Potential of mango (Mangifera indica L.) plantations in carbon detention and ecosystem services.

IF 8.4 4区环境科学与生态学 Q2 ENVIRONMENTAL SCIENCES

Integrated Environmental Assessment and Management Pub Date : 2025-09-01 DOI:10.1093/inteam/vjaf045

Ajaya Kumar Trivedi, Ghanshyam Pandey, Sushil Kumar Shukla, Jay Narayan Tiwari, Achal Singh

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Abstract

Fruit tree plantations have a pivotal role in regulating the microclimate and physical environment of a region. Contribution of forestry species in carbon sequestration and as carbon sinks has been well documented. However, meager attention has been paid to reveal the contribution of fruit tree species. Mango (Mangifera indica L.) is an important fruit tree crop of tropical and subtropical regions of the world, grown in more than 100 countries. With an annual production of 20,946 thousand metric tons (MT), a 2,371 thousand ha area is under mango cultivation in India alone. To assess the carbon detention potential of mango trees, 35-year-old, uniform trees were selected. The circumference of trees in the study was found to vary from 1.43 to 1.96 m, diameter below graft union varied from 0.44 to 0.68 m, tree height varied from 9.45 to 11.13 m, above-ground weight of trees ranged from 1,489.44 to 3,788.56 kg/tree, total weight of trees varied from 1,787.32 to 4,546.27 kg/tree, and total dry weight of trees varied from 1,295.81 to 3,296.05 kg/tree. Magnitude of carbon dioxide sequestered by mango trees was estimated to be 660.98-3,838.96 kg/tree. Annual carbon sequestration potential of an individual mango tree was found to vary from 30.78 to 78.30 kg/tree with an average of 50.55 kg/tree. Mango plantations are crucial for fruit production, ecosystem services, and sustainability of the region. Hence, monitoring and estimation of carbon detention and interaction with the farmers was done simultaneously. The study signifies the fundamental role of mango trees in the mitigation of adverse impact of climate change through carbon detention and vital impact on ecosystem services.

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芒果人工林在碳滞留和生态系统服务中的潜力

果树人工林在调节地区小气候和自然环境方面具有重要作用。森林物种在固碳和作为碳汇方面的贡献已得到充分的记录。然而，揭示果树物种的贡献却很少受到重视。芒果（Mangifera indica L.）是世界热带和亚热带地区重要的果树作物，在100多个国家都有种植。仅在印度，芒果的年产量为2094.6万吨，种植面积为237.1万公顷。为了评估芒果树的碳滞留潜力，选择了35岁的均匀树。树木周长1.43 ~ 1.96 m，嫁接下直径0.44 ~ 0.68 m，树高9.45 ~ 11.13 m，地上重1489.44 ~ 378.56 kg/棵，总重1778.32 ~ 4546.27 kg/棵，总干重1295.81 ~ 3296.05 kg/棵。芒果树的固碳量估计为660.98 ~ 3838.96 kg/棵。单株芒果树年固碳潜力在30.78 ~ 78.30 kg/棵之间变化，平均为50.55 kg/棵。芒果种植园对该地区的水果生产、生态系统服务和可持续性至关重要。因此，碳滞留监测和估算与农民互动是同步进行的。该研究表明，芒果树通过碳滞留和对生态系统服务的重要影响，在缓解气候变化的不利影响方面发挥了重要作用。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Integrated Environmental Assessment and Management ENVIRONMENTAL SCIENCESTOXICOLOGY&nbs-TOXICOLOGY

CiteScore

5.90

自引率

6.50%

发文量

156

期刊介绍： Integrated Environmental Assessment and Management (IEAM) publishes the science underpinning environmental decision making and problem solving. Papers submitted to IEAM must link science and technical innovations to vexing regional or global environmental issues in one or more of the following core areas: Science-informed regulation, policy, and decision making Health and ecological risk and impact assessment Restoration and management of damaged ecosystems Sustaining ecosystems Managing large-scale environmental change Papers published in these broad fields of study are connected by an array of interdisciplinary engineering, management, and scientific themes, which collectively reflect the interconnectedness of the scientific, social, and environmental challenges facing our modern global society: Methods for environmental quality assessment; forecasting across a number of ecosystem uses and challenges (systems-based, cost-benefit, ecosystem services, etc.); measuring or predicting ecosystem change and adaptation Approaches that connect policy and management tools; harmonize national and international environmental regulation; merge human well-being with ecological management; develop and sustain the function of ecosystems; conceptualize, model and apply concepts of spatial and regional sustainability Assessment and management frameworks that incorporate conservation, life cycle, restoration, and sustainability; considerations for climate-induced adaptation, change and consequences, and vulnerability Environmental management applications using risk-based approaches; considerations for protecting and fostering biodiversity, as well as enhancement or protection of ecosystem services and resiliency.