A Dynamic Succession-Based Life-Cycle Simulation Model for Projecting Carbon Source–Sink Transitions in Urban Plant Communities
都市植物群落における炭素源・吸収源転換を予測する動的遷移型ライフサイクルシミュレーションモデル (AI 翻訳)
Xiaxi Liuyang, Jiayu Lu, Yang Cao
🤖 gxceed AI 要約
日本語
中国天津の150の都市植物群落を対象に、植生の50年間の炭素収支をシミュレーション。初期はほとんどの群落が炭素源だが、時間経過とともに炭素吸収源に転換し、86.1%が50年後に正味炭素吸収源となる。維持管理における施肥が主要排出源であることを示し、資源節約型管理が有効と結論。
English
This study develops a dynamic life-cycle simulation model to project 50-year carbon source-sink transitions for 150 urban plant communities in Tianjin, China. Results show most communities shift from carbon sources to sinks over time, with 86.1% becoming net sinks after 50 years. Fertilization is the dominant maintenance emission source, and resource-saving management improves net carbon balance. Vertical complexity and species richness are key positive predictors.
Unofficial AI-generated summary based on the public title and abstract. Not an official translation.
📝 gxceed 編集解説 — Why this matters
日本のGX文脈において
日本でも都市緑化によるカーボンオフセットが注目されているが、本モデルは植生のライフサイクル全体(建設・維持管理・成長)を考慮した炭素収支評価を提供。日本の都市計画やグリーンインフラ政策において、植栽設計や維持管理の低炭素化に示唆を与える。
In the global GX context
This paper contributes a robust life-cycle framework for assessing the net carbon benefits of urban plant communities, addressing a gap in nature-based solutions accounting. Globally, it provides a transferable methodology for cities to optimize planting design and maintenance for climate mitigation, aligning with urban decarbonization strategies and TCFD/ISSB's nature-related disclosure trends.
👥 読者別の含意
🔬研究者:Provides a validated model integrating succession and maintenance emissions, useful for urban carbon cycle research.
🏢実務担当者:Offers evidence-based guidelines for planting design and low-maintenance practices to enhance carbon sequestration.
🏛政策担当者:Supports urban climate action plans with quantitative carbon benefit projections for green infrastructure investments.
📄 Abstract(原文)
Urban plant communities are widely regarded as important nature-based solutions for climate mitigation, yet their actual carbon benefits remain uncertain: vegetation growth is accompanied by carbon emissions from construction and long-term maintenance, and existing assessments rarely integrate community succession, interspecific competition, and maintenance-related emissions within a consistent life-cycle framework. To address these limitations, this study developed a dynamic succession-based life-cycle simulation model to project the 50-year carbon source–sink transitions of 150 typical urban plant communities in Tianjin, China. The model updates plant structural attributes—diameter at breast height, crown width, and tree height—iteratively by linking individual plant growth to environmental suitability and neighborhood competition through a Plant Health Index. Simulated structural trajectories were coupled with biomass equations and carbon content coefficients to estimate aboveground carbon sequestration, while construction and maintenance emissions were quantified using life cycle assessment, enabling evaluation of modeled net carbon balance rather than gross carbon sequestration alone. Under the modeled 50-year scenario, most communities were projected to act as carbon sources during the early stage but gradually shifted toward carbon sinks as biomass accumulated; 86.1% of the communities were projected to become net carbon sinks after 50 years (a scenario-based projection under specified growth, maintenance, and emission assumptions). The highest modeled net carbon balance reached 3186.08 kg C ha−1, whereas the weakest community remained a slight carbon source at −81.21 kg C ha−1. Vertical structural complexity and species richness were the strongest positive predictors of modeled net carbon balance, followed by three-dimensional green quantity and canopy closure. Among maintenance processes, fertilization was the dominant emission source, followed by pesticide application and irrigation; comparative scenario analysis showed that resource-saving maintenance consistently improved projected net carbon balance relative to high-maintenance management. These results suggest that low-carbon planting design should prioritize locally adapted species, multi-layered vertical structures, and adaptive maintenance over simply maximizing planting density or minimizing inputs. The results represent scenario-based projections of aboveground vegetation carbon balance; belowground biomass, soil carbon, litter carbon, dead organic matter, and parameter uncertainty were not fully incorporated, and future studies should address these limitations to improve the robustness and transferability of the proposed framework.
🔗 Provenance — このレコードを発見したソース
- openalex https://doi.org/10.3390/biology15131072first seen 2026-07-08 05:23:53
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