Biomass and its allocation in relation to temperature, precipitation, and soil nutrients in Inner Mongolia grasslands, China

Understanding and predicting ecosystem functioning such as biomass accumulation requires an accurate assessment of large-scale patterns of biomass distribution and partitioning in relation to climatic and soil environments. We sampled above- and belowground biomass from 26 sites spanning 1500 km in...

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Bibliographic Details
Published in:PloS one 2013-07, Vol.8 (7), p.e69561-e69561
Main Authors: Kang, Muyi, Dai, Cheng, Ji, Wenyao, Jiang, Yuan, Yuan, Zhiyou, Chen, Han Y H
Format: Article
Language:English
Subjects:
Annual precipitation
Biology
Biomass
Carbon
China
Climate
Climate change
Comparative analysis
Desert environments
Deserts
Earth Sciences
Ecology
Ecosystem
Ecosystems
Grasslands
Laboratories
Mean annual precipitation
Models, Statistical
Natural resources
Nitrogen
Nutrients
Organic carbon
Organic soils
Partitioning
Plant production
Plant Roots - physiology
Poaceae - physiology
Precipitation
Predictions
Rain
Rainfall
Sampling methods
Science
Soil - chemistry
Soil carbon
Soil nutrients
Soil temperature
Soils
Steppes
Studies
Temperature
Terrestrial ecosystems
Water
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Summary:Understanding and predicting ecosystem functioning such as biomass accumulation requires an accurate assessment of large-scale patterns of biomass distribution and partitioning in relation to climatic and soil environments. We sampled above- and belowground biomass from 26 sites spanning 1500 km in Inner Mongolian grasslands, compared the difference in aboveground, belowground biomass and below-aboveground biomass ratio (AGB, BGB, and B/A, respectively) among meadow steppe, typical steppe, and desert steppe types. The relationships between AGB, BGB, B/A and climatic and soil environments were then examined. We found that AGB and BGB differed significantly among three types of grasslands while B/A did not differ. Structural equation model analyses indicated that mean annual precipitation was the strongest positive driver for AGB and BGB. AGB was also positively associated with soil organic carbon, whereas B/A was positively associated with total soil nitrogen. These results indicated that precipitation positively influence plant production in Inner Mongolian grasslands. Contrary to the prediction from the optimal partitioning hypothesis, biomass allocation to belowground increased with soil total nitrogen, suggesting that more productive sites may increase belowground allocation as an adaptive strategy to potentially high fire frequencies.
ISSN:1932-6203
1932-6203
DOI:10.1371/journal.pone.0069561