Maximizing tree carbon in croplands and grazing lands while sustaining yields

IF 3.9 3区环境科学与生态学 Q2 ENVIRONMENTAL SCIENCES

Carbon Balance and Management Pub Date : 2024-07-31 DOI:10.1186/s13021-024-00268-y

Starry Sprenkle-Hyppolite, Bronson Griscom, Vivian Griffey, Erika Munshi, Melissa Chapman

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Abstract

Background

Integrating trees into agricultural landscapes can provide climate mitigation and improves soil fertility, biodiversity habitat, water quality, water flow, and human health, but these benefits must be achieved without reducing agriculture yields. Prior estimates of carbon dioxide (CO₂) removal potential from increasing tree cover in agriculture assumed a moderate level of woody biomass can be integrated without reducing agricultural production. Instead, we used a Delphi expert elicitation to estimate maximum tree covers for 53 regional cropping and grazing system categories while safeguarding agricultural yields. Comparing these values to baselines and applying spatially explicit tree carbon accumulation rates, we develop global maps of the additional CO₂ removal potential of Tree Cover in Agriculture. We present here the first global spatially explicit datasets calibrated to regional grazing and croplands, estimating opportunities to increase tree cover without reducing yields, therefore avoiding a major cost barrier to restoration: the opportunity cost of CO₂ removal at the expense of agriculture yields.

Results

The global estimated maximum technical CO₂ removal potential is split between croplands (1.86 PgCO₂ yr^− 1) and grazing lands (1.45 PgCO₂ yr^− 1), with large variances. Tropical/subtropical biomes account for 54% of cropland (2.82 MgCO₂ ha^− 1 yr^− 1, SD = 0.45) and 73% of grazing land potential (1.54 MgCO₂ ha^− 1 yr^− 1, SD = 0.47). Potentials seem to be driven by two characteristics: the opportunity for increase in tree cover and bioclimatic factors affecting CO₂ removal rates.

Conclusions

We find that increasing tree cover in 2.6 billion hectares of agricultural landscapes may remove up to 3.3 billion tons of CO₂ per year – more than the global annual emissions from cars. These Natural Climate Solutions could achieve the Bonn Challenge and add 793 million trees to agricultural landscapes. This is significant for global climate mitigation efforts because it represents a large, relatively inexpensive, additional CO₂ removal opportunity that works within agricultural landscapes and has low economic and social barriers to rapid global scaling. There is an urgent need for policy and incentive systems to encourage the adoption of these practices.

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在保持产量的同时，最大限度地提高耕地和牧场的树木碳含量。

背景：将树木纳入农业景观可缓解气候影响，并改善土壤肥力、生物多样性栖息地、水质、水流和人类健康，但必须在不降低农业产量的情况下实现这些效益。先前对增加农业植被所产生的二氧化碳（CO2）清除潜力的估算假定，可以在不降低农业产量的情况下整合中等水平的木质生物量。相反，我们采用德尔菲专家征询法估算了 53 个地区种植和放牧系统类别的最大树木覆盖率，同时保证了农业产量。将这些数值与基线进行比较，并应用空间明确的树木碳积累率，我们绘制了农业中树木覆盖的额外二氧化碳清除潜力的全球地图。我们在此提出了首个全球空间明确数据集，并对区域放牧和耕地进行了校准，估算了在不减少产量的情况下增加树木覆盖的机会，从而避免了恢复的主要成本障碍：以牺牲农业产量为代价的二氧化碳去除机会成本：全球估计的最大技术二氧化碳清除潜力分布在耕地（1.86 PgCO2 yr-1）和牧场（1.45 PgCO2 yr-1）之间，差异很大。热带/亚热带生物群落占耕地潜力的 54%（2.82 MgCO2 ha- 1 yr- 1，SD = 0.45），占牧场潜力的 73%（1.54 MgCO2 ha- 1 yr- 1，SD = 0.47）。潜力似乎受两个特征的驱动：增加树木覆盖率的机会和影响二氧化碳去除率的生物气候因素：我们发现，在 26 亿公顷的农业景观中增加树木覆盖率每年可清除多达 33 亿吨的二氧化碳--超过全球汽车的年排放量。这些自然气候解决方案可以实现 "波恩挑战"，为农业景观增加 7.93 亿棵树。这对全球气候减缓工作意义重大，因为它代表了一个巨大的、相对廉价的、额外的二氧化碳清除机会，可在农业景观中发挥作用，而且经济和社会障碍较少，可在全球范围内迅速推广。目前迫切需要制定政策和激励制度，以鼓励采用这些做法。

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

Carbon Balance and Management Environmental Science-Management, Monitoring, Policy and Law

CiteScore

7.60

自引率

0.00%

发文量

审稿时长

14 weeks

期刊介绍： Carbon Balance and Management is an open access, peer-reviewed online journal that encompasses all aspects of research aimed at developing a comprehensive policy relevant to the understanding of the global carbon cycle. The global carbon cycle involves important couplings between climate, atmospheric CO2 and the terrestrial and oceanic biospheres. The current transformation of the carbon cycle due to changes in climate and atmospheric composition is widely recognized as potentially dangerous for the biosphere and for the well-being of humankind, and therefore monitoring, understanding and predicting the evolution of the carbon cycle in the context of the whole biosphere (both terrestrial and marine) is a challenge to the scientific community. This demands interdisciplinary research and new approaches for studying geographical and temporal distributions of carbon pools and fluxes, control and feedback mechanisms of the carbon-climate system, points of intervention and windows of opportunity for managing the carbon-climate-human system. Carbon Balance and Management is a medium for researchers in the field to convey the results of their research across disciplinary boundaries. Through this dissemination of research, the journal aims to support the work of the Intergovernmental Panel for Climate Change (IPCC) and to provide governmental and non-governmental organizations with instantaneous access to continually emerging knowledge, including paradigm shifts and consensual views.