The importance of organic matter addition in composted mounds in terms of nutrients status, nutrient uptake, and environmental impact under different climatic conditions need to be studied. This study was conducted to assess the importance of Cogon grass materials addition as organic matter in composted mounds used for sweet potato cultivation on selected sandy loam soil properties under humid lowland, tropical climatic conditions. A replicated trial with four treatments with or without organic matter or sweet potato plants was set in a completely randomized design. After 6 months, soil samples were collected from two profiles in each treatment and analyzed for selected soil physiochemical properties. Data collected from each profile was pooled, averages taken, and statistically analyzed. The results showed organic matter addition increased water holding capacity and electrical conductivity, lowered soil bulk density, pH, and soil organic carbon content. Cultivation of sweet potato in soil with or without organic matter amendment, in general, depleted nitrogen, potassium, and magnesium contents and increased phosphorous availability. This study showed the addition of Cogon grass materials as organic matter in composted mounds has implications for the production of sweet potato in sandy loam soil in the tropics.

Aipa, J, & Michael, P. S. (2019). Different land-use system improves soil fertility status of sandy soil and increases the yield of rice under rain-fed wet tropical lowland conditions in Papua New Guinea. Int J Agric Environ Res, 5, 19–27.

Aipa, James, & Michael, P. S. (2018). Poultry manure application and fallow improve peanut production in sandy soil under continuous cultivation. International Journal of Environmental and Agriculture Research, 4(2).

Al-Esailyl, I. A., & El-Naka, E. A. (2013). Effects of magnesium and humic acid on the productivity of sweet potato grown in sandy soil. Egypt Journal of Applied Science, 28, 615–633.

D’Souza, E., & Bourke, R. M. (1982). Compost increases sweet potato yields in the highlands. Harvest, 8(4), 171–175.

Floyd, C. N., Lefroy, R. D. B., & D’souza, E. J. (1988). Soil fertility and sweet potato production on volcanic ash soils in the highlands of Papua New Guinea. Field Crops Research, 19(1), 1–25.

Hughes, M. J., Coleman, E. A., Taraken, I. T., & Igua, P. (2009). Sweetpotato agronomy in Papua New Guinea. Soil Fertility in Sweetpotato-Based Cropping Systems in the Highlands of Papua New Guinea (Edited by G. Kirchhof). ACIAR Technical Report, 71, 12–23.

Hunt, N., & Gilkes, R. (1992). Farm monitoring handbook.

Jiang, X., Cao, L., & Zhang, R. (2014). Changes of labile and recalcitrant carbon pools under nitrogen addition in a city lawn soil. Journal of Soils and Sediments, 14(3), 515–524.

Landon, J. R. (1991). Booker tropical soil manual: a handbook for soil survey and agricultural land evaluation in the tropics and subtropics. Longman Scientific & Technical.

Mårtensson, A. M., & Witter, E. (1990). Influence of various soil amendments on nitrogen-fixing soil microorganisms in a long-term field experiment, with special reference to sewage sludge. Soil Biology and Biochemistry, 22(7), 977–982.

Michael, P. S. (2020). Simple carbon and organic matter addition in acid sulfate soils and time-dependent changes in pH and redox under varying moisture regimes. Asian Journal of Agriculture, 4(1).

Michael, P. S. (2019). Roles of Leucaena leucocephala on sandy loam soil pH, bulk density, water-holding capacity, and carbon stock under humid lowland tropical climatic conditions. Bull J Soil Sci, 4, 33–45.

Michael, P. S., Fitzpatrick, R., & Reid, R. (2015). The importance of organic matter on amelioration of acid sulfate soils with sulfuric horizons. Geoderma, 225, 42–49.

Michael, P. S. (2018a). Comparative analysis of the ameliorative effects of soil carbon and nitrogen amendment on surface and subsurface soil pH, Eh, and sulfate content of acid sulfate soils. Eurasian Soil Science, 51, 1181–1190.

Michael, P. S. (2018b). Effects of live and dead plant matter on the stability of pH, redox potential, and sulfate content of sulphuric soil material neutralized by addition of alkaline sandy loam. Malaysian Journal of Soil Science, 22, 1–18.

Michael, P. S. (2018c). The Roles of Surface Soil Carbon and Nitrogen in Regulating the Surface Soil pH and Redox Potential of Sulfidic Soil Materials of Acid Sulfate Soils. Pertanika Journal of Tropical Agricultural Science, 41(4).

Michael, P. S, Fitzpatrick, R. W., & Reid, R. J. (2016). The importance of soil carbon and nitrogen for amelioration of acid sulphate soils. Soil Use and Management, 32(1), 97–105.

Michael, P. S., Fitzpatrick, R. W., & Reid, R. J. (2017). Effects of live wetland plant macrophytes on acidification, redox potential and sulphate content in acid sulphate soils. Soil Use and Management, 33(3), 471–481.

Michael, P. S., & Reid, J. R. (2018). The combined effects of complex organic matter and plants on the chemistry of acid sulfate soils under aerobic and anaerobic soil conditions. Journal of Soil Science and Plant Nutrition, 18, 542–555.

Michael, P. S. (2015). Effects of alkaline sandy loam on sulfuric soil acidity and sulfidic soil oxidation. International Journal of Environment, 4(3), 42–54.

Michael, P. S. (2020). Cogon grass biochar amendment and Panicum coloratum planting improve selected properties of sandy soil under humid lowland tropical climatic conditions. Biochar, 2(4), 489–502.

Muktamar, Z., Lifia, L., & Adiprasetyo, T. (2020). Phosphorus availability as affected by the application of organic amendments in Ultisols. SAINS TANAH-Journal of Soil Science and Agroclimatology, 17(1), 16–22.

Parvage, M. M., Ulén, B., Eriksson, J., Strock, J., & Kirchmann, H. (2013). Phosphorus availability in soils amended with wheat residue char. Biology and Fertility of Soils, 49(2), 245–250.

Pérez-Piqueres, A., Edel-Hermann, V., Alabouvette, C., & Steinberg, C. (2006). Response of soil microbial communities to compost amendments. Soil Biology and Biochemistry, 38(3), 460–470.

Schulte, E. E., & Hopkins, B. G. (1996). Estimation of soil organic matter by weight loss‐on‐ignition. Soil Organic Matter: Analysis and Interpretation, 46, 21–31.

Schulz, H., & Glaser, B. (2012). Effects of biochar compared to organic and inorganic fertilizers on soil quality and plant growth in a greenhouse experiment. Journal of Plant Nutrition and Soil Science, 175(3), 410–422.

Shakir, M. S., & Razzaq, A. (2002). Effect of salts on bulk density, particle density, and porosity of different soil series. Asian Journal of Plant Sciences.

Taraken, I. T., & Ratsch, R. (2009). Sweetpotato cultivation on composted mounds in the highlands of Papua New Guinea. Soil Fertility in Sweetpotato-Based Cropping Systems in the Highlands of Papua New Guinea, 24–32.

Tilston, E. L., Pitt, D., & Groenhof, A. C. (2002). Composted recycled organic matter suppresses soil‐borne diseases of field crops. New Phytologist, 154(3), 731–740.

Tiquia, S. M. (2010). Reduction of compost phytotoxicity during the process of decomposition. Chemosphere, 79(5), 506–512.

Tiquia, S. M., Tam, N. F. Y., & Hodgkiss, I. J. (1996). Microbial activities during composting of spent pig-manure sawdust litter at different moisture contents. Bioresource Technology, 55(3), 201–206.

Tuitert, G., Szczech, M., & Bollen, G. J. (1998). Suppression of Rhizoctonia solani in potting mixtures amended with compost made from organic household waste. Phytopathology, 88(8), 764–773.

Tuomela, M., Vikman, M., Hatakka, A., & Itävaara, M. (2000). Biodegradation of lignin in a compost environment: a review. Bioresource Technology, 72(2), 169–183.

Weber, J., Karczewska, A., Drozd, J., Licznar, M., Licznar, S., Jamroz, E., & Kocowicz, A. (2007). Agricultural and ecological aspects of sandy soil as affected by the application of municipal solid waste composts. Soil Biology and Biochemistry, 39(6), 1294–1302.

Xiong, Y., Zeng, H., Xia, H., & Guo, D. (2014). Interactions between leaf litter and soil organic matter on carbon and nitrogen mineralization in six forest litter-soil systems. Plant and Soil, 379(1–2), 217–229.