Vegetation diversity, structure, composition and carbon stock of community managed forests of Mid-hills, Nepal

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DOI https://doi.org/10.13057/asianjfor/r070104
Issue
Vol. 7 No. 1 (2023)
Section
Articles

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PADAM JOSHI
Department of Environmental Science, Amrit Campus, Tribhuvan University. Kathmandu 44600, Nepal
RAJEEV JOSHI
College of Natural Resource Management, Faculty of Forestry, Agriculture and Forestry University. Katari 56310, Udayapur, Nepal. 2. Amity Global Education (Lord Buddha College). CTEVT, Kathmandu-44600, Nepal.
RAMESH PRASAD SAPKOTA
Central Department of Environmental Science, Amrit Campus, Tribhuvan University. Kathmandu 44600, Nepal
MANOJ PANTA
School of Environmental Science and Management, Pokhara University. Kathmandu 44600, Nepal
PRIYANKA CHAND
Department of Environmental Science, Amrit Campus, Tribhuvan University. Kathmandu 44600, Nepal

Abstract

Abstract. Joshi P, Joshi R, Sapkota RP, Panta M, Chand P. 2023. Vegetation diversity, structure, composition and carbon stock of community managed forests of Mid-hills Nepal. Asian J For 7: 29-36. Depending on management practices, forests can serve as both carbon sinks and sources. The goal of reducing carbon emissions and increasing the carbon sink is thought to be feasible if carbon reservoirs in current forests are protected and conserved. This study was objectively conducted to assess the vegetation diversity, structure, and carbon stock of the Mid-hills of Nepal. The study was undertaken in the Lanta Community Forest, Jajarkot District, Nepal, which has an extent of 38.65 hectares. Data for vegetation analysis and carbon stock assessment were collected using systematic random sampling using quadrats of 10×10 m with a total number of 35 quadrats. Within each quadrat, individual trees and bamboo were identified in the sites, and their height (m) and DBH (cm) were measured. Density, frequency, basal area, and Important Value Index (IVI) were calculated as structural parameters of vegetation. The Above-Ground Tree Biomass (AGTB) and Below-Ground Tree Biomass (BGTB) were calculated using an allometric equation based on tree diameter, height, and wood-specific gravity. The species diversity, species richness, and evenness were found to be 2.2, 2.35, and 0.83, respectively. A total of 14 tree species, with 723 individuals and one bamboo species were recorded. Rhododendron arboreum Sm. had the highest tree density with 211 trees/ha, while Tsuga dumosa (D.Don) Eichler had the highest IVI. Total wood volume, biomass, and total carbon stock were estimated at 15.37 m3 ha-1, 31.99 t ha-1, and 15.03 t ha-1, respectively. There was a strong negative correlation (r = -0.59) between R. arboreum and R. campanulatum D. Don and a strong positive correlation (r = +0.65) between Malus sikkimensis and Machilus species. For the preservation and sustainable management of community forests, information regarding the structure, composition, and dominance of tree species is provided by the study. The establishment of community forests is thus demonstrated in this article as a means of promoting the protection and preservation of regional biodiversity.

2017-01-01

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