Management of sandy soil in oil palm plantations requires location-specific technology that prioritizes sustainability principles. Palm oil mill Effluent (POME) has the potential to be a substitute for nutrients for oil palm plantations. This research aims to reveal the role of POME in improving soil and tissue nutrient status and increasing oil palm production on sandy soil. The research was conducted on eleven plantation blocks using POME and six blocks without by-products (30 ha block^-1, sandy soil) of 12-13 years palm. Observations were carried out for 3 years, including harvest tonnage, number and weight of fresh fruit bunches (FFB) of palm oil, soil, and tissue nutrient content (N, P, K, Mg, Ca, Cu, and B), CEC, and soil organic carbon. The research results show that POME flatbed system application can increase the nutrient content, pH, CEC, and soil organic carbon in the low to medium range. This application can also increase the tissue nutrient content to the optimal range. Production, quantity, and weight of oil palm FFB on sandy soil applied by POME were increased compared to those without by-product application. This application can also reduce monthly fluctuations in palm oil production on sandy soil.

POME, Production, Sandy soil; Soil nutrients; Tissue

Adam H, Collin M, Richaud F, Beulé T, Cros D, Omoré A, Nodichao L, Nouy B, Tregear JW. 2011. Environmental regulation of sex determination in oil palm: Current knowledge and insights from other species. Ann Bot. 108(8):1529–1537. https://doi.org/10.1093/aob/mcr151.

Advent R, Zulgani Z, Nurhayani N. 2021. Analisis faktor-faktor yang mempengaruhi ekspor minyak kelapa sawit di Indonesia Tahun 2000-2019. e-Journal Perdagang Ind dan Monet. 9(1):49–58. https://doi.org/10.22437/pim.v9i1.13652.

Barcelos E, De Almeida Rios S, Cunha RNV, Lopes R, Motoike SY, Babiychuk E, Skirycz A, Kushnir S. 2015. Oil palm natural diversity and the potential for yield improvement. Front Plant Sci. 6(MAR):1–16. https://doi.org/10.3389/fpls.2015.00190.

Boafo DK, Kraisornpornson B, Panphon S, Owusu BE, Amaniampong PN. 2020. Effect of organic soil amendments on soil quality in oil palm production. Appl Soil Ecol. 147:103358. https://doi.org/10.1016/j.apsoil.2019.09.008.

Carron MP, Pierrat M, Snoeck D, Villenave C, Ribeyre F, Suhardi, Marichal R, Caliman JP. 2015. Temporal variability in soil quality after organic residue application in mature oil palm plantations. Soil Res. 53(2):205–215. https://doi.org/10.1071/SR14249.

Corley RHV, Tinker PB. 2015. The oil palm. 5th ed. Oxford (EN): Jhon Wiley and Sons.

Dislich C, Keyel AC, Salecker J, Kisel Y, Meyer KM, Auliya M, Barnes AD, Corre MD, Darras K, Faust H, et al. 2017. A review of the ecosystem functions in oil palm plantations, using forests as a reference system. Biol Rev. 92(3):1539–1569. https://doi.org/10.1111/brv.12295

Fairhurst T, Griffiths W, Rankine I. 2019. TCCL field handbooks: Oil palm-agronomy. Kent (EN): Tropical Crop Consultants Limited.

Fairhurst Thomas, Hardter R. 2003. Oil palm: Management for large and sustainable yields. Fairhurst Th., Härdter R, editor. Canada (CA): International Plant Nutrition Institute.

Ginting C, Prasetio D. 2019. Produktivitas kebun kelapa sawit dengan aplikasi berbagai kombinasi pupuk dan janjang kosong pada lahan pasiran. Agroista J Agroteknologi. 3(1):44–55.

Hasanuzzaman M, Bhuyan M, Nahar K, Hossain M, Mahmud J, Hossen M, Masud A, Moumita, Fujita M. 2018. Potassium: A vital regulator of plant responses and tolerance to abiotic stresses. Agronomy. 8(3):31. https://doi.org/10.3390/agronomy8030031.

Hazmi A, Desmiarti R, Waldi EP, Emeraldi P. 2016. Preliminary study on treatment of palm oil mill effluent by sand filtration-dielectric barrier discharge system. J Eng Technol Sci. 48(1):21–30. https://doi.org/10.5614/j.eng.technol.sci.2016.48.1.3.

Marschner P. 2012. Marschner’s Mineral Nutrition of Higher Plants. 3rd ed. Cambridge (US): Elsevier.

McCarthy B, Liu HB, Chen T. 2016. Innovations in the agro-food system: Adoption of certified organic food and green food by Chinese consumers. Caiazza, Tiziana Volpe, John L. Sta R, editor. Br Food J. 118(6):1334–1349. https://doi.org/10.1108/BFJ-10-2015-0375.

Monita CF, Zebua DDN. 2023. Faktor-faktor yang mempengaruhi produktivitas kelapa sawit di PT. Mustika Agung Sentosa. J Manaj Agribisnis. 11(1):229–241. https://doi.org/10.24843/jma.2023.v11.i01.p18.

Monzon JP, Jabloun M, Cock J, Caliman JP, Couëdel A, Donough CR, Vui PHV, Lim YL, Mathews J, Oberthür T, et al. 2022. Influence of weather and endogenous cycles on spatiotemporal yield variation in oil palm. Agric For Meteorol. 314:108789. https://doi.org/10.1016/j.agrformet.2021.108789.

Paltseva J, Searle S, Malins C. 2016. Potential for advanced biofuel production from palm residues in Indonesia. Intenational Counc Clean Transp.(June):1–17.

Paterson RRM. 2020. Oil palm survival under climate change in Kalimantan and alternative SE Asian palm oil countries with future basal stem rot assessments. For Pathol. 50(4):12604. https://doi.org/10.1111/efp.12604.

Paterson RRM. 2023. Future climate effects on yield and mortality of conventional versus modified oil palm in SE Asia. Plants. 12(12):2236. https://doi.org/10.3390/plants12122236.

Poh PE, Wu TY, Lam WH, Poon WC, Lim CS. 2020. Waste management in the palm oil industry: Plantation and milling processes. Cham (CH): Springer International Publishing (Green Energy and Technology).

Ramadhan R, Tampubolon G, Ermadani E. 2021. Pengaruh pemberian limbah cair pabrik kelapa sawit terhadap beberapa sifat kimia tanah dan pertumbuhan bibit kelapa sawit pada pembibitan utama. J Silva Trop. 5(1):339–356. https://doi.org/10.22437/jsilvtrop.v5i1.12429.

Siregar RS, Khusrizal, Yusra, Nasruddin. 2023. Improving the chemical quality of sandy-textured soil and shallot (Allium cepa L.) yields using biochar and clay. J Ilm Pertan. 20(2):175–186. https://doi.org/10.31849/jip.v20i2.13760

Sonali, Huda S, Jayasena V, Ahmed T, Chen ZH. 2023. Potassium transport and use efficiency for sustainable fertigation in protected cropping. J Sustain Agric Environ. 2(3):346–356. https://doi.org/10.1002/sae2.12065.

Susanto JP, Santoso AD, Suwedi N. 2017. Perhitungan potensi limbah padat kelapa sawit untuk sumber energi terbaharukan dengan Metode LCA. J Teknol Lingkung. 18(2):165–172. https://doi.org/10.29122/jtl.v18i2.2046.

Taiz L, Zeiger E. 2010. Plant physiology. 5th ed. Sunderland (EN): Sinauer Associates Inc.

Viena V, Bahagia, Nurlaini, Juanda R. 2023. Efektivitas penurunan COD , BOD dan TSS limbah industri sawit menggunakan koagulan kimia dan ekstrak alami pati pelepah sawit. J Serambi Eng. 8(1):4931–4939.

Yama DI, Kartiko H. 2020. Pertumbuhan dan Kandungan klorofil pakcoy (Brassica rapa L) pada beberapa konsentrasi AB Mix dengan Sistem Wick. J Teknol. 12(1):21–30.

Yudha EP, Bagaskara F. 2024. Analisis daya saing ekspor kelapa sawit (CPO) Indonesia dan Malaysia di India. J Ilm Mhs Agroinfo Galuh. 11(2):1212–1227.

Yuniarti DP, Komala R, Aziz S. 2019. Pengaruh proses aerasi terhadap pengolahan limbah cair pabrik kelapa sawit di PTPN VII secara aerobik. J Redoks. 4(2):7–16.