In situ measurement of leaf chlorophyll concentration: analysis of the optical/absolute relationship. Plant, cell & environment, 37(11), 2508-2520.
Pishgar-Komleh, S. H., Akram, A., Keyhani, A., Sefeedpari, P., Shine, P., & Brandao, M. (2020). Integration of life cycle assessment, artificial neural networks, and metaheuristic optimization algorithms for optimization of tomato-based cropping systems in Iran. The International Journal of Life Cycle Assessment, 25(3), 620-632.
Procházková, P., Hanč, A., Dvořák, J., Roubalová, R., Drešlová, M., Částková, T., & Bilej, M. (2018). Contribution of Eisenia andrei earthworms in pathogen reduction during vermicomposting. Environmental Science and Pollution Research, 25(26), 26267-26278.
Radin, A. M., & Warman, P. R. (2011). Effect of municipal solid waste compost and compost tea as fertility amendments on growth and tissue element concentration in container-grown tomato. Communications in soil science and plant analysis, 42(11), 1349-1362.
Razmi, J. 2020. Richness of bacterial microsimbionts around plants in the permaculture agricultural system. Proceedings of the Fifth National Conference on Biodiversity and Its Impact on Agriculture and the Environment, pp. 919-914. [in persian]
Razmi, J. 2013. Semeskandeh abandoned landfill in Sari; Background, status, the possibility of rehabilitation. Hormod Institute for Sustainable Development, 40 pages. [in persian]
Saheb Hasan, M., Selahvarzi, Y., Nabati, J., & Azizi, M. (2020). Effects of drought stress and bio-fertilizers on some growth, photosynthetic pigments, morphophysiological and biochemical traits of Calendula officinalis. Journal of plant process and function, 9(36), Retrieved from https://www.sid.ir/en/journal/ViewPaper.aspx?ID=827199. [in persian]
Shamsaddin saied, M. Ghanbari, A. Ramroudi, M. & Khezri, A. 2017. Effects of Green Manure Management and Fertilization Treatments on the Chemical and Physical Properties and Fertility of Soil. Journal of water and soil science. 21 (1) P. 37-49. [in persian]
Samawat, S., Lakzian, A. & Zamirpour A. R. (2001). The effect of Vermicompost on growth characteristics of tomato. Agricultural science and technology, 15(2), Retrieved from https://www.sid.ir/en/journal/ViewPaper.aspx?ID=26021. [in persian]
Sharma, P., Gaur, V. K., Kim, S., & Pandey, A. (2020). Microbial strategies for bio-transforming food waste into resources. Bioresource technology, 299, 122580.
Sifola, M. I., & Barbieri, G. (2006). Growth, yield and essential oil content of three cultivars of basil grown under different levels of nitrogen in the field. Scientia Horticulturae, 108(4), 408-413.
Stewart-Wade, S. M. (2020). Efficacy of organic amendments used in containerized plant production: Part 1–Compost-based amendments. Scientia Horticulturae, 266, 108856.
Vaughan, D., & Ord, B. (1985). Introduction soil organic Matter—a perspective on its nature, extraction, turnover and role in soil fertility. In Soil organic matter and biological activity (pp. 1-35): Springer.
Villecco, D., Pane, C., Ronga, D., & Zaccardelli, M. (2020). Enhancing sustainability of tomato, pepper and melon nursery production systems by using compost tea spray applications. Agronomy, 10(9), 1336.
Wang, X.-X., Zhao, F., Zhang, G., Zhang, Y., & Yang, L. (2017). Vermicompost improves tomato yield and quality and the biochemical properties of soils with different tomato planting history in a greenhouse study. Frontiers in plant science, 8, 1978.
Williams, L. (1987). Growth of Thompson seedless grapevines. I: Leaf area development and dry weight distribution. Journal of the American Society for Horticultural Science, 112(2), 325-330.
Zaccardelli, M., Pane, C., Villecco, D., Palese, A. M., & Celano, G. (2018). Compost tea spraying increases yield performance of pepper (Capsicum annuum L.) grown in greenhouse under organic farming system. Italian Journal of Agronomy, 13(3), 229-234.
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