Species richness is a strong driver of forest biomass along broad bioclimatic gradients in the Himalayas

Species richness is a strong driver of forest biomass along broad bioclimatic gradients in the Himalayas

Forest biomass is an important component of terrestrial carbon pools. However, how climate, biodiversity, and structural attributes co‐determine spatiotemporal variation in forest biomass remains not well known. We aimed to shed light on these drivers of forest biomass by measuring diversity and str...

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Published in:Ecosphere (Washington, D.C) Vol. 13; no. 6
Main Authors: Dyola, Nita, Sigdel, Shalik Ram, Liang, Eryuan, Babst, Flurin, Camarero, J. Julio, Aryal, Sugam, Chettri, Nakul, Gao, Shan, Lu, Xiaoming, Sun, Jian, Wang, Tao, Zhang, Gengxin, Zhu, Haifeng, Piao, Shilong, Peñuelas, Josep
Format: Journal Article
Language:English
Published: Hoboken, USA John Wiley & Sons, Inc 01-06-2022
Wiley
Subjects:
Air temperature
alpine treeline
Bioclimatology
Biodiversity
Biomass
Carbon
Carbon sinks
climate
Climate change
Climate change mitigation
Community composition
diversity
elevation
Evapotranspiration
Forest biomass
Forests
Plant species
potential evapotranspiration
Precipitation
Species richness
Terrestrial environments
tropical forest
Vegetation
Water availability
Water demand
Wind
Himalaya Mountains
Kangchenjunga
Nepal
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Summary:Forest biomass is an important component of terrestrial carbon pools. However, how climate, biodiversity, and structural attributes co‐determine spatiotemporal variation in forest biomass remains not well known. We aimed to shed light on these drivers of forest biomass by measuring diversity and structural attributes of tree species in 400‐m2 plots located every 100 m along a 4200‐m elevational gradient in the eastern Himalayas. We applied structural equation models to test how climate, species richness, structural attributes, and their interactions influence forest biomass. Importantly, species richness was a stronger driver of biomass than environmental and structural attributes such as annual air temperature or stem density. Integrating the availability of energy and the demand for water, potential evapotranspiration was more strongly correlated with biomass than water availability, likely due to the strong influence of the Indian summer monsoon. Thus, interactions between climate and tree community composition ultimately control how much carbon is stored in woody biomass across bioclimatic gradients. This fundamental understanding will support predictive efforts of the forest carbon sink in this hydroclimatically important region and help preserving regional forests as a potent natural solution for climate change mitigation.
ISSN:2150-8925
2150-8925
DOI:10.1002/ecs2.4107