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RESEARCH ARTICLE

Evaluation of lablab and velvet bean fallows in a maize production system for improved livestock feed supply in semiarid tropical Kenya

D. M. G. Njarui A C and J. G. Mureithi B
+ Author Affiliations
- Author Affiliations

A Kenya Agricultural Research Institute, Katumani Research Centre, PO Box 340, Machakos 90100, Kenya.

B Kenya Agricultural Research Institute, Headquarters, PO Box 57811, Nairobi 0200, Kenya.

C Corresponding author. Email: donaldnjarui@yahoo.com

Animal Production Science 50(3) 193-202 https://doi.org/10.1071/AN09137
Submitted: 14 October 2009  Accepted: 3 March 2010   Published: 8 April 2010

Abstract

The mixed crop–livestock farming systems of semiarid tropical Kenya are characterised by low livestock feed supply. The contribution of lablab and velvet bean to fodder production in a maize production system was investigated in the eastern region of Kenya. The experiment was run in three cycles, where each cycle consisted of a short legume fallow phase of ~6 months, followed by a maize-cropping phase. At the end of the fallow phase, the legume herbage was incorporated in soil at three levels; 0, 50 and 100% of total DM yield and maize planted. Maize yield from the legume fallow plots was compared with maize grown after natural fallow and maize top-dressed with 40 kg nitrogen/ha and nil nitrogen fertiliser. Overall, herbage DM yield was highest in velvet bean (3.9 t/ha) followed by lablab (3.4 t/ha) and lowest in natural fallow (2.2 t/ha). Mean crude protein from velvet bean was 13.5% of DM, which was significantly (P < 0.05) higher than that of lablab (8.4% of DM) and natural weedy fallow (3.5% of DM). Maize grain yield following lablab fallow was 38% (3569 kg/ha) and 27% (1810 kg/ha) in short rains (SR) 2002 and SR 2004, respectively, higher than maize succeeding natural fallow. However, maize planted after velvet bean fallow was 43% (3728 kg/ha) and 29.4% (1828 kg/ha) in SR 2002 and SR 2004, respectively, higher than in maize grown after natural fallow. Generally, the highest maize yield among the fallows was recorded in plots where legumes were incorporated in soil at 50% of total DM implying that the other 50% was available for livestock feed. Maize stovers DM yields were highest at the higher (100%) and middle (50%) level of legume incorporation, and yields were more than those from natural weedy fallow. Maize production under the legume fallow system was more profitable than from natural weedy fallows. It was concluded that if lablab and velvet bean are integrated in cropping systems as fallows, they can provide highly nutritious livestock feeds and improve maize yield and are recommended in the maize production systems within semiarid tropical Kenya.

Additional keywords: cost benefit analysis, legume fallows, maize yield, natural fallow.


Acknowledgements

This research was funded by the Rockefeller Foundation through the Legume Research Network Project of the Kenya Agricultural Research Institute and the support is gratefully acknowledged. The authors also gratefully acknowledge Mr Gatheru for statistical analysis.


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