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ENHANCING MAIZE PRODUCTIVITY AND PROFITABILITY USING ORGANIC INPUTS AND MINERAL FERTILIZER IN CENTRAL KENYA SMALL-HOLD FARMS

Published online by Cambridge University Press:  12 September 2013

MONICAH MUCHERU-MUNA ,
DANIEL MUGENDI ,
PIETER PYPERS ,
JAYNE MUGWE ,
JAMES KUNG'U ,
BERNARD VANLAUWE  and
ROEL MERCKX
MONICAH MUCHERU-MUNA*
Affiliation:
Kenyatta University, PO Box 43844-00100, Nairobi, Kenya
DANIEL MUGENDI
Affiliation:
Embu University College PO Box 6-60100, Embu, Kenya
PIETER PYPERS
Affiliation:
Tropical Soil Biology and Fertility (TSBF) Institute of CIAT, PO Box 30677, Nairobi, Kenya
JAYNE MUGWE
Affiliation:
Kenyatta University, PO Box 43844-00100, Nairobi, Kenya
JAMES KUNG'U
Affiliation:
Kenyatta University, PO Box 43844-00100, Nairobi, Kenya
BERNARD VANLAUWE
Affiliation:
International Institute for Tropical Agriculture, PO Box 823-00621, Nairobi, Kenya
ROEL MERCKX
Affiliation:
Laboratory for Soil and Water Management, Faculty of Bioscience Engineering, KU Leuven, Kasteelpark Arenberg 20, 3001 Heverlee, Belgium
*
Corresponding author. Email: [email protected]
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Summary

Declining land productivity is a major problem facing smallholder farmers today in Sub-Saharan Africa, and as a result increase in maize grain yield has historically staggered behind yield gains that have been achieved elsewhere in the world. This decline primarily results from reduction in soil fertility caused by continuous cultivation without adequate addition of external nutrient inputs. Improved soil fertility management practices, which combine organic and mineral fertilizer inputs, can enable efficient use of inputs applied, and can increase overall system's productivity. The trials were established at two sites with different soil fertility status to determine the effects of various organic sources (Tithonia diversifolia, Mucuna pruriens, Calliandra calothyrsus and cattle manure) and their combinations with mineral fertilizer on maize grain yield, economic return and soil chemical properties. Drought spells were common during the peak water requirement periods, and during all the seasons most (90%) of the rainfall was received before 50% flowering. In good and poor sites, there was a significant (p < 0.001) effect of season on maize grain yield. Tithonia diversifolia recorded the highest (4.2 t ha−1) average maize grain yield in the poor site, while Calliandra calothyrsus gave the highest (4.8 t ha−1) average maize grain yield in the good site. Maize grain yields were lower in treatments with sole fertilizer compared with treatments that included organic fertilizers. The maize grain yields were higher with sole organics compared with treatments integrating organic and inorganic fertilizers. Soil pH increment was statistically significant in the sole manure treatment in good and poor sites (t-test, p = 0.036 and 0.013), respectively. In the poor site, magnesium increased significantly in the sole manure and manure + 30 kg N ha−1 treatments with t-test p = 0.006 and 0.027, respectively. Soil potassium was significant in the sole manure treatment (t-test, p = 0.03). Generally the economic returns were low, with negative net benefits and benefit cost ratio of less than 1. Inorganic fertilizer recorded the highest net benefit and return to labour (p < 0.001 and <0.01, respectively) in the good site. The treatments that had very high maize grain yields did not lead to improved soil fertility, thus there is need for tradeoffs between yield gains and soil fertility management when selecting agricultural production technologies.

Type
Research Article
Information
Experimental Agriculture , Volume 50 , Issue 2 , April 2014 , pp. 250 - 269
Copyright
Copyright © Cambridge University Press 2013 

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References

REFERENCES

Anderson, J. M. and Ingram, J. S. L. (1993). Tropical Soil Biology and Fertility: A Handbook of Methods. Wallingford, UK: CAB.Google Scholar
Balarios, J. and Edmeades, G. O. (1993). Eight cycles of selection for drought tolerant in lowland tropical maize 11. Responses in reproductive behavior. Field Crops Research 31:253268.Google Scholar
Bationo, A. and Waswa, B. S. (2011). New challenges and opportunities for integrated soil fertility management in Africa. In Innovation as Key to the Green Revolution in Africa. Exploring the Scientific Facts, Vol 1 (Eds Bationo, A., Waswa, B., Okeyo, J. M., Maina, F. and Kihara, J.). New York, NY: Springer.CrossRefGoogle Scholar
Bationo, A., Waswa, B., Kihara, J. and Kimetu, J. (2007). Advances in Integrated Soil Fertility Management in Sub-Saharan Africa: Challenges and Opportunities. Dordrecht, Netherlands: Springer.Google Scholar
Bayu, W., Rethman, N. F. G. and Hammes, P. S. (2005). The role of manure in sustainable soil fertility management in Sub-Saharan Africa. Journal of Sustainable Agriculture 25:113136.Google Scholar
Blair, G. J. and Boland, O. W. (1978). The release of P from plant material added to soil. Australian Journal of Soil Research 16:101111.CrossRefGoogle Scholar
Brady, N. C. (1990). The Nature and Properties of Soils, 3rd edn.London: Macmillan.Google Scholar
Chakravarty, S. (1987). Cost-benefit analysis. In The New Palgrave: A Dictionary of Economics, Vol. 1, 687690 (Eds Eatwell, J., Milgate, M. and Newman, P.). Hampshire, UK: Palgrave Macmillan.Google Scholar
Donovan, G. and Casey, F. (1998). Soil Fertility Management in Sub-Saharan Africa. World Bank Technical Paper 408. Washington, DC: World Bank.Google Scholar
Drinkwater, L. E., Letourneau, D. K., Workneh, F., van Bruggen, A. H. C. and Shennan, C. (1995). Fundamental difference between conventional and organic tomato agroecosystems in California. Ecology Applications 5:10981112.Google Scholar
Eghball, B. (2002). Soil properties as influenced by phosphorus and nitrogen based manure and compost applications. Agronomy Journal 94:128135.Google Scholar
Eghball, B. and Power, J. F. (1999). Phosphorus and nitrogen-based manure and compost application: corn production and soil phosphorus. Soil Science Society of America Journal 63:895901.Google Scholar
Feller, C. and Beare, M. H. (1997). Physical control of organic matter dynamics in the tropics. Georderma 79:69116.Google Scholar
Fertilizer Use Recommendation Project (FURP). (1987). Description of First Priority Trial Site in Various Districts. Final Report. Vol. 24. Embu District. Nairobi, Kenya: National Agricultural Research Laboratories.Google Scholar
Gachene, C. K. K., Palm, C. A. and Mureithi, J. G. (1999). Legume Cover Crops for Soil Fertility Improvement in the East African Region. Report of AHI Workshop held at TSBF, Nairobi, Kenya, 18–19 February 1999.Google Scholar
Gachengo, C. (1996). Phosphorus Release and Availability on Addition of Organic Materials to Phosphorus Fixing Soils. MPhil Thesis, Moi University, Eldoret, Kenya.Google Scholar
Gachengo, C. N., Palm, C. A., Jama, B. and Otieno, C. (1999). Tithonia and senna green manures and inorganic fertilizers as phosphorus sources for maize in Western Kenya. Agroforestry Systems 44:2126.CrossRefGoogle Scholar
Gao, G. and Chang, C. (1996). Changes in CEC and particle size distribution of soils associated with long-term annual application of cattle feed lot manure. Soil Science Journal 161:115120.Google Scholar
Genstat. (2005). Genstat Release 8.1 for Windows. Hertfordshire, UK: Lawes Agricultural Trust, Rothamstead Experimental Station.Google Scholar
George, T. S., Gregory, P. J., Robinson, J. S., Buresh, R. J. and Jama, B. A. (2001). Tithonia diversifolia: variations in leaf nutrient concentration and implications for biomass transfer. Agroforestry Systems 52:199205.Google Scholar
Giller, K. E., Rowe, C., de Ridder, C. and van Keulen, H. (2006). Resource use dynamics and interactions in the tropics: scaling up in space and time. Agricultural Systems 88:827.Google Scholar
Gitari, J. N., Karumba, S., Gichovi, M. and Mwaniki, K. (1998). Integrated Nutrient Management Studies at Embu site. In Legume Research Network Project Annual Report, Issue No. 4, 7–10 (Ed Mureithi, J. G.).Google Scholar
Government of Kenya (2001). The 1999 Kenya National Census Results. Nairobi, Kenya: Ministry of Home Affairs.Google Scholar
Hue, N. V. (1992). Correcting soil acidity of a highly weathered Ultisol with chicken manure and sewage sludge. Communication in Soil Science Plant Analysis 23:241264.Google Scholar
Hue, N. V. and Amien, I. (1989). Aluminum detoxification with green manures. Communication in Soil Science and Plant Journal 20:14991511.Google Scholar
Hunter, D. J., Yapa, L. G. G. and Hue, N. V. (1997). Effects of green manure and coral lime on corn growth and chemical properties of an acid Oxisol in Western Samoa. Biology and Fertility of Soils 24:266273.Google Scholar
Jaetzold, R., Schmidt, H., Hornet, Z. B. and Shisanya, C. A. (2006). Farm Management Handbook of Kenya. Natural Conditions and Farm Information (Eastern Province), Vol 11/C, 2nd edn.Nairobi, Kenya: Ministry of agriculture/GTZ.Google Scholar
Jama, B. A., Buresh, R. J., Ndufa, J. K. and Shepherd, K. D. (1997). Agronomic and economic evaluation of organic and inorganic sources of phosphorus in western Kenya. Agronomy Journal 89:597604.CrossRefGoogle Scholar
Jama, B., Palm, C. A., Buresh, R. J., Niang, A., Gachengo, C., Nziguheba, G. and Amadalo, B. (2000). Tithonia diversifolia as a green manure for soil fertility improvement in western Kenya: a review. Agroforestry Systems 49:201221.Google Scholar
Jiri, O. and Waddington, S. R. (1998). Leaf prunings from two species of Tithonia diversifolia raise maize grain yield in Zimbabwe, but take a lot of labor. Target (Newsletter of Soil Fertility Network, Harare, Zimbabwe) 16, 4–5.Google Scholar
Kang, B. T. (1993). Alley cropping: past achievements and future directs. Agroforestry Systems 23:141155.Google Scholar
Kapkiyai, J. J., Karanja, N. K., Woomer, P. and Qureshi, J. N. (1998). Soil organic carbon fractions in a long-term experiment and the potential for their use as a diagnostic assays in highland farming systems of central Kenya. African Crop Science Journal 6:1928.CrossRefGoogle Scholar
Kihanda, F. M. (1996). The Role of Farmyard Manure in Improving Maize Production in the Sub-Humid Central Highlands of Central Kenya. PhD thesis, The University of Reading, UK.Google Scholar
Kihanda, F. M., Warren, G. P. and Micheni, A. N. (2006). Effect of manure application on crop yield and soil chemical properties in a long-term field trial of semi-arid Kenya. Nutrient Cycling in Agroecosystems 76:341354.Google Scholar
Kimani, S. K., Macharia, J. M., Gachengo, C., Palm, C. A. and Delve, R. J. (2004). Maize production in the central highlands of Kenya using cattle manures combined with modest amounts of mineral fertilizer. Uganda Journal of Agricultural Sciences 9:480490.Google Scholar
Kimetu, J. M., Mugendi, D. N., Palm, C. A., Mutuo, P. K., Gachengo, C. N., Bationo, A., Nandwa, S. and Kung'u, J. B. (2004). Nitrogen fertilizer equivalencies of organics of differing quality and optimum combination with inorganic nitrogen source in central Kenya. Nutrient Cycling in Agroecosystems 68:127135.Google Scholar
Landon, J. R. (1991). Booker Tropical Soil Manual: A Handbook of Soil Survey and Agricultural and Evaluation in the Tropics and Sub-Tropics. Harlow, UK: Booker Tate Essex, Longman.Google Scholar
Mafongoya, P. L., Giller, K. E. and Palm, C. A. (1998). Decomposition and nitrogen release patterns of tree prunings and litter. Agroforestry Systems 38:7797.CrossRefGoogle Scholar
McCann, J. C. (2005). Africa and the world ecology of maize. In Maize and Grace: Africa's Encounter with a New World Crop, 1500–2000, 122. Cambridge, MA: Harvard University Press.Google Scholar
Mtambanengwe, F., Mapfumo, P. and Vanlauwe, B. (2006). Comparative short-term effects of different quality organic resources on maize productivity under two different environments in Zimbabwe. Nutrient Cycling in Agroecosystems 76:271284.CrossRefGoogle Scholar
Mucheru-Muna, M. W., Mugendi, D., Kungu, J., Mugwe, J. and Bationo, A. (2007). Effects of organic and mineral fertilizer inputs on maize yield and soil chemical properties in a maize cropping system in Meru South District, Kenya. Agroforestry Systems 69:189197.CrossRefGoogle Scholar
Mugendi, D. N., Nair, P. K. R., Mugwe, J. N., O'Neill, M. K. and Woomer, P. L. (1999). Calliandra and Leucaena alley cropped with maize. Part 1: soil fertility changes and maize production in the sub-humid highlands of Kenya. Agroforestry Systems 46:3950.Google Scholar
Mugwe, J., Mugendi, D. N., Mucheru, M. and Kung'u, J. (2003). Adoption potential of soil replenishment resources: feasibility and acceptibility of leguminous plants and other organic resources for soil fertility improvement in Meru South District, Kenya. In African Crop Science Conference Proceedings, Vol. 6, 424429 (Eds Namplala, M. P., Tenywa, J. S., Mwangombe, A. W., Osiru, M., Kawuki, R. and Biruma, M.). El-Minia, Egypt: African Crop Science Society.Google Scholar
Mugwe, J., Mugendi, D., Mucheru-Muna, M., Merckx, R., Chianu, J. and Vanlauwe, B. (2009). Determinants of the decesion to adopt integrated soil fertility management practices by smallholder farmers in the Central highlands of Kenya. Experimental Agriculture 45:6175.Google Scholar
Murwira, H. K., Mutuo, P. K., Nhamo, N., Marandu, A. E., Rabeson, R., Mwale, M. and Palm, C. A. (2002). Fertilizer equivalency values of organic materials of different quality. In Integrated Plant Nutrients Management in Sub-Saharan Africa: From Concept to Practice, 113152 (Eds Vanlauwe, B., Diels, J., Sanginga, N. and Merckx, R.). Wallingford, UK: CAB International.Google Scholar
Murwira, H. K., Swift, M. J. and Frost, P. G. H. (1995). Manure as a key resource in sustainable agriculture. In Livestock and Sustainable Nutrient Cycling in Mixed Farming Systems of Sub-Saharan Africa, Vol. II, 131148 (Eds Powell, L. M., Fernandez-Rivera, S., Williams, O. T. and Renard, C.). Technical papers, Proceeding of the International Conference held in Addis Ababa, Ethiopia, 22–26 November 1993. Addis Ababa, Ethiopia: International Livestock Centre for Africa.Google Scholar
Mutuo, P. K., Mukalama, J. P. and Agunda, J. (2000). On-farm testing of organic and inorganic phosphorous source on maize in western Kenya. The Biology and Fertility of Tropical Soils, TSBF Report, 22 pp.Google Scholar
Mwangi, J. N., Mugendi, D. N. and O'Neill, K. M. (1998). Crop yield response to incorporation of leaf prunnings in sole and alley cropping systems. East Africa Agricultural Journal 62:209218.Google Scholar
Nziguheba, G. and Mutuo, P. K. (2000). Integration of Tithonia diversifolia and inorganic fertilizer for maize production. In The Biology and Fertility of Tropical Soils, TSBF Report, 23 pp.Google Scholar
Nziguheba, G., Palm, C. A., Buresh, R. J. and Smithson, P. C. (2000). Soil phosphorus fractions and adsorption as affected by organic and inorganic sources. In The Biology and Fertility of Tropical Soils, TSBF Report, 22 pp.Google Scholar
Palm, C. A., Gachengo, C. N., Delve, R. J., Cadish, G. and Giller, K. E. (2001). Organic inputs for soil fertility management in tropical agroecosystems application of an organic resource data base. Agriculture, Ecosystems and Environment 83:2742.CrossRefGoogle Scholar
Palm, C. A., Myers, R. J. K. and Nandwa, S. M. (1997). Organic-inorganic nutrient interactions in soil fertility replenishment. In, Replenishing Soil Fertility in Africa. Soil Science Society of America Special Publication, Vol. 51, 193218, (Eds Buresh, R. J., Sanchez, P. A. and Calhoun, F.). Madison WI: Soil Science Society of America.Google Scholar
Palm, C. A., Nziguheba, G., Gachengo, C., Gacheru, E. and Rao, M. R. (1999). Organic materials as sources of phosphorus. Agroforestry Forum 9 (4):3033.Google Scholar
Pocknee, S. and Summer, M. E. (1994). The role of organic matter in soil acidity amelioration. In Agronomy Abstract. University of Wisconsin, Madison, WI: American Society of Agronomy, 260 pp.Google Scholar
Probert, M. E., Okalebo, J. R. and Jones, R. K. (1995).The use of manure on smallholders’ farm in semi-arid eastern Kenya. Experimental Agriculture 31:371381.Google Scholar
Sanginga, N. and Woomer, P. L. (Eds) (2009). Integrated Soil Fertility Management in Africa: Principles, Practices and Development Process. Nairobi, Kenya: Tropical Soil Biology and Fertility Institute of the Centre for Tropical Agriculture, 263 pp.Google Scholar
Saviozzi, A., Biasci, A., Riffaldi, R. and Levi-Minzi, R. (1999). Long-term effects of farmyard manure and sewage sludge on some soil biochemical characteristics. Biology and Fertility of Soils 30:100106.CrossRefGoogle Scholar
Schlegel, A. T. (1992). Effect of composted manure on soil chemical properties and nitrogen use by grain sorghum. Journal of Productive Agriculture 5:153157.CrossRefGoogle Scholar
Six, J., Elliot, E. T. and Paustin, K. (2000). Soil structure and organic matter I. Distribution of aggregate-size classes and aggregate associated carbon. Soil Science Society of American Journal 64:681689.Google Scholar
Smaling, E. M. A. (1993). Soil nutrient depletion in Sub-Saharan Africa. In The Role of Plant Nutrients for Sustainable Food Crop Production in Sub- Saharan Africa, 47–61 (Eds Van Reuler, H. and Prins, W.). Leidschendam, Netherlands: VKP.Google Scholar
Teklay, T. (2005). Organic Inputs from Agroforestry Trees on Farms for Improving Soil Quality and Crop Productivity in Ethiopia. Umea, Sweden: Faculty of Forest Sciences, Department of Forest Ecology.Google Scholar
Telalign, T., Haque, I. and Aduayi, E. A. (1991). Soil, Plant, Water, Fertilizer, Animal Manure and Compost Analysis Manual. Plant Science Division Working Document, 13. Addis Ababa, Ethiopia: ILCA.Google Scholar
Tisdale, S. L., Nelson, W. L., Beaton, J. D. and Havlin, J. L. (1993). Soil Fertility and Fertilizers, 5th edn.New York, NY: Macmillan.Google Scholar
Tittonell, P., Corbeels, M. and van Wijk, M. T. (2008). Combining organic and mineral fertilizers for integrated soil fertility management in smallholder farming systems of Kenya: explorations using the crop-soil model FIELD. Agronomy Journal 100:15111526.Google Scholar
Vanlauwe, B., Bationo, A., Chianu, J., Giller, K. E., Merckx, R., Mokwunye, U., Ohiokpehai, O., Pypers, P., Tabo, R., Shepherd, K. D., Smaling, E. M. A., Woomer, P. L. and Sanginga, N. (2010a). Integrated soil fertility management. Operational definition and consequences for implementation and dissemination. Outlook on Agriculture 39:1724CrossRefGoogle Scholar
Vanlauwe, B. and Giller, K. E. (2006). Popular myths around soil fertility management in Sub-Saharan Africa. Agriculture, Ecosystems and Environment 116:3446.Google Scholar
Vanlauwe, B., Kihara, J., Chivenge, P., Pypers, P., Coe, R. and Six, J. (2010b). Agronomic use efficiency of N fertilizer in maize-based systems in Sub-Saharan Africa within the context of integrated soil fertility management. Plant Soil 339:3550.Google Scholar
Werner, M. W. (1997). Soil quality characteristics during conversion to organic orchard management. Applied Soil Ecology 5:151167.Google Scholar