Patterns and drivers of tree carbon stocks in Kashmir Himalayan forests: implications for climate change mitigation

Background Temperate forests are major carbon sinks because of their high storage potential and low decomposition processes. We quantified tree carbon (TC) storage from 143 plots distributed across three major forest types of Kashmir Himalaya, relative to differences in ecological factors. Combined...

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Bibliographic Details
Published in:Ecological processes 2022-12, Vol.11 (1), p.1-13, Article 58
Main Authors: Dar, Ashaq Ahmad, Parthasarathy, Narayanaswamy
Format: Article
Language:English
Subjects:
Abies pindrow
Area
Bivariate analysis
Carbon
Carbon sequestration
Carbon sinks
Carbon stock
Climate change
Climate change mitigation
Coniferous forest
Distribution
Disturbance
Earth and Environmental Science
Elevation
Environment
Environmental factors
Forests
Kashmir Himalaya
Mitigation
Pinus wallichiana
Precipitation
Regression analysis
Regression models
Stand structure
Stocks
Storage
Temperate forests
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Summary:Background Temperate forests are major carbon sinks because of their high storage potential and low decomposition processes. We quantified tree carbon (TC) storage from 143 plots distributed across three major forest types of Kashmir Himalaya, relative to differences in ecological factors. Combined regression and Random Forest (RF) analysis were used to examine the distribution of TC stock along ecological gradients and recognize the role of driving factors on TC stocks. Results Among the three forest types, sub-alpine (SA) forest was the primary TC sink, accounting for 228.73 t ha −1  of carbon, followed by mixed conifer (MC; 181.29 t C ha −1 ) and blue pine (BP; 133.04 t C ha −1 ) forests. The distribution of TC stocks among the three forest types differed significantly ( χ 2  = 18.87; P  = 0.000). Relative carbon stock analysis demonstrated that Abies pindrow and Pinus wallichiana accounted 91% of TC stocks across the landscape. Basal area, mean diameter at breast height (DBH), elevation, disturbance and precipitation had significant effects on TC stocks in bivariate regression models. The RF model explained 86% of the variation; basal area interpreted 30.15%, followed by mean DBH (17.96%), disturbance complex (10.64%), precipitation (8.00%) and elevation (7.34%). Conclusions Kashmir Himalayan forests are significant carbon sinks as they store a substantial quantum of carbon in trees. Forest carbon, an essential climatic indicator, is determined by a complex interaction of other ecological variables, particularly stand structural features. The study provides insights into the role of these natural forests in climate change mitigation and in REDD+/national commitments to offset the carbon.
ISSN:2192-1709
2192-1709
DOI:10.1186/s13717-022-00402-z