Utilization of slurry and mushroom baglog to improve growth and yield on strawberry on degraded volcanic soils

Authors

  • Titin Eka Setianingsih Brawijaya University
  • Retno Suntari
  • Cahyo Prayogo

DOI:

https://doi.org/10.15243/jdmlm.2021.083.2769

Keywords:

contaminant, crop management, nutrient balance, organic manure, soil fertility

Abstract

Utilization of slurry under the combination with mushroom baglog could be used a potential source for replacing nitrogen fertilizer and improve soil fertility. The purpose of this study was to evaluate the different combination and the level of slurry application combining with mushroom baglog on total soil nitrogen and organic contents, total soil bacteria and fungi, along with the improvement of growth and yield of strawberry (Fragaria x ananassa). The experiment used a complete randomized design with five treatments and five replications. The treatments were A1 (100% inorganic fertilizer application as control), A2 (50% composted slurry and mushroom baglog + 50% in-organic fertilizer), A3 (100%  composted slurry and mushroom baglog), A4 (150% composted slurry and mushroom baglog), A5 (50% composted slurry and mushroom baglog + 50% in-organic fertilizer), A6 (100% fresh slurry (uncomposted)), and A7 (150% uncomposted fresh slurry). Results showed that the treatments significantly affected total soil nitrogen, total soil bacteria and fungi, along with the growth and yield of strawberry. The A6 treatment which used 100% uncomposted fresh slurry, showed the highest total nitrogen in the soil (0.23%) and total population of bacteria (7.1 log CFU/g) and the greatest number of strawberry stolons. In term of the number of leaves and total soil fungi, the A3 treatment was the greatest, resulted in number of leaves and total soil fungi at 19.7 per plant and 4.8 log cfu/g x 104. However, the best yield was obtained from the A7 treatment (150% of fresh slurry) at 15.1 kg/ha.

Author Biography

Titin Eka Setianingsih, Brawijaya University

Department Soil dan Water Management, Graduate Programme, Faculty of Agriculture, Brawijaya University, Malang, Indonesia.

References

Abu-Zahra, T.R. and Tahboub, A.A. 2008. Effect of Organic Matter Sources on Chemical Properties of the Soil and Yield of Strawberry under Organic Farming Conditions. World Applied Sciences Journal 5(3): 383-388.

Andriolo, J. L., Erpen, L., Cardoso, F.L., Cocco, C., Casagrande, G.S. and Jänish D.I. 2011. Nitrogen level in the cultivation of strawberries in soilless culture. Horticultura Brasileira 29: 516-519.

Arancon, N.Q., Edwards, C.A,, Bierman, P., Welch, C. and Metzger, J.D. 2004. Influences of vermicompost on field strawberries: effect on growth and yield. Bioresource Technology 93(2): 145-153.

Arfarita, N., Higuchi,T. and Prayogo, C. 2019. Effects of seaweed waste on the viability of three bacterial isolates in biological fertilizer liquid formulations to enhance soil aggregation and fertility. Journal of Degraded and Mining Lands Management 6(4): 1889-1895, doi: 10.15243/jdmlm.2019.064.1889.

Asami, D.K., Hong, Y.J. Barrett, D.M. and Mitchell, A.E. 2003. Comparison of the total phenolic and ascorbic acid content of freeze- dried and air- dried marionberry, strawberry and corn grown using conventional, organic and sustainable agriculture practices. Journal of Agriculture and Food Chemistry 51: 1237- 1241.

Awasthi, M.K., Wang, M., Chen, Q., Wang, J., Zhao, X., Ren, D.S., Li, S.K., Awasthi, F., Shen, R.L. and Zhang, Z. 2017. Heterogeneity of biochar amendment to improve the carbon and nitrogen sequestration through reducing the greenhouse gases emissions during sewage sludge composting. Bioresource Technology 224: 428–438.

Bray, R.H. and Kurtz, L.T. 1945. Determination of Total Organic and Available Phosphorus in Soil. Soil Science. 59: 39-45.

Chhabbra, R., Plrysier, J.L. and Cremers, A. 1975. The Measurement of The Cation Exchange Capacity and Exchangeable Cations in Soil. A New Method. In: S. W. Bailey (ed) Proc Int Clay Conf. Mexico. Applied Publish Wilmette III. 439-449.

Di, Q.L. and Lin, M. 2014. Effect of Biogas Manure on Yield and Quality of Strawberry in Greenhouse. Journal of Henan Agricultural Sciences 43(3):121-123.

Fang, W., Zhang, P., Gou, X., Zhang, H., Wu, Y., Ye, J. and Zeng, G. 2016. Volatile fatty acid production from spent mushroom compost: effect of total solid content. International Biodeterioration and Biodegradation 113:217–221.

Federico, A., Gutierrea, M., Borraz, J.S., Molina, J.A.M., Nafate, C.C., Archila, M.A., Llaven, M.A.O., Rosales, R.R. and Dendooven, L. 2007. Vermicompost as a soil supplement to improve growth, yield and fruit quality of tomato (Lycopersicum esculentum). Bioresource Technology 98:2781-2786.

Feng, H., Qu, G., Ning, P., Xiong, X., Jiae, L., Shif Y. and Zhang J. 2011. The resource utilization of anaerobic fermentation residue. Procedia Environmental Sciences 11: 1092-1099.

Fieldes, M. and Perrott, K.W. 1966. The nature of allophane in soil. Part 3- rapid field and laboratory test for allophane. New Zealand Journal Soil Science 9: 632-629.

Fließbach, A.H., Oberholzer, L., Gunst, P. and Mader, P. 2007. Soil organic matter and biological soil quality indicators after 21 years of organic and conventional farming. Agriculture, Ecosystems and Environment 118: 273–284.

Grandy A.S., Porter G.A. and Erich, M.S. 2002. Organic amendment and rotation crop effects on the recovery of soil organic matter and aggregation in potato cropping systems. Soil Science Society of America Journal 66: 1311–1319.

Gutser, R., Ebertseder, T.H., Weber, A., Schraml, M. and Schmidhalter, U. 2005. Short-term and residual availability of nitrogen after long- term application of organic fertilizers on arable land. Journal of Plant Nutrition and Soil Science 168: 439-446.

Harril, R. 1998. Using a Refractometer to Test the Quality of Fruits and Vegetables. Keedysville. Pineknoll Publishing.

Hart, J., Righetti, T., Sheets, A. and Martin, L.W. 2000. Fertilizer Guide Strawberries. Oregon State University. Pp 14

Hong-yan, Z., Jie, L., Jing-jing, L., Yu-cai, L., Xion-fen, W. and Zong-jun, C. 2013. Microbial community dynamics during biogas slurry and cow manure compost. Journal of Integrative Agriculture 12(6): 1087-1097.

Houba, V.J.G., Vander, L.J.J., Novozamki, I. and Walinga, M. 1998. Soil and Plant Analysis. Part 5: Soil Analysis Procedures. Department of Soil Science and Plant Nutrition. Agricultiural University Wageningen.

Hu, W., Zheng, G., Fang, D., Cui, C., Liang, J. and Zhou, L. 2015. Bioleached sludge composting drastically reducing ammonia volatilization as well as decreasing bulking agent dosage and improving compost quality: a case study. Waste Management 44: 55-62.

Huan-Tao, P. 2008. Comparative test on the applications of biogas manure and compound fertilizer on strawberry. Journal of Anhui Agricultural Sciences 22:1-4.

Khalil, N.H. and Agah, R.J. 2018. Effect of chemical, organic and bio fertilization on growth and yield of strawberry plant. International Journal of Advances in Chemical and Biological Sciences 4 (1): 167-173

Kjeldahl, J.N. 1883. Methode zur bestimmung des stickstoffs in organischen körpern. [New method for the determination of nitrogen in organic substances]. Zeitschrift Für Analytische Chemie. 22: 366-383.

Kumar, N., Singh, H.K. and Mishra, P.K. 2015a. Impact of organic manures and biofertilizers on growth, and quality parameters of strawberry cv. Chandler. Indian Journal of Science and Technology 8(15): 51107, doi: 10.17485/ijst/2015/v8i15/51107.

Kumar, R., Bakshi, P., Singh, M., Singh, A., Vikas, V., Srivatava, J., Kumar, V. and Gupta, V. 2018. Organic production of strawberry. International Journal of Chemical Studies 6(3): 1231-1236.

Kumar, S., Malav, L.C., Malav, M.K. and Khan, S.A. 2015b. Biogas slurry: source of nutrients for eco-friendly agriculture. Journal of Extensive Research 2: 42- 46

LaMondia, J.A., Elmer, W.H., Mervosh, T.L. and Cowles, R.S. 2002. Integrated management of strawberry pests by rotation and intercropping. Crop Protection 21: 837-846.

Leghari, S.J., Wahocho, N.A., Laghari, G.M., Laghari, A.H., Bhabhan, G.M., Talpur, K.H., Bhutto, T.A., Wahocho, S.A. and Lashari, A.A. 2016. Role of nitrogen for plant growth and development: A review. Advances in Environmental Biology 10: 209–218.

Liu, L., Sun, C., Liu, S., Chai, R., Huang, W., Liu, X., Tang, C. and Zhang, Y. 2015. Bioorganic fertilizer enhances soil suppressive capacity against bacterial wilt of tomato. PLoS ONE 10 (4): 1-16.

Meng, L., Li, W., Zhang, S., Wu, C. and Li, L. 2017. Feasibility of co-composting of sewage sludge, spent mushroom substrate and wheat straw. Bioresource Technology 226: 39-45.

Meng, L., S. Zhaq, H. Gong. X. Zhang and C. Wu. 2018b. Improving sewage sludge composting by addition of spent mushroom substrate and sucrose. Journal of Bioresource Technology 253: 197-203.

Meng, X., Dai, J., Zhang, Y., Wang, X., Zhu, W., Yuan, X., Yuan, H. and Cui, Z. 2018a. Composted biogas residue and spent mushroom substrate as a growth. medium for tomato and pepper seedlings. Journal of Environmental Management 216: 62-69.

Ministry of Agriculture. 2019. The Regulation of Ministry of Agriculture on Organic Fertilizer, Biofertilizer, and Soil Amendment No 70. The Republic of Indonesia.

Muramoto, J., Gliessman, S.R., Schmida, D., Stephens, R., Shennan, C. and Swezey, S.T. 2014. Nitrogen Dynamics in an organic strawberry production system. 131-134. https://ucanr.edu/sites/nm/files/76709.pdf .

Nasseri, S., Kalantary, R., Nourich, N., Naddafi, K., Mahvi, A.H. and Baradaran, N. 2010. influence of bioaugmentation in biodegradation of PAHs-contaminated soil in bio-slurry phase reactor. Journal Environment Health and Science 7(3) : 199-208.

Nestby, R., Lieten, F., Pivot, D., Lacroix, C.R. and Tagliavini, M. 2005. Influence of mineral nutrients on strawberry fruit quality and their accumulation in plant organs: a review. International Journal of Fruit Science 5(1):139-158.

Odongo, T., Isutsa, D.K. and Aguyoh, J.N. 2008. Effects of integrated nutrient sources on growth and yield of strawberry grown under tropical high altitude conditions. African Journal Horticultural Science 1: 53-69.

Onwosi, C.O., Igbokwe, V.C., Odimba, J.N., Eke, I.E., Nwankwoala, M.O., Iroh, I.N, and Ezeogu, L.I. 2017. Composting technology in waste stabilization: on the methods, challenges and future prospects. Journal Environmental Management 190: 140-157.

Pochon, J., Tardieux, P. and D’Aguilar, J. 1969. Natural Resources Research: Soil Biology. United National Education, Scientific and Cultural Organization. Belgium.

Prayogo, C. and Ihsan M. 2018. Utilization of LCC (legume cover crop) and bokashi fertilizer for the efficiency of Fe and Mn uptake of former coal mine land. Journal of Degraded and Mining Lands Management 6(1): 1527-1537, doi: 10.15243/jdmlm.2018.061.1527.

Prayogo, C., Prastyaji, D., Prasetya, B. and Arfarita, N. 2021. Structure and composition of arbuscular mycorrhizal fungi under different farmer management of coffee and pine agroforestry system. AGRIVITA Journal of Agricultural Science 43(1): 146-163.

Rashid, M.H.A. 2018. Optimization of growth yield and quality of strawberry cultivars through organic farming. Journal Environmental Science and Natural Resources 11(1&2):121-129

Reganold, J.P., Andrews, P.K., Reeve, J.R., Carpenter- Boggs, L. and Schadt, C.W. 2010. Fruit and soil quality of organic and conventional strawberry agroecosystems. Public Library of Science One (PLoS ONE) 5(9): e12346.

Robertson, G.P and Vitousek, P.M. 2009. Nitrogen in agriculture: balancing the cost of an essential resource. The Annual Review of Environment and Resources 34: 97–125.

Sánchez, O.J., Ospina, D.A. and Montoya, S. 2017. Compost supplementation with nutrients and microorganisms in composting process. Journal Waste Management 69: 136-153.

Sharma, R.R. 2002. Growing Strawberries. International Book Distributing Co. Chaman Studio Building, 2nd Floor, Charbagh, Lucknow 226004 U.P. (India). p. 164

Sihaloho, A.N and Meriaty, M. 2019. Interaction the doses of fertilizer organic baglog mushroom and potassium to the growth and result of sweet corn (Zea mays L. Saccharata). International Journal of Agronomy and Agricultural Research 14(6): 1-7.

Tagliavini, M., Baldi, E., Lucchi, P., Antonelli, M., Sorrenti, G., Baruzzi, G. and Faedi, W. 2005. Dynamics of nutrients uptake by strawberry plants (Fragaria x AAnanassa Dutch.) grown in soil and soilless culture. European Journal of Agronomy 23: 15-25.

USDA. 1982. Soil Conservation Service. Soil Survey Laboratory Methods and Procedures for Collecting Soil Samples. Soil Survey Investigations Report no 1 U. S. Dept Agri, Washinton, D. C.

Wentzel, S. and Joergensen, R.G. 2016. Quantitative microbial indices in biogas and raw cattle slurries. Engineering in Life Sciences 16(3): 231-237.

Yavari, S., Eshghi, S., Tafazoli, E. and Karimian, N. 2009. Mineral elements uptake and growth of strawberry as influenced by organic substrates. Journal of Plant Nutrition 32:1498-1512.

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Submitted

22-01-2021

Accepted

09-03-2021

Published

01-04-2021

How to Cite

Setianingsih, T. E., Suntari, R., & Prayogo, C. (2021). Utilization of slurry and mushroom baglog to improve growth and yield on strawberry on degraded volcanic soils. Journal of Degraded and Mining Lands Management, 8(3), 2769–2777. https://doi.org/10.15243/jdmlm.2021.083.2769

Issue

Vol. 8 No. 3 (2021)

Section

Research Article

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