Tropical and Subtropical Agroecosystems

Background. Soil acidity is a major soil health challenge that impacts agricultural productivity in Kenya while information on its national extent and severity remains limited. Objective. To determine national extent and spatial distribution of soil acidity, estimate the number of farming households affected and quantify lime requirements for acid soils within the Country. Methodology. This was achieved through application of data-driven approach, utilizing existing soil data collected at 0 -30 cm depth between 2012 and 2024, gridded environmental GIS layers, digital farmer registry data and geospatial analysis techniques. Soil pH and exchangeable acidity were then integrated to map acidity classes, estimate affected land area and households, and compute lime requirements for soils with pH≤5.5.  Results. Soil pH (H2O) across the Agricultural soils ranged from 3.7 to 10. 8. Approximately 13.29% (7.7 million ha) of the national land area was affected by soil acidity (pH ≤ 5.99), comprising < 1% (< 100 ha) extremely acid (pH ≤ 4.5), 0.2% (0.12 million ha) very strongly acid (pH 4.51 – 4.99), 5.5% (3.16 million ha) strongly acid (pH 5.00 – 5.50) and 7.6% (4.4 million ha) moderately acid (pH 5.51 – 5.99). The soil acidity problem spanned across 29 counties, with higher severity in Western, Rift Valley and Central Kenya. The counties with largest proportion of acidic land were Kisii (100%), Nyamira (100%), Vihiga (93%), Nandi (91%) and Kakamega (91%). Out of the 6.4 million digitally-registered farming households nationwide, Kisii County had the highest number (184,103) and proportion (83.6%) affected. Additionally, lime requirements at pH <5.5 were observed to vary widely ranging from 269 metric tons (MT) in Kakamega to 8 MT in Kisumu, and 0.58 ± 0.08 t ha-1 in Nakuru to 1.51 ± 0.07 t ha-1 in Nyamira. Implications. Obtained spatially-explicit soil acidity maps and lime requirement estimates provides evidence for supporting government and stakeholders in operationalization of soil health interventions, lime use policies, subsidy programs and prioritization of acid soil remediation and research. Conclusion. This study provides a nationally representative, spatiall assessment of soil acidity and lime requirements, offering critical guidance for targeted remediation and integrated soil health management approaches.

Acidic soils; lime; soil pH;

Agegnehu, G., Yirga, C. and Erkossa, T., 2019. Soil Acidity Management. Ethiopian Institute of Agricultural Research (EIAR). Addis Ababa, Ethiopia.

AUDA-NEPAD., 2023. Addressing Africa’s Soil Health Challenges Through the Ten-Year African Fertilizer and Soil Health Action Plan (2024–2034) and the Longer-Term Soil Initiative for Africa Framework: Briefing Note – December 2023. African Union Development Agency. Available at: https://www.nepad.org/file-download/download/public/149886 [Accessed 20 Dec. 2024].

Desta, G., Kassawmar, T., Tadesse, M. and Zeleke, G., 2021. Extent and distribution of surface soil acidity in the rainfed areas of Ethiopia. Land Degradation and Development, 32(18), pp.5348-5359.

Erica, L. and Larrea, C. 2024. Addressing Soil Acidity and Enhancing Soil Health. Recommendations for the use of lime and other conservation measures. SSI&EAC Policy Report. IISD, Winnipeg, Manitoba, pp. 31.

Esilaba, A.O., Opala, P.A., Nyongesa, D., Muindi, E.M., Gikonyo, E., Kathuku-Gitonga, A.N., Kamau, D.M., Kamau, M., Kisinyo, P.O., Wendt, J., Mutegi, J., Mbakaya, D., Adolwa, I., Kamau, N., Mangale, N., Maina, F.W., Gudu, S.O., Wanyama, J.M. and Biko, B., 2023. Soil Acidity and Liming Handbook for Kenya. Nairobi: Gatsby Africa, Eco Media.

Food and Agriculture Organization of the United Nations (FAO). 1988. Soil map of the world: Revised legend (World Soil Resources Report No. 60). FAO.

Gachene, C.K.K. and Kimaru, G., 2003. Soil Fertility and Land Productivity – A Guide for Extension Workers in the Eastern Africa Region. Technical Handbook No. 30. Nairobi: RELMA/SIDA.

Hijbeek, R., van Loon, M.P., Ouaret, W., Boekelo, B. and van Ittersum, M.K., 2021. Liming agricultural soils in Western Kenya: Can long-term economic and environmental benefits pay off short-term investments? Agricultural Systems, 190, p.103095. https://doi.org/10.1016/j.agsy.2021.103095.

Jaetzold, R., Schmidt, H., Hornetz, B. and Shisanya, C., 2010. Farm Management Handbook of Kenya Vol. II – Natural Conditions and Farm Management Information. 2nd Edition, Part A1–A3. Ministry of Agriculture, Kenya in cooperation with the German Agency for Technical Cooperation (GTZ).

Jaetzold, R., Schmidt, H., Hornet, Z.B. and Shisanya, C.A., 2012. Farm Management Handbook of Kenya. Vol. 1–4. Nairobi: Ministry of Agriculture/GTZ.

Kamprath, E.J., 1970. Exchangeable aluminium as a criterion for liming leached mineral soils. Soil Science Society of America Proceedings, 34, pp.252–254.

Kanengereh N, A., 1979. Lime requirements of Kenya acid soils. MSc Thesis. Nairobi: University of Nairobi.

Kanyanjua, S.M., Ireri, L., Wambua, S. and Nandwa, S.M., 2002. Acidic Soils in Kenya: Constraints and Remedial Options. Kenya Agricultural Research Institute. Available at: https://repository.seku.ac.ke/bitstream/handle/123456789/4313/Wambua_Acidic%20soils%20in%20Kenya....pdf?sequence=1&isAllowed=y [Accessed 20 Dec. 2024].

Kibet, P.K., Mugwe, J.N., Korir, N.K., Mucheru-Muna, M.W., Ngetich, F.K. and Mugendi, D.N., 2023. Granular and powdered lime improves soil properties and maize (Zea mays L.) performance in humic nitisols of Central Highlands in Kenya. Heliyon, 9(6), p.e17286. https://doi.org/10.1016/j.heliyon.2023.e17286.

Kisinyo, P., Othieno, O., Gudu, S., Okalebo, R., Opala, P., Maghanga, J., Ng’etich, W., Agalo, J., Opile, R., Kisinyo, J. and Ogola, B., 2013. Phosphorus sorption and lime requirements of maize growing acid soils of Kenya. Sustainable Agriculture Research, 2(2), pp.116. https://doi.org/10.5539/sar.v2n2p116.

Kisinyo, P.O., Othieno, C.O., Gudu, S.O., Okalebo, J.R., Opala, P.A., Maghanga, J.K., Ng’etich, W.K., Agalo, J.J. and Kisinyo, J.A., 2014. Immediate and residual effects of lime and phosphorus fertilizer on soil acidity and maize production in western Kenya. Experimental Agriculture, 50(1), pp.128–143. https://doi.org/10.1017/S0014479713000318.

Kisinyo, P.O., Othieno, C.O., Gudu, S.O., Okalebo, J.R., Opala, P.A., Maghanga, J.K., Ng’etich, W.K., Agalo, J.J. and Kisinyo, J.A., 2015a. Micro-dosing of lime, phosphorus and nitrogen fertilizers effect on maize performance on an acid soil in Kenya. Sustainable Agriculture Research, 4(2), pp.21–30. https://doi.org/10.5539/sar.v4n2p21.

Kisinyo, P., Opala, P., Gudu, S., Othieno, C.O., Okalebo, J.R., Palapala, V. and Otinga, A., 2015b. Recent advances towards understanding and managing Kenyan acid soils for improved crop production. African Journal of Agricultural Research, 9, pp.2397–2408. https://doi.org/10.5897/AJAR2013.8359.

Kopittke, P.M., Menzies, N.W., Wang, P., McKenna, B.A. and Lombi, E., 2019. Soil and the intensification of agriculture for global food security. Environment International, 132, p.105078. https://doi.org/10.1016/j.envint.2019.105078.

Laekemariam, F. and Kibret, K., 2021. Extent, distribution, and causes of soil acidity under subsistence farming system and lime recommendation: The case in Wolaita, Southern Ethiopia. Applied and Environmental Soil Science, Article ID 5556563. https://doi.org/10.1155/2021/5556563.

Liana, E. and Pozza, D.J., 2020. The science of soil security and food security. Soil Security, 1, p.100002. https://doi.org/10.1016/j.soisec.2020.100002.

Gichaba, C.M., 2013. Overview of landslide occurrences in Kenya. In: D.K. Pal and P.N. Owens, eds. Developments in Earth Surface Processes. Amsterdam: Elsevier, pp.1–22. https://doi.org/10.1016/B978-0-444-59559-1.00020-7.

McLean, E.O., Eckert, D.J., Reddy, G.Y. and Trierweiler, J.F., 1978. An improved SMP soil lime requirement method incorporating double-buffer and quick-test features. Soil Science Society of America Journal, 42, pp.311–316. https://doi.org/10.2136/sssaj1978.03615995004200020022x

Mehlich, A., Bellis, E. and Gitau, J.K., 1964. Fertilizing and liming in relation to soil chemical properties. Nairobi: Department of Agriculture, Kenya, Scott Laboratories.

Mganga, K.Z., 2022. Agricultural land degradation in Kenya. In: P. Pereira, M. Muñoz-Rojas, I. Bogunovic and W. Zhao, eds. Impact of Agriculture on Soil Degradation I. Cham: Springer, pp.1–23. https://doi.org/10.1007/698_2022_929.

Ministry of Agriculture and Livestock Development (MoALD), 2024. National Farmer Registration (NFR) Statistics. Available at: https://www.kalro.org/kiamis/nfr_stat.html [Accessed 20 Dec. 2024].

Muindi, E.M., Mrema, J.P., Semu, E., Mtakwa, P.W., Gachene, C.K. and Njogu, M.K., 2015. Phosphorus adsorption and its relation with soil properties in acid soils of Western Kenya. International Journal of Plant and Soil Science, 4(3), pp.203–211. https://doi.org/10.9734/IJPSS/2015/13037

Muindi, E.M., 2016. Phosphorus retention and the interactive effects of phosphorus, lime and tillage on maize in acid soils of the Kenya Highlands. PhD Thesis. Sokoine University of Agriculture, Tanzania.

Muindi, E.M., Semu, E., Mrema, J.P., Mtakwa, P.W., Gachene, C.K. and Njogu, M.K., 2016. Soil acidity management by farmers in the Kenya Highlands. Journal of Agriculture and Ecology Research International, 5(3), pp.1–11. https://doi.org/10.9734/JAERI/2016/22519

Muindi, E.M., 2020. Effects of liming on dithionate and oxalate extractable aluminum in acid soils. Asian Journal of Soil Science and Plant Nutrition, 5(3), pp.1–9. https://doi.org/10.9734/AJSSPN/2019/v5i330069.

Muthoni, F.K., Guo, Z., Bekunda, M., Sseguya, H., Kizito, F., Baijukya, F. and Hoeschle-Zeledon, I., 2017. Sustainable recommendation domains for scaling agricultural technologies in Tanzania. Land Use Policy, 66, pp.34–48. https://doi.org/10.1016/j.landusepol.2017.04.028

National Accelerated Agricultural Inputs Access Programme (NAAIAP), 2014. Soil suitability evaluation for maize production in Kenya. Available at: https://kalroerepository.kalro.org/items/81c2150e-77ca-4489-8e0a-19cca5648433/full [Accessed 20 Dec. 2024].

National Land Commission (NLC), 2023. Kenya Natural Resources Atlas. Available at: https://landcommission.go.ke/download/kenya-country-natural-resource-atlas/?wpdmdl=19905&refresh=676983d1dd2891734968273 [Accessed 20 Dec. 2024].

Okalebo, J.R., Gathua, K.W. and Woomer, P.L., 2002. Laboratory Methods of Soil Analysis: A Working Manual. 2nd ed. Nairobi: TSBF-CIAT and SACRED Africa.

Opala, P.A., Odendo, M. and Muyekho, F.N., 2018. Effects of lime and fertilizer on soil properties and maize yields in acid soils of western Kenya. African Journal of Agricultural Research, 13, pp.657–663. https://doi.org/ 10.5897/AJAR2018.13066

Owusu, S., Hartemink, A.E., Zhang, Y., Csorba, Á. and Michéli, E., 2024. Exchangeable acidity and pedotransfer functions for the soils of Ghana. European Journal of Soil Science. https://doi.org/10.1111/ejss.13460

Pulfrey, D.L., 1969. Geology of the Lake Victoria Region, Kenya. Bulletin no. 29. Nairobi: Geological Survey of Kenya, Government Printer.

Sanchez, P.A., 2019. Properties and Management of Soils of the Tropics. 2nd ed. Cambridge: Cambridge University Press.

Sileshi, G.W., Kihara, J., Tamene, L., Vanlauwe, B., Phiri, E. and Jama, B., 2022. Unravelling causes of poor crop response to applied N and P fertilizers on African soils. Experimental Agriculture, 58, p.e7, https://doi.org/10.1017/S0014479721000247.

Sombroek, W. G., Braun, H. M. H. and van der Pouw, B. J. A., 1982. Exploratory soil map and agro-climatic zone map of Kenya, 1980, scale 1: 1,000,000. (Exploratory soil survey report. Kenya Soil Survey; No. no. E1). Kenya Soil Survey. Available at: https://edepot.wur.nl/399397 [Accessed 20 Dec. 2024].

Suleymanov, A., Richer-de-Forges, A.C., Saby, N.P.A., Arrouays, D., Martin, M.P. and Bispo, A., 2024. National-scale digital soil mapping performances are related to covariates and sampling density: Lessons from France. Geoderma Regional, 37, p.e00801. https://doi.org/10.1016/j.geodrs.2024.e00801

Survey of Kenya, 2014. Kenya topographical and cadastral data: National mapping report. Ministry of Lands and Physical Planning, Government of Kenya.

U.S. Department of Agriculture, 2022. Soil pH: Soil Health Guide. Available at: https://www.nrcs.usda.gov/sites/default/files/2022-11/pH%20-%20Soil%20Health%20Guide_0.pdf [Accessed 20 Dec. 2024].

United Nations Environment Programme (UNEP), 2006. Africa Environment Outlook 2: Our Environment, Our Wealth. Nairobi: UNEP. Available at: https://www.unep.org/resources/report/africa-environment-outlook-2-our-environment-our-wealth [Accessed 20 Dec. 2024].

van Wijk, M.T., Hammond, J., Giller, K.E., Klapwijk, C.J. and van Etten, J., 2020. The Future of Farming: Who Will Produce Our Food? Wageningen: Wageningen University & Research. Available at: https://edepot.wur.nl/488039 [Accessed 20 Dec. 2024].

Weil, R. and Brady, N.C., 2017. The Nature and Properties of Soil. 15th ed. Boston: Pearson.

Were, K.O., Bui, D.T., Dick, Ø.B. and Singh, B.R., 2015. A comparative assessment of support vector regression, artificial neural networks, and random forests for predicting and mapping soil organic carbon stocks across an Afro-montane landscape. Ecological Indicators, 52, pp.394–403. http://dx.doi.org/10.1016/j.ecolind.2014.12.028

Zama, N., Kirkman, K., Mkhize, N., Tedder, M. and Magadlela, A., 2022. Soil acidification in nutrient-enriched soils reduces the growth, nutrient concentrations, and nitrogen-use efficiencies of Vachellia sieberiana (DC.) Kyal. & Boatwr saplings. Plants, 11(24), p.3564. https://doi.org/10.3390/plants11243564.

Zingore, S., Desalegn, T., Diallo, A., Amede, T., Njoroge, S., Diallo, M., Wanjiru, L. and Botillen, Ø., 2023. The implication of soil acidity and management options for sustainable crop production in Africa. Growing Africa, 2(1), pp.32–38. Available at: https://growingafrica.pub/the-implication-of-soil-acidity-and-management-options-for-sustainable-crop-production-in-africa/ [Accessed 20 Dec. 2024].