NUTRIENT STATUS AND MANAGEMENT OF SOME HYDROMORPHIC SOILS IN RIVERS STATE, NIGERIA FOR SUSTAINABLE CROP PRODUCTION

PDF

Published: 2021-12-28

Page: 1459-1468


P. O. ABAM *

Department of Crop and Soil Science, Faculty of Agriculture, University of Port Harcourt, P.M.B. 5323 Port Harcourt, Rivers State, Nigeria.

J. A. CHUKWUMATI

Department of Crop and Soil Science, Faculty of Agriculture, University of Port Harcourt, P.M.B. 5323 Port Harcourt, Rivers State, Nigeria.

*Author to whom correspondence should be addressed.


Abstract

Nutrient status of some hydromorphic soils in Rivers State were studied for their potentials and probable constraints to crop production. A total of one hundred and twenty surface (0-15 cm) and sub-surface (15-30 cm depth) soil samples obtained from ten locations were subjected to routine laboratory and statistical analysis using standard methods. Random sampling technique was employed in the collection of soil samples. Results revealed that the sand component of the soils which ranged from 117 g/kg to 891 g/kg decreased with increased soil depth. The clay and silt fractions ranged from 24 g/kg to 231 g/kg and 28 g/kg to 701 g/kg respectively. The highest sand content was obtained at 0 – 15 cm topsoil. The results showed that nutrient status of some of the soils were low as revealed by their estimated levels of availability. The soils were acidic in reaction. Mean pH values were 4.2 in the surface soils and 3.7 in the subsurface soils. Total nitrogen, calcium, sodium and electrical conductivity were all less than the critical levels in soils but moderate to high in organic matter, available phosphorus, exchangeable potassium, base saturation and micronutrient (Fe and Mn). The main constraints of these soils to sustainable crop production were therefore, the low chemical fertility (high acidity, low exchangeable Calcium and Nitrogen concentrations). However, short season crops (vegetables) can be grown at subsistence level. Ordinarily, fertilizer and lime could be recommended as measures to increase yield of crops, but these inputs are both unaffordable and unavailable at critical periods. Therefore, the farmers are encouraged to harness cheap resources found on the farms such as mulch and bio-fertilizers, to improve soil nutrient status rather than rely on inputs that are normally not accessible.

Keywords: Nutrient status, Five striped palm squirrels, testes, hydromorphic soils, spermatogenic activity, sustainable crop production, breeding seasons


How to Cite

ABAM, P. O., & CHUKWUMATI, J. A. (2021). NUTRIENT STATUS AND MANAGEMENT OF SOME HYDROMORPHIC SOILS IN RIVERS STATE, NIGERIA FOR SUSTAINABLE CROP PRODUCTION. Asian Journal of Advances in Research, 4(1), 1459–1468. Retrieved from https://jasianresearch.com/index.php/AJOAIR/article/view/11

Downloads

Download data is not yet available.

References

Aghimien AE. The chemistry and fertility status of hydromorphic soils supporting raphia palms (Raphia spp) in Southern Nigeria. Ph.D Thesis, University of Ibadan, Ibadan Nigeria; 1982.

Ogban PI, Babalola O. Characteristics of hydromorphic soils from South Western Nigeria. African Soils. 1994;28:142-165.

Imogie AE, Udosen CV, Ugbah MM. Fertility indices and management of hydromorphic soils supporting raphia palms (Raphia hookeri, Mann and Wendland) Plantation at Onuebum, Bayelsa State, Nigeria. Continental J. Agronomy. 2008;2:19-24.

Esu IE. Soil characterization and mapping for food security and sustainable environment in Nigeria. Proceedings of the 29th annual conference of the soil Science Society of Nigeria. 5-9th Nov. 2001, Calabar, Nigeria; 2004.

Guthrie RL. Characterizing and Classifying wetland soils in relation to food production. Wetland Soils: Characterization Classification and Utilization. IRRI, Los Banos, Philippines; 1986.

Eshett ET. The wetlands of Nigeria. Distribution, characterization and traditional land use practices. Paper delivered at the 21st Annual conference of the Soil Science society of Nigeria, University of Uyo; 1994.

Otedoh MO. Raphia palm and other wine producing palms in Nigeria J. Niger. Institute for Oil Palm Res. 1981;6(21):92-99.

Okusami TA, Rust RH. Occurrence, characteristics and classification of some hydromorphic soils from south Nigeria. In J. M. Kimble (ed) Characterization, Classification and Utilization of Wet Soils. Proc. VIII ISCOM. USDA, Soil Conserv. Service, National Soil Survey Centre, Lincoln, NE. 1992;185-197.

Reddy KL, Patrick Jr., WH. Wetland Soils: Opportunities and Challenges. A Guest Editorial. Soil Sci. Soc. Am. J. 1993;57:1145-1147.

Ogban PI, Babalola O. Soil characteristics and constraints to crop production in inland valley bottoms in southwestern Nigeria. Agric. Water Management. 2003;61:13-28.

Ogban PI, Babalola O. Characteristics, classification, and management of inland valley bottom soils for crop production in sub-humid southwestern Nigeria. Agro-Sci. J. Trop. Agric., Food, Environment and Extension. 2009;8(1):1-13.

Fagbami AA. Extent of marginal lands in Nigeria. A lead paper, 23rd Annual Conf. Soil Sci. Soc. Nig., Usman Danfodiyo Univ., Sokoto, Nig. 2nd-5th March, 1997; 1994.

Udo EJ, Ibia TO, Ogunwale JA. Ano AO, Esu IE. Manual of soil, plant and water analysis. Sibon books Ltd, Lagos, Nigeria. 2009; 183.

Praveen Sarojam. Analysis of micronutrients in soil by using AA 800 Atomic Absorption Spectrophotometer; 2009.

Wilding LP, Dress LR. Spatial variability. A pedologist view point. In: Diversity of soils in the tropics. As a special publ.1-12 Am. Soc. Agron, Madison, Wisconsin; 1978.

Ogunwale JA, Dixon JB. Chemical and mineralogical properties of Nigerian soils, derived from feldspathic sandstone. Nigeria J. Sci. 1979;133-146.

Kyuma K. Fundamental characteristics of wetland soils. International workshop on wetlands: Characterization, classification and utilization. IRRI. Los Banos Philippines; 1986.

FPDD. Literatrure on soil fertility mitigation in Nigeria. Produced by the Federal Ministry of Agriculture and Natural Resources, Lagos; 1989.

FAO. A framework for land evaluation. Soils bulletin 32 FAO, Rome. 1976;79.

Slavich PG, Peterson GH. Estimating the critical conductivity of saturated paste extracts from 1:5 soil: water suspensions and texture. Australian journal of Soil Research. 1993;73-81.

Genon JG, Hepcee Nd, Duffy JE, Delvaux B, Hennebert PA. Iron toxicity and other chemical soil constraints to rice in high land swamps of Burundi. Plant Soil. 1994;166:109-115.

Nelson DW, Sommers LC. Total carbon, organic carbon and organic matter in Sparks D.L (ed). Methods of Soil Analysis Part 3, chemical method SSA, Madison W USA. 1996;539-579.

Olsen SR, Sommer LE. Determination of available phosphorus on methods of soil analysis part. Chemical and Microbiological Properties Agronomy Monograph NO.9 2nd edition; 1982.