JOURNAL OF AGRICULTURAL SCIENCE AND PRACTICE
Integrity Research Journals
ISSN: 2536-7072
Model: Open Access/Peer Reviewed
DOI: 10.31248/JASP
Start Year: 2016
Email: jasp@integrityresjournals.org
Soil degradation assessment of some selected land use in two Agro ecological zones of Gombe State, Nigeria
https://doi.org/10.31248/JASP2022.386 | Article Number: BDA5382D1 | Vol.7 (4) - December 2022
Received Date: 18 November 2022 | Accepted Date: 06 December 2022 | Published Date: 30 December 2022
Authors: Ibrahim, A. K.* , Bappah, M. and Muhammad, Z.
Keywords: Agro ecological zones, soil degradation, soil fertility; sustainability, indicator.
Soil degradation remains a global environmental phenomenon caused by anthropogenic activities. The assessment of degradation status of soils in some selected land uses of two agro ecological zones of Gombe state was carried out. Representative soil samples from four land uses were collected from 0 - 30 cm depths (cultivated, Fadama, forest and mining land). The soil samples were labeled, air-dried, crushed, sieved through a 2 mm mesh, and subjected to various physical and chemical analyses. Data collected were subjected to descriptive statistics and soil degradation assessment was done following standard procedures. The levels of degradation of soils were assessed using the standard indicators and criteria for land degradation assessment by the Global Assessment of Land Degradation. Analytical data from each sample were placed in a degradation class by matching the soil characteristics with the land degradation indicators, while estimation of the overall degree of degradation was arrived at mathematically, using physical, chemical, and biological parameters. The results shows that the textural class of the soil ranged from clay to sandy loam. Permeability ranged from 0.10 to 7.97 cm hr-1 corresponding low to high permeability. Bulk density ranged from 1.24 to 1.62 g cm-3. Organic matter was very low in all the study sites. Available phosphorus ranged from 6.2 to 15.5 mgkg-1. Total nitrogen was predominantly low (0.05 – 0.08%) in all the land uses. Exchangeable Sodium Percentage (ESP) of the sites depicted that most of the soils were non sodic soils (0.71 – 1.61%). The potential for all the land uses are moderately degraded varied from Fadama land (41.67%), cultivated land (44.44%), mining land (47.22%) and forest land (50%), respectively. The major barriers in the study areas were low fertility, and soil conservation measures. In order to optimize crop production in these areas, there may be need to introduce soil conservation measures. The practice may include use of farm yard manure, compost, crop residues, green manure or poultry manure to boost soil fertility. Regular monitoring of the fertility status of the soils is encouraged.
| Adhikari, K., & Hartemink, A. E. (2016). Linking soils to ecosystem services-A global review. Geoderma, 262, 101-111. Crossref |
||||
| Agbai, W. P., & Kosuowei M. T. (2022). Influence of land-use systems on hydraulic properties of soils in Yenagoa and Amassoma, Bayelsa State, Nigeria. International Journal of Environment, 11(1), 23-45, Crossref |
||||
| Agbede O. O. (2009). Understanding soil and plant nutrition (1st edition). Petra Digital Press, Nigeria. Pp.132-160. | ||||
| Agbenin, J. O. (1995). Laboratory manual for soil and plant analysis (Selected methods and data analysis). Department of Soil Science, ABU Zaria. 140p. | ||||
| Ahukaemere, C. M., Ndukwu, B. N., & Agim, L. C. (2012). Soil quality and soil degradation as influenced by agricultural land use types in the humid environment. International Journal of Forest, Soil and Erosion. 2(4), 175-179. | ||||
| Ananya, C., Swaroop, N., Smriti Rao, P., & Tarence, T (2019). Effect of NPK and Zn fertilizers on growth and yield of maize (Zea mays L.) Var. Shivani-KSHM 1980. International Journal of Chemical Studies, 7(3), 1864-1867 | ||||
| Ande, O. T., & Senjobi, B. A. (2014). Comparison of soil quality improvement under different fallow types on dystric nitosols derived from sand stone in south western Nigeria. Agricultural Sciences, 5(11), 1061-1068. Crossref |
||||
| Ashenafi, A., Esayas, A., & Beyene, S. (2010). Characterizing soils of Delbo Wegene watershed, Wolaita Zone, Southern Ethiopia for planning appropriate land management. Journal of Soil Science and Environmental Management, 1(8)184-199. | ||||
| Awwal, A. Y., Onokebhagbe, V. O., & Adegboye, K. A. (2020). Degradation assessment of fallowed and cultivated soils of Teaching and Research Farm, Federal University Dutse, Jigawa State. Proceedings of the 44 the Conference of Soil Science Society of Nigeria on Climate-smart soil management, soil health/quality and land management synergies for sustainable ecosystem services. Colloquia series. Pp. 67-70. Crossref |
||||
| Barrios, E. (2007). Soil biota, ecosystem services and land productivity. Ecological economics, 64(2), 269-285. Crossref |
||||
| Bartlett, G. N., Craze, B., Stone, M. J., & Crouch, R. (1994). Guidelines for analytical laboratory safety. Department of Conservation & Land Management, Sydney. | ||||
| Bello, Y., Adebayo, A. A. and Abubakar, B. (2020). Analysis of rainfall and temperature changes in Gombe State, Nigeria. FUDMA Journal of Sciences, 4(1) 632-646. | ||||
| Brady, N. C., & Weil, R. R. (2017). The nature and properties of soil (15th edition). Macmillan Publishing Company, New York, USA. Pp. 661-699. | ||||
| Bremner, J. (2012). Population and food security: Africa's challenge. Population Reference Bureau. Last modified February 2012. | ||||
| Brevik, E. C., Cerdà, A., Mataix-Solera, J., Pereg, L., Quinton, J. N., Six, J., & Van Oost, K. (2015). The interdisciplinary nature of soil. Soil, 1(1), 117-129. Crossref |
||||
| Cerdà, A., González-Pelayo, Ó., Giménez-Morera, A., Jordán, A., Pereira, P., Novara, A., Brevik, E. C., Prosdocimi, M., Mahmoodabadi, M., Keesstra, S., & Ritsema, C. J. (2016). Use of barley straw residues to avoid high erosion and runoff rates on persimmon plantations in Eastern Spain under low frequency-high magnitude simulated rainfall events. Soil Research, 54(2), 154-165. Crossref |
||||
| Di, H. J., Cameron, K. C., & Shen, J. (2013). The role of bacteria and archaea in nitrification, nitrate leaching and nitrous oxide emissions in nitrogen-rich grassland soils. In: Xu, J., & Sparks, D. L. (eds.). Molecular Environmental Soil Science, Springer, Dordrecht, Netherlands. Pp. 79-89, Crossref |
||||
| Doran, J. W., & Zeiss, M. (2000). Soil health and sustainability: Managing the biotic component of soil quality. Applied Soil Ecology, 15(1), 3-11. Crossref |
||||
| Esu, I. E. (1991). Detailed soil survey of NIHORT farm at Bunkure, Kano State, Nigeria. Institute for Agricultural Research, Ahmadu Bello University, Zaria, Nigeria. | ||||
| Ewetola, E. A., Owoade, F. M., & Olatunji, O. O. (2015). Assessment of degradation status of soils in selected areas of Ogbomoso, Oyo State, Nigeria. International Letters of Chemistry, 59, 17-25. Crossref |
||||
| FAO (1979). A framework for land evaluation. Soil resource development and conservation service: land and water development division, Rome, Italy. | ||||
| FAO, IFAD, UNICEF, WFP, WHO (2017). The state of food security and nutrition in the world 2017. Building Resilience for Peace and Food Security. Rome, FAO. | ||||
| Fasinmirin, J. T., & Adesigbin, A. J. (2011). Soil physical properties and hydraulic conductivity of compacted sandy clay loam planted with maize Zee may. In: Proceedings of the Environmental Management Conference, Abeokuta: Federal University of Agriculture. | ||||
| GLASOD (1998). Global assessment of soil degradation. Guidelines for general assessment of the status of human-induced soil degradation. Wageningen (Netherlands) ISRIC and UNEP. | ||||
| Gorobtsova, O. N., Gedgafova, F. V., Uligova, T. S., & Tembotov, R. K. (2016). Ecophysiological indicators of microbial biomass status in chernozem soils of the Central Caucasus (in the territory of Kabardino-Balkaria with the Terek variant of altitudinal zonation). Russian Journal of Ecology, 47(1), 19-25. Crossref |
||||
| Hakeem A. A., Ignatius I. A., Abubakar H. I., Folorunso M. A., & Tukur A. (2020). Handbook on improved pearl millet production practices in Northeastern Nigeria. Feed the Future Nigeria Integrated Agriculture Activity. | ||||
| Ibrahim, A. K., & Muhammad, H. U. (2021). Effects of land use on concentration of some heavy metals in soil and plant leaves in Kashere Area, Akko Local Government Area of Gombe State, Nigeria. Taraba Journal of Agricultural Research, 9(1), 28-36. | ||||
| Ibrahim, A. K., & Umar, A. H., (2012). Profile distribution of micronutrients in Jangargari, Yamaltu-Deba Local Government Area, Gombe State. Journal of Applied Phytotechnology in Environmental Sanitation, 1(2), 83-89. | ||||
| Ibrahim, A. K., Hassan, B., & Muhammad, H (2021a). Effects of different land use types and soil depth on phosphorus forms status in selected areas in Gombe State. Nigerian Journal of Soil and Environmental Research, 20, 39-46. | ||||
| Ibrahim, A. K., Ibrahim, S. A., Voncir, N., & Hassan, A. M. (2018). Effects of Green Manuring and Nitrogen Levels on the Yield and Yield Attributes of Maize (Zea mays L.). Asian Journal of Soil Science and Plant Nutrition, 2(4), 1-11. Crossref |
||||
| Ibrahim, A. K., Muhammad, H., & Hassan, B. (2021b). Effects of different land use types and soil depth on selected soil physicochemical properties and nutrient status in selected areas in Gombe State. Nigerian Journal of Soil and Environmental Research, 20, 47-55. | ||||
| Ibrahim, A. K., Usman, A., & Girei, A. H. (2022). Effect of NPK fertilizer and agrolyser on growth, yield and yield components of maize in Northeastern Nigeria. Ife Journal of Agriculture, 34(2), 61-74. | ||||
| Ibrahim. A. K. Ibrahim, S. A., & Mustapha, S. (2010). Physico-chemical properties of Fadama Sols in Yamaltu-Deba, Gombe State. Journal of Research in Agriculture, 7(3), 1-5. | ||||
| Khaledian, Y., Kiani, F., Ebrahimi, S., Brevik, E. C., & AitkenheadāPeterson, J. (2017). Assessment and monitoring of soil degradation during land use change using multivariate analysis. Land Degradation & Development, 28(1), 128-141. Crossref |
||||
| Kiflu, A., & Beyene, S. (2013). Effects of different land use systems on selected soil properties in South Ethiopia. Journal of Soil Science and Environmental Management, 4(5) 100-107. Crossref |
||||
| Kuria, A. W., Barrios, E., Pagella, T., Muthuri, C. W., Mukuralinda, A., & Sinclair, F. L. (2019). Farmers' knowledge of soil quality indicators along a land degradation gradient in Rwanda. Geoderma regional, 16, e00199. Crossref |
||||
| Lal, R. (2013). Food security in a changing climate. Ecohydrology & Hydrobiology, 13(1), 8-21. Crossref |
||||
| Maniyunda, L. M. (2012). Pedogenesis of a Lithosequence in the Northern Guinea Savanna of Kaduna State, Nigeria. Ph.D. Dissertation. Ahmadu Bello University Zaria, Nigeria. | ||||
| Microsoft Excel Version (2013). Microsoft Cooperation. | ||||
| Mohammed, B. Y., Umar, J. A., & Mohammed, S. I. (2019). Assessment of soil degradation under agricultural land use sites: Emerging evidence from the Savanna Region of North Eastern Nigeria. Ghana Journal of Geography, 11(2), 243-263. | ||||
| Molchanov, E., Savin, I. Y., Yakovlev, A., Bulgakov, D., & Makarov, O. (2015). National approaches to evaluation of the degree of soil degradation. Eurasian Soil Science, 48(11), 1268-1277. Crossref |
||||
| Montpellier, P. (2013). Sustainable Intensification: A New Paradigm for African Agriculture. | ||||
| Nael, M., Khademi, H., & Hajabbasi, M. A. (2004). Response of soil quality indicators and their spatial variability to land degradation in central Iran. Applied Soil Ecology, 27(3), 221-232. Crossref |
||||
| Odunze, A. C. (1998). Soil management strategy under continuous rain fed-irrigation agriculture. Proceedings of the 12th National Irrigation and Drainage Seminar. Irrigation in sustainable Agriculture. 14 -16th April 1998, IAR, ABU, Zaria, Nigeria. Pp. 178-186. | ||||
| Oyedele, D. J., Awotoye O. O., & Popoola, S. E., (2009). Soil physical and chemical properties under continuous maize cultivation as influenced by hedgerow trees species on an alfisol in South- Western Nigeria. African Journal of Agricultural Research, 4 (7), 736-739. | ||||
| Raji, B. A. (1995). Pedogenesis of ancient dune soils in the Sokoto sedimentary basin, North-Western Nigeria. Un-published Ph.D. thesis, ABU Zaria, Nigeria. 194p. | ||||
| Rhoades, J. D. (1982). Cation exchange capacity. In: Page, A. L., Miller, R. H. & Keeney, D. R (eds.). Methods of Soil Analysis. Part 2 Agron 9. Madison WI. Pp. 149-157. Crossref |
||||
| Rowell, D., (1994). Soil science: Methods and applications. Longman Limited. England. 350p. | ||||
| Schloter, M., Dilly, O., & Munch, J. C. (2003). Indicators for evaluating soil quality. Agriculture, Ecosystems & Environment, 98(1-3), 255-262. Crossref |
||||
| Schoenholtz, S. H., Van Miegroet, H., & Burger, J. A. (2000). A review of chemical and physical properties as indicators of forest soil quality: challenges and opportunities. Forest ecology and management, 138(1-3), 335-356. Crossref |
||||
| Senjobi, B. A., & Ogunkunle, A. O. (2011). Effect of different land use types and their implications on land degradation and productivity in Ogun State, Nigeria. Journal of Agricultural Biotechnology and Sustainable Development, 3(1), 7-18. | ||||
| Snakin, V. V., Krechetov, P. P., Kuzovnikova, T. A., Alyabina, I. O., Gurov, A. F., & Stepichev, A. V. (1996). The system of assessment of soil degradation. Soil technology, 8(4), 331-343. Crossref |
||||
| Stevenson, F. J., & Cole, M.A. (1999). Cycles of soil. - 2nd ed., Wiley, NY, USA. | ||||
| Walkley, A., & Black, I. A. (1934). Determination of organic matter in soil. Soil Science 37, 549-556. Crossref |
||||
| Yusuf, M. B., Firuza B. M., & Khairulmaini, O.S. (2015). Survey of rill erosion characteristics of small-scale farmers' crop fields in the northern part of Taraba State, Nigeria. International Journal of Tropical Agriculture, 33(4), 3305-3313. | ||||
Copyright © 2025 Integrity Research Journals. All rights reserved.