Loading...

Research on Crops

Effect of pineapple skin Bokashi on improvement of soil properties and growth of shallot (Allium ascalonicum L.)


DOI: 10.31830/2348-7542.2023.ROC-11161    | Article Id: ROC-11161 | Page : 319-325
Citation :- Effect of pineapple skin Bokashi on improvement of soil properties and growth of shallot (Allium ascalonicum L.). Res. Crop. 24: 319-325
AGUSALIM MASULILI, AGUS SUYANTO, SETIAWAN, MULYADI AND PAIMAN agusalim@upb.ac.id
Address : Department of Agrotechnology, Faculty of Agriculture, Panca Bhakti University, Pontianak 78113, West Kalimantan, Indonesia
Online Published:

Abstract

Shallot (Allium ascalonicum L.) is one of the horticultural crops that has high economic value, along with the increase in demand for this commodity. Alluvial is a type of soil with the potential for agricultural development, among others, and can be used to cultivate shallots. However, this soil has physical and chemical constraints that can inhibit plant growth, so it requires soil amendment treatment to improve it. This study aimed at determining the effect of a combination of cow dung compost and pineapple skin bokashi on the improvement of alluvial soil properties and the growth of shallot plants. The research used polybags and was carried out in the laboratory and greenhouse of the Faculty of Agriculture, Panca Bhakti University, Pontianak, West Kalimantan, Indonesia, lasting 60 days from February-April 2022. The study used a completely randomized design (CRD) with three replications. Each polybag was filled with 8 kg of soil and added the cow dung compost of 80 g. Then, the treatment of bokashi pineapple skin consisted of eight levels: 10, 20, 30, 40, 50, 60, 70 and 80 g/polybag. Each replication consisted of three plant samples so that the plant numbers were 72 units. The research results showed that the use of organic amendments of pineapple skin bokashi affected improving alluvial soil properties, which could reduce BD and increase soil pores, pH, organic C, P available and N total of soil. Furthermore, there was an increase in the growth of shallot plants as a result of the treatment given. The research findings showed that the best growth of shallots was achieved at the dose of 60 g/polybag pineapple skin bokashi. Furthermore, it can be recommended that further research be carried out on the effect of the combination of cow dung. compost and other organic and inorganic amendments.

Keywords

Alluvial bulk density nitrogen phosphate pineapple skin shallot

References

Adeleke, R., Nwangburuka, C. and Oboirien, B. (2017). Origins, roles and fate of organic acids in soils: A review. South African J. Bot. 108: 393-06.
Alasa, J. J., Bashir, A. U., Mustapha, M. and Muhammed, B. (2021). Experimental study on the use of banana and pineapple peel waste as biofertilizers, tested on Hibiscus sabdariffa plant: Promoting sustainable agriculture and environmental sanitation. Arid Zone J. Eng. Technol. Environ. 17: 211-20.
Alwaneen, W. S. (2020). Effect of cow manure compost on chemical and microbiological soil properties in Saudi Arabia. Pak. J. Biol. Sci. 23: 940-45.
Amandeep, Singh, G., Ram, M. and Batham, P. (2021). Effects of indigenous plant extracts with cow urine on incidence of stem borer, Scirpophaga incertulas (Walker) in paddy (Oryza sativa L.). Crop Res. 56: 341-45.
Anwar, Z., Irshad, M., Mahmood, Q., Hafeez, F. and Bilal, M. (2017). Nutrient uptake and growth of spinach as affected by cow manure co-composted with poplar leaf litter. Int. J. Recycl. Org. Waste Agric. 6: 79-88.
Ayu, A. S., Reny, S., Ida, M., Jaka, S., Laela, R. U. I, Dinar, Yayan, S., Yadi I. A, Umar, D. and Suhaeni (2021). Prediction model of production patterns of shallot development in the highlands of Indonesia. Res. Crop. 22: 895-900.
Blake, G. R. and Hartge, K. H. (1986). Bulk density. In Methods of soil analysis, Part 1: Physical and mineralogical methods; Klute, A. (ed.); Soil Science Society of America: Madison, Wisconsin. Pp. 363-75.
Boettinger, J. L. (2004). Alluvium and alluvial soils. Encyclopedia of Soils in the Environment 4: 45-49.
Bremner, J. M. and Mulvaney, C. S. (1982). Nitrogen-total. In: Methods of soil analysis. Part 2. Chemical and microbiological properties, Page, A. L., Miller, R. H. and Keeney, D. R. Eds., American Society of Agronomy, Soil Science Society of America, Madison, Wisconsin. Pp. 595-24.
Cahyono, P., Loekito, S., Wiharso, D., Afandi, Rahmat, A., Nishimura, N. and Senge, M. (2020). Effects of compost on soil properties and yield of pineapple (Ananas comusus L. Merr.) on red acid soil, Lampung, Indonesia. Int. J. Geomate 19: 33-39.
Cincotta, M. M., Perdrial, J. N., Shavitz, A., Libenson, A., Landsman-Gerjoi, M., Perdrial, N., Armfield, J., Adler, T. and Shanley, J. B. (2019). Soil aggregates as a source of dissolved organic carbon to streams: An experimental study on the effect of solution chemistry on water extractable carbon. Front. Environ. Sci. 7 : 1-14.
Cristina, E. F., Inonu, I. and Khodijah, N. S. (2022). Utilization of liquid organic fertilizer of pineapple peel waste for shallots cultivation (Allium ascalonicum L.). J. J. Suboptimal Lands 11: 1-13.
Das, S., Jeong, S. T., Das, S. and Kim, P. J. (2017). Composted cattle manure increases microbial activity and soil fertility more than composted swine manure in a submerged rice paddy. Front. Microbiol. 8: 1-10.
Dergam, H. and Abdulrazzak, O. (2022). Effect of humic acid on soil properties and productivity of maize irrigated with saline water. Environ. Sci. Proc. 16: 2-4
Dhillon, J., Del Corso, M. R., Figueiredo, B., Nambi, E. and Raun, W. (2018). Soil organic carbon, total nitrogen, and soil pH in a long-term continuous winter wheat (Triticum aestivum L.) experiment. Commun. Soil Sci. Plant Anal.  49: 803-13.
Dwevedi, A., Kumar, P., Kumar, P., Kumar, Y., Sharma, Y. K. and Kayastha, A. M. (2017). Soil sensors: detailed insight into research updates, significance, and future prospects. In: New pesticides and soil sensors. Pp. 561-94.
Faoziah, N., Iskandar and Djajakirana, G. (2022). The effect of the addition of cow dung compost and FABA on the chemical characteristics of sandy soil and the growth of tomato plants. J. Soil Environ. Sci. 24: 1-5.
Frimpong, K. A., Abban-Baidoo, E. and Marschner, B. (2021). Can the combined application of compost and biochar improve the quality of a highly weathered coastal savanna soil? Heliyon 7: doi.org/10.1016/j.heliyon.2021.e07089.
Haroon, B., Hassan, A., Abbasi, A. M., Ping, A., Yang, S. and Irshad, M. (2020). Effects of co-composted cow manure and poultry litter on the extractability and bioavailability of trace metals from the contaminated soil irrigated with wastewater. J. Water Reuse Desalin. 10: 17-29.
Li, S., Liu, Z., Li, J., Liu, Z., Gu, X. and Shi, L. (2022). Cow manure compost promotes maize growth and improves soil quality in saline-alkali soil: the role of fertilizer addition rate and application depth. Sustainability (Switzerland) 14: doi.org/10.3390/su141610088.
Nguyen, V. D. and Tran, D. H. (2022). Response of okra (Abelmoschus esculentus) to cow dung compost in central Vietnam. Res. Crop. 23: 375-79.
Suntoro, S., Widijanto, H., Suryono, Syamsiyah, J., Afinda, D. W., Dimasyuri, N. R. and Triyas, V. (2018). Effect of cow manure and dolomite on nutrient uptake and growth of corn (Zea mays L.). Bulg. J. Agric. Sci. 24: 1020-26.
Suryani, R., Masulili, A., Sutikarini, S. and Tamtomo, F. (2022). Utilization of liquid organic fertilizer of pineapple waste to improve growth of sweet corn plant in red yellow podsolic soil. Int. J. Multidiscip. Sci. 5: 30-36.
Tibu, C., Annang, T. Y., Solomon, N. and Yirenya-Tawiah, D. (2019). Effect of the composting process on physicochemical properties and concentration of heavy metals in market waste with additive materials in the Ga West Municipality, Ghana. Int. J. Recycl.Org. Waste  Agric. 8: 393-403.
Voltr, V., Menšík, L., Hlisnikovský, L., Hruška, M., Pokorný, E. and Pospíšilová, L. (2021). The soil organic matter in connection with soil properties and soil inputs. Agronomy 11: 1-21.
Walkley, A. J. and Black, I. A. (1934). Estimation of soil organic carbon by the chromic acid titration method. Soil Sci. 37: 29-38.
Wibowo, H. and Kasno, A. (2021). Soil organic carbon and total nitrogen dynamics in paddy soils on the Java Island, Indonesia. IOP Conf. Series: Earth Environ. Sci. 648: doi: 10.1088/1755-1315/648/1/012192.
Widodo, K. H. and Kusuma, Z. (2018). Effects of compost on soul physical properties and growth of maize on an inceptisol. J. Land Land Resour. 5: 959-67.
Wijanarko, A. and Purwanto, B. H. (2017). Effect of land use and organic matter on nitrogen and carbon labile fractions in a Typic Haplodult. J. Degraded and Mining Lands Manage. 4 : 837-43.
Yahya, Z., Mohammed, A. T., Harun, M. H. and Shuib, A. R. (2012). Oil palm adaptation to compacted alluvial soil (typic endoaquepts) in Malaysia. J. Oil Palm Res. 24: 1533-41.
Zhang, J, Gao, L., Pang, Z., Liu, L., Chen, X., Wang, S., Wang, H., Tong, R., Shi, C. and Chen, X. (2021). Effect of low-molecular-weight organic acids on phosphorus soil activation: A laboratory study of the soils from Wangbeng section of the Huaihe River Basin, China. Plants Soil Environ. 67: 660-67.
Zhang, J., Chi, F., Wei, D., Zhou, B., Cai, S., Li, Y., Kuang, E., Sun, L. and Li, L. J. (2019). Impacts of long-term fertilization on the molecular structure of humic acid and organic carbon content in soil aggregates in black soil. Sci. Rep. 9: 1-7.
Zziwa, A., Jjagwe, J., Kizito, S., Kabenge, I., Komakech, A. J. and Kayondo, H. (2021). Nutrient recovery from pineapple waste through controlled batch and continuous vermicomposting systems. J. Environ. Manag. 279: doi: 10.1016/j.jenvman.2020. 111784.

Global Footprints