Landscape‐Level Assessment of Topographic Influences on Organic Carbon Storage in Forests of Far Western Nepal

• Published in: Plant-environment interactions (Hoboken, N.J. : 2018) Vol. 6; no. 2; pp. e70039 - n/a
• Main Authors: GC, Santosh, Kafle, Gandhiv, Ayer, Santosh, Khamcha, Renuka, Poudel, Sandip, Prabhakar, Aman, Bhusal, Amrita, Lamichhane, Prakash, Airee, Janak, Sapkota, Terisa
• Format: Journal Article
• Language: English
• Published: United States John Wiley & Sons, Inc 01.04.2025; John Wiley and Sons Inc; Wiley
• Subjects: Carbon sequestration; Climate change; Climate change mitigation; Deforestation; Diameters; Emissions control; forest biomass; Forest degradation; Forests; Height; Organic carbon; Soils; Spatial distribution; Topography; Nepal; forest biomass; climate change mitigation; carbon sequestration; topography
• ISSN: 2575-6265; 2575-6265
• DOI: 10.1002/pei3.70039

ABSTRACT Carbon sequestration significantly aids in mitigating climate change, with its spatial distribution greatly influenced by topographical factors. However, data on organic carbon distribution and its interaction with topographic factors inside the forest of the Far Western Region of Nepal are limited. Therefore, this study aims to analyze forest carbon stock variation under different topographic variables (physiographic region, aspect, and slope) in Far‐western Nepal. In this study, stratified systematic cluster sampling was adopted with elevation, aspect, and slope as strata. A total of 181 circular plots were used for dendrometric measurements and soil sample collection. Within each plot, diameter at breast height and height of each tree (diameter at breast height ≥ 5 cm) were measured for biomass carbon assessment. Composite soil samples (0–30 cm) from each soil pit within a plot were collected for determining soil organic carbon stock. Physiographic region‐wise, our study reported the highest mean aboveground carbon (174.04 ± 29.75 ton ha−1) and belowground carbon (34.044 ± 5.95 ton ha−1) and soil organic carbon stock (150.62 ± 11.02 ton ha−1) in the Mountain and High Himal region. The East aspect exhibited the highest aboveground carbon (125.9 ± 22.34 ton ha−1) and belowground carbon (27.54 ± 3.44 ton ha−1) stocks, while the North aspect showed the highest soil organic carbon stock (96.85 ± 8.82 ton ha−1). Organic carbon stocks declined with steeper slopes, with the (0–10)° slope category recording the highest aboveground organic carbon (135.17 ± 17.87 ton ha−1), belowground carbon (27.03 ± 3.57 ton ha−1), and soil organic carbon (107.14 ± 12.51 ton ha−1) stocks. Conversely, the (30–40)° slope category exhibited the lowest organic carbon stocks across all pools. This study's findings will support accurate monitoring, reporting, and verification (MRV) processes for initiatives like reducing emissions from deforestation and forest degradation (REDD+) and enhance credibility on United National Framework Convention on Climate Change (UNFCCC) reporting on a national scale. The design and application of site‐specific management activities to optimize organic carbon storage are recommended due to the observed variability of organic carbon stock with topographic factors.