Evaluation and Optimization Model of Green Space Ecosystem Services in Urbanization Process
DOI:
https://doi.org/10.54097/86w0rd80Keywords:
Urbanization process, Green space ecosystem services, Evaluation and optimizationAbstract
In the rapidly advancing wave of urbanization in China, a series of urban environmental problems have gradually surfaced, seriously threatening the quality of life of residents and the sustainable development of cities. In this context, the importance of urban green space ecosystems as the "lungs of the city" is increasingly prominent. Green spaces not only effectively absorb pollutants from the air, regulate urban microclimate, and alleviate the heat island effect, but also provide valuable leisure space and spiritual comfort for urban residents, playing an irreplaceable role in improving citizens' well-being and beautifying urban landscapes. This article explores in depth the evaluation methods of green space ecosystem services in the process of urbanization, aiming to comprehensively analyze the service functions and values of green space systems in various aspects such as air purification, climate regulation, biodiversity conservation, leisure and entertainment, and cultural education through scientific quantitative methods. At the same time, this article also constructs an optimization model for green space ecosystem services, aiming to guide urban planners and managers on how to scientifically layout green space systems, achieve maximum utilization and rational allocation of green space resources.
Downloads
References
[1] De Lima G N, Fonseca-Salazar M A, Campo J. Urban growth and loss of green spaces in the metropolitan areas of São Paulo and Mexico City: effects of land-cover changes on climate and water flow regulation [J]. Urban Ecosystems, 2023, 26(6): 1739-1752.
[2] Washbourne C L. Environmental policy narratives and urban green infrastructure: Reflections from five major cities in South Africa and the UK [J]. Environmental Science & Policy, 2022, 129: 96-106.
[3] Plummer K E, Gillings S, Siriwardena G M. Evaluating the potential for bird‐habitat models to support biodiversity‐friendly urban planning [J]. Journal of Applied Ecology, 2020, 57(10): 1902-1914.
[4] Wang J, Zhou W, Pickett S T A, et al. A multiscale analysis of urbanization effects on ecosystem services supply in an urban megaregion [J]. Science of the total environment, 2019, 662: 824-833.
[5] Fang G, Sun X, Liao C, et al. How do ecosystem services evolve across urban–rural transitional landscapes of Beijing–Tianjin–Hebei region in China: patterns, trade-offs, and drivers [J]. Landscape Ecology, 2023, 38(4): 1125-1145.
[6] Zhang S, Sun C, Zhang Y, et al. Exploring the Spatiotemporal Changes and Driving Forces of Ecosystem Services of Zhejiang Coasts, China, Under Sustainable Development Goals [J]. Chinese Geographical Science, 2024, 34(4): 647-661.
[7] Amini Parsa V, Istanbuly M N, Kronenberg J, et al. Urban trees and hydrological ecosystem service: a novel approach to analyzing the relationship between landscape structure and runoff reduction [J]. Environmental Management, 2024, 73(1): 243-258.
[8] Wu W, Zeng H, Guo C, et al. Spatial heterogeneity and management challenges of ecosystem service trade-offs: a case study in Guangdong Province, China [J]. Environmental Management, 2024, 73(2): 378-394.
[9] Chen S, Li G, Zhuo Y, et al. Trade-offs and synergies of ecosystem services in the Yangtze River Delta, China: response to urbanizing variation [J]. Urban Ecosystems, 2022, 25(1): 313-328.
[10] Das S, Kumar Shit P, Bera B, et al. Effect of urbanization on the dynamics of ecosystem services: An analysis for decision making in Kolkata urban agglomeration [J]. Urban Ecosystems, 2022, 25(5): 1541-1559.
Downloads
Published
Issue
Section
License
This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.
