Biomass production and resource partitioning in silvi-pastoral systems

Abstract

A randomized block design experiment involving factorial combinations of four fodder species : Pennisetum purpureum (hybrid napier), Brachiaria ruziziensis (congo signal), Panicum maximum (guinea grass) and Zea Mexicana (Teosinte) and four tree species (Leucaena leucocephala, Casuarina equisetifolia, Acacia auriculiformis and Ailanthus triphysa initiated in June 1988 was used for the present investigations. The study was pursued with the objective of quantifying the biomass production potential of selected forage species grown in association with tree components after canopy closure, comparing the productivity of different tree components grown in silvopastoral systems; characterizing the micro-site enrichment and nutrient cycling aspects of silvopastoral systems, analysis the partitioning of solar radiation among the different components of the system and elucidate influence regarding the nature of root interactions in silvopastoral systems.

The tree attributes such as biomass, height, DBH and crown diameter were in the order acasia > leucaena>casuarinas>ailanthus and the fodder biomasses were in the order hybrid napier> guinea grass > congo signal>teosinte. The concentration of N,P and K in the above ground portion decreased in the order: leaves >Branches >bole. The N-fixing trees, in general, had lower nutrient – use efficiencies. Amount of photosynthetically active radiation interception by the tree canopy was a cardinal factor effecting the herbage yield a direct correspondence was lacking. All the three N-fixing species had markedly higher soil nitrogen status. Soil organic matter, K and P were also higher under the tree canopy. Recovery pattern of 32p isotope injected in the soil revealed that 65 to 85 percent of the fine roots responsible for water and nutrient absorption were concentrated in the 0-15 cms layer of the soil profile. However, 32P recovery from the tree monocultures was generally low suggesting stimulatory effect of nutrient absorption by trees in presence of an associated field crop. The rate of litterfall amount of detritus produced ranged from 1.92 Mg ha-1 yr-1 (ailanthus) to 6.2 Mg ha-1 yr-1 (acacia). Relatively lower contents of nitrogen and phosphorus in the litter recorded during the dry period (March-April). Regarding the inter – specific variations with regards to litter decomposition rates, casuarina and leucaena litter decomposed at a faster rate than acacia and leucaena. The nitrogen and phosphorous contents of the decomposing litter increased during the one – year decay period for all the species. Although widely accepted and yield initial N, lignin or initial lignin/nitrogen could not be directly related to decay rate coefficients in the present study.