Effect of bamboo foliage on soil respiration, microbial biomass and N mineralization

Q4 Agricultural and Biological Sciences

Journal of Bamboo and Rattan Pub Date : 2004-04-01 DOI:10.1163/156915904774195160

K. Upadhyaya, A. Arunachalam, K. Arunachalam

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引用次数: 7

Abstract

Microbial N, CO2 evolution rate and mineral-N dynamics were determined in soils collected beneath the canopy of two different bamboo species in a 9-year-old bamboo forest developed on an abandoned sloping agricultural land in a humid tropical zone of north-east India. A laboratory incubation study was set up to determine the dynamics of microbial biomass, soil respiration and N mineralization rates as influenced by addition of bamboo residues (leaves and scale leaves). Soil nutrients and microbial biomass C, N and P were greater in soils under Bambusa pallida as compared to B. balcooa. Lignin and N concentrations were greater in B. balcooa. Scale leaves had low lignin and N concentrations than the leaf litter. The litter quality, particularly lignin/N, influenced the dynamics of soil mineral-N and, therefore, on the net N mineralization rate. CO2 evolution rate in the soil had a negative relationship with the N mineralization rate, while the microbial N showed weaker correlations with the dynamics of the mineral N. Overall, amendments using the sclerophyllous and slow decomposing foliage did not contribute to the increasing N mineralization in the soils. The study also suggests that soil management practices in bamboo forests should take into account incorporation of residues of good quality, probably of other plant species, failing which, soil quality may deteriorate over a long term that would be critical in productivity and nutrient cycling of secondary bamboo forests regenerating on nutrient-poor, fragile and marginal fallow agricultural lands.

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竹叶对土壤呼吸、微生物量和氮矿化的影响

在印度东北部潮湿热带地区的废弃坡耕地上，研究了9年历史的竹林中两种不同竹林树冠下的土壤微生物N、CO2演化速率和矿物N动态。通过室内培养研究，确定添加竹叶和鳞片叶对微生物生物量、土壤呼吸和氮矿化率的影响。竹林土壤养分和微生物生物量C、N、P均高于竹林土壤。木质素和氮浓度在balcoba中较高。鳞片叶的木质素和氮浓度低于凋落叶。凋落物质量，特别是木质素/氮，影响土壤矿物氮的动态，从而影响净氮矿化率。土壤中CO2演化速率与N矿化速率呈负相关，而微生物N与矿质N动态的相关性较弱。总体而言，利用硬叶和慢腐叶的修正对土壤中N矿化的增加没有贡献。该研究还建议，竹林的土壤管理实践应考虑纳入质量良好的残留物，可能是其他植物物种的残留物，否则，土壤质量可能在长期内恶化，这将对在营养贫乏、脆弱和边缘休耕农用地上再生的次生竹林的生产力和养分循环至关重要。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of Bamboo and Rattan Agricultural and Biological Sciences-Agronomy and Crop Science

CiteScore

0.40

自引率

0.00%

发文量

期刊介绍： The Journal of Bamboo and Rattan is a peer-reviewed scientific journal and provides a forum for scientific articles and reviews on all aspects of fast growing, multi-purpose pliable species. The scope of the journal encompasses income security, craft industry, small to medium size enterprises, industrial fibre and fuel. Articles related to natural distribution and conservation of species, genetics and biotechnology, harvesting and production systems, and environmental applications are also included, as well as papers on marketing and policy restraints in relation to bamboo, rattan and related species.