Evaluation Indicator System for Ecological Benefit of Hydropower Projects

WANG Peng-xiang; JIANG Xiao-xuan; XU Yang; WANG Dong; HUO Jun-jun; ZHOU Tao

doi:10.11988/ckyyb.20231423

PDF(1566 KB)

Journal of Changjiang River Scientific Research Institute ›› 2024, Vol. 41 ›› Issue (9) : 8-18. DOI: 10.11988/ckyyb.20231423

Comprehensive Management of River Basin

Evaluation Indicator System for Ecological Benefit of Hydropower Projects

WANG Peng-xiang ¹ ,
JIANG Xiao-xuan ²^,³^,⁴ ,
XU Yang ⁵ ,
WANG Dong ²^,³^,⁴ ,
HUO Jun-jun ²^,³^,⁴ ,
ZHOU Tao ²^,³^,⁴

Author information +

History +

Abstract

To address the ambiguity surrounding the ecological benefits of hydropower projects and the challenges in quantifying these benefits, we take the Three Gorges Project as a case study to review existing research and define the ecological benefits in hydropower projects. In line with the river ecosystem service functions, we propose an evaluation framework for the ecological benefits of hydropower project from four dimensions: supply service function, support service function, regulation service function, and cultural service function. We further construct an evaluation index system for ecological benefit, and collect relevant data for quantitative analysis. Methods such as the shadow price method are used to convert these benefits into quantifiable economic values. The results indicate that the supply service value of the Three Gorges Project reaches 104.783 billion yuan, the support service value 20.074 billion yuan, the regulation service value 83.38 billion yuan, and the cultural service value 19.556 billion yuan, totaling 227.793 billion yuan. The findings offer technical support for establishing a mechanism for valuing ecological products in the Yangtze River Basin, and enhancing market-oriented and diversified ecological compensation.

Key words

ecological service function / value assessment / benefit evaluation / Three Gorges Project / indicator system

Cite this article

EndNote

Ris (Procite)

Bibtex

Download Citations

WANG Peng-xiang , JIANG Xiao-xuan , XU Yang , et al . Evaluation Indicator System for Ecological Benefit of Hydropower Projects[J]. Journal of Yangtze River Scientific Research Institute. 2024, 41(9): 8-18 https://doi.org/10.11988/ckyyb.20231423

References

List( Publishing order | Descend order by publishing year | Descend order by cited within ) Chart analysis

[1]	胡兴娥, 曹瑞. 三峡工程蓄水运用20年综合效益发挥与展望[J]. 长江科学院院报, 2024, 41(6): 1-9. (HU Xing-e, CAO Rui. Review and Prospect of Comprehensive Benefits of Three Gorges Project in 20 Years of Operation[J]. Journal of Yangtze River Scientific Research Institute, 2024, 41(6): 1-9. (in Chinese)) Cited in this article [1]

[2]

焦文婧. 三峡工程对长江中华鲟种群动态的影响分析[D]. 武汉: 中国科学院大学(中国科学院武汉植物园), 2020.

(JIAO

Wen-jing

. Analysis of the Influence of the Three Gorges Project on the Population Dynamics of Chinese Sturgeon in the Yangtze River[D]. Wuhan: Wuhan Botanical Garden, Chinese Academy of Sciences, 2020. (in Chinese))

Cited in this article [1]

[3]	欧德才. 三峡工程运行后洞庭湖水文、水质变化研究[J]. 湖南水利水电, 2020(4): 64-65, 72. (OU De-cai. Study on Changes of Hydrology and Water Quality of Dongting Lake after Operation of Three Gorges Project[J]. Hunan Hydro & Power, 2020(4): 64-65, 72. (in Chinese)) Cited in this article [1]

[4]	任琼, 严员英, 周莉荫. 三峡工程蓄水运行对鄱阳湖的影响[J]. 南方林业科学, 2017, 45(1): 64-68. (REN Qiong, YAN Yuan-ying, ZHOU Li-yin. Influence of Water-impoundment and Running of Three Gorges Reservoir on Poyang Lake[J]. South China Forestry Science, 2017, 45(1): 64-68. (in Chinese)) Cited in this article [1]

[5]	张莉媛, 宁家贤, 马长鹏, 等. 水利水电工程建设对生态环境影响的利弊分析[J]. 人民黄河, 2023, 45(增刊1): 64-65. (ZHANG Li-yuan, NING Jia-xian, MA Chang-peng, et al. Benefits and Harms of Hydropower Projects to Ecological Environment[J]. Yellow River, 2023,45 (Supp.1): 64-65. (in Chinese)) Cited in this article [1]

[6]

陈求稳, 张建云, 莫康乐, 等. 水电工程水生态环境效应评价方法与调控措施[J]. 水科学进展, 2020, 31(5): 793-810.

(CHEN

Qiu-wen

, ZHANG

Jian-yun

, MO

Kang-le

, et al. Effects of Hydropower Development on Aquatic Eco-environment and Adaptive Managements[J]. Advances in Water Science, 2020, 31(5): 793-810. (in Chinese))

Cited in this article [1]

[7]	王博娅. 生态系统服务导向下北京市中心城区绿色空间的现状及优化研究[D]. 北京: 北京林业大学, 2020. (WANG Bo-ya. Study on the Present Situation and Optimization of Green Space in Central Beijing City under the Guidance of Ecosystem Services[D]. Beijing: Beijing Forestry University, 2020. (in Chinese)) Cited in this article [1]

[8]	石铭鼎. 长江流域概况(一)[J]. 人民长江, 1982(6): 76-77. (SHI Ming-ding. Overview of the Yangtze River Basin I[J]. Yangtze River, 1982(6): 76-77. (in Chinese)) Cited in this article [1]

[9]

董耀华, 汪秀丽. 长江流域水系划分与河流分级初步研究[J]. 长江科学院院报, 2013, 30(10): 1-5.

(DONG

Yao-hua

, WANG

Xiu-li

. Preliminary Research on Watershed Division and Stream Order Classification of the Yangtze River[J]. Journal of Yangtze River Scientific Research Institute, 2013, 30(10): 1-5. (in Chinese))

Cited in this article [1]

[10]

尚淑丽, 顾正华, 曹晓萌. 水利工程生态环境效应研究综述[J]. 水利水电科技进展, 2014, 34(1): 14-19, 48.

(SHANG

Shu-li

, GU

Zheng-hua

, CAO

Xiao-meng

. Review of Research on Ecological and Environmental Effects of Water Conservancy Projects[J]. Advances in Science and Technology of Water Resources, 2014, 34(1): 14-19, 48. (in Chinese))

Cited in this article [1]

[11]	王效科, 杨宁, 吴凡, 等. 生态效益及其特性[J]. 生态学报, 2019, 39(15): 5433-5441. (WANG Xiao-ke, YANG Ning, WU Fan, et al. Ecological Benefit and Its Characteristics[J]. Acta Ecologica Sinica, 2019, 39(15): 5433-5441. (in Chinese)) Cited in this article [1]

[12]	COSTANZA R, D’ARGE R, DE GROOT R, et al. The Value of the World’s Ecosystem Services and Natural Capital[J]. Nature, 1997, 387(6630): 253-260. Cited in this article [2]

[13]	王效科, 杨宁, 吴凡, 等. 生态效益评价内容和评价指标筛选[J]. 生态学报, 2019, 39(15): 5442-5449. (WANG Xiao-ke, YANG Ning, WU Fan, et al. Ecological Benefit Evaluation Contents and Indicator Selection[J]. Acta Ecologica Sinica, 2019, 39(15): 5442-5449. (in Chinese)) Cited in this article [1]

[14]	FELD C K, SOUSA J P, DA SILVA P M, et al. Indicators for Biodiversity and Ecosystem Services: Towards an Improved Framework for Ecosystems Assessment[J]. Biodiversity and Conservation, 2010, 19(10): 2895-2919. Cited in this article [1]

[15]	傅伯杰, 刘世梁, 马克明. 生态系统综合评价的内容与方法[J]. 生态学报, 2001, 21(11): 1885-1892. (FU Bo-jie, LIU Shi-liang, MA Ke-ming. The Contents and Methods of Integrated Ecosystem Assessment(IEA)[J]. Acta Ecologica Sinica, 2001, 21(11): 1885-1892. (in Chinese)) Cited in this article [1]

[16]	陈久良. 层次分析法在急倾斜煤层采煤方法选择中的应用[J]. 科技进步与对策, 2000, 17(6): 162-163. (CHEN Jiu-liang. Application of Analytic Hierarchy Process in Selection of Mining Methods in Steep Seam[J]. Science & Technology Progress and Policy, 2000, 17(6): 162-163. (in Chinese)) Cited in this article [1]

[17]	Millennium Ecosystem Assessment. Ecosystems and Human Well-being: A Framework for Assessment[J]. Physics Teacher, 2003, 34(9): 534. Cited in this article [1]

[18]	张宁. 生态系统服务功能及其生态经济价值评价研究[J]. 商讯, 2020(12): 186. (ZHANG Ning. Service Functions of Eco-system and Assessment of Its Economic Values[J]. Business Information, 2020(12): 186. (in Chinese)) Cited in this article [1]

[19]

王毅, 张蒙, 李海东, 等. 推进应对气候变化与保护生物多样性协同治理[J]. 环境与可持续发展, 2021, 46(6): 19-25.

(WANG

, ZHANG

Meng

, LI

Hai-dong

, et al. Promoting the Co-governance to Cope with Climate Change and Biodiversity Conservation[J]. Environment and Sustainable Development, 2021, 46(6): 19-25. (in Chinese))

Cited in this article [1]

[20]	李锋, 刘旭升, 胡聃, 等. 城市可持续发展评价方法及其应用[J]. 生态学报, 2007, 27(11): 4793-4802. (LI Feng, LIU Xu-sheng, HU Dan, et al. Evaluation Method and Its Application for Urban Sustainable Development[J]. Acta Ecologica Sinica, 2007, 27(11): 4793-4802. (in Chinese)) Cited in this article [1]

[21]

赵炎, 曾源, 吴炳方, 等. 水库水气界面温室气体通量监测方法综述[J]. 水科学进展, 2011, 22(1): 135-146.

(ZHAO

Yan

, ZENG

Yuan

, WU

Bing-fang

, et al. Review of Methods for Measuring Greenhouse Gas Flux from the Air-water Interface of Reservoirs[J]. Advances in Water Science, 2011, 22(1): 135-146. (in Chinese))

Cited in this article [1]

[22]

吴炳方, 陈永柏, 曾源, 等. 三峡水库发电和航运的碳减排效果评价[J]. 长江流域资源与环境, 2011, 20(3): 257-261.

(WU

Bing-fang

, CHEN

Yong-bo

, ZENG

Yuan

, et al. Evaluation on Effectiveness of Carbon Emission Reduction of the Power Generation and Shipping Functions of the Three Gorges Reservoir[J]. Resources and Environment in the Yangtze Basin, 2011, 20(3): 257-261. (in Chinese))

Cited in this article [1]

[23]	刘飞. 引江济淮工程合肥段生态效益评价及优化策略研究[D]. 合肥: 安徽建筑大学, 2023. (LIU Fei. Study on Ecological Benefit Evaluation and Optimization Strategy of Hefei Section of Water Diversion Project from Yangtze River to Huaihe River[D]. Hefei: Anhui Jianzhu University, 2023. (in Chinese)) Cited in this article [3]

[24]

谢高地, 张彩霞, 张雷明, 等. 基于单位面积价值当量因子的生态系统服务价值化方法改进[J]. 自然资源学报, 2015, 30(8): 1243-1254.

(XIE

Gao-di

, ZHANG

Cai-xia

, ZHANG

Lei-ming

, et al. Improvement of the Evaluation Method for Ecosystem Service Value Based on Per Unit Area[J]. Journal of Natural Resources, 2015, 30(8): 1243-1254. (in Chinese))

Cited in this article [4]

[25]

张彩霞, 谢高地, 杨勤科, 等. 人类活动对生态系统服务价值的影响:以纸坊沟流域为例[J]. 资源科学, 2008, 30(12): 1910-1915.

(ZHANG

Cai-xia

, XIE

Gao-di

, YANG

Qin-ke

, et al. Influence of Human Activities on the Value of Ecosystem Services: Case Study of Zhifanggou Watershed[J]. Resources Science, 2008, 30(12): 1910-1915. (in Chinese))

Cited in this article [4]

[26]	谢高地, 张彩霞, 张昌顺, 等. 中国生态系统服务的价值[J]. 资源科学, 2015, 37(9): 1740-1746. (XIE Gao-di, ZHANG Cai-xia, ZHANG Chang-shun, et al. The Value of Ecosystem Services in China[J]. Resources Science, 2015, 37(9): 1740-1746. (in Chinese)) Cited in this article [4]

[27]

习文祥, 祝贤彬, 潘红忠, 等. 三峡水库水质时空变化特征及影响机制研究[J]. 人民长江, 2024(2): 41-50.

(XI

Wen-xiang

, ZHU

Xian-bin

, PAN

Hong-zhong

, et al. Spatio-temporal Variation Characteristics and Influence Mechanisms of Water Quality in Three Gorges Reservoir[J]. Yangtze River, 2024(2): 41-50. (in Chinese))

Cited in this article [2]

[28]	李锦秀, 廖文根. 水流条件巨大变化对有机污染物降解速率影响研究[J]. 环境科学研究, 2002, 15(3): 45-48. (LI Jin-xiu, LIAO Wen-gen. The Effect of Water Flow on the Biodegradation of Organic Pollutant[J]. Research of Environmental Sciences, 2002, 15(3): 45-48. (in Chinese)) Cited in this article [1]

[29]	蒲迅赤, 李克锋, 李嘉, 等. 紊动对水体中有机物降解影响的实验[J]. 中国环境科学, 1999, 19(6): 485-489. (PU Xun-chi, LI Ke-feng, LI Jia, et al. The Effect of Turbulence in Water Body on Organic Compound Biodegradation[J]. China Environmental Science, 1999, 19(6): 485-489. (in Chinese)) Cited in this article [1]

[30]	梁培瑜, 王烜, 马芳冰. 水动力条件对水体富营养化的影响[J]. 湖泊科学, 2013, 25(4): 455-462. (LIANG Pei-yu, WANG Xuan, MA Fang-bing. Effect of Hydrodynamic Conditions on Water Eutrophication: A Review[J]. Journal of Lake Sciences, 2013, 25(4): 455-462. (in Chinese)) Cited in this article [1]

[31]	李亚娜. 辽河流域生态修复工程效果评估及湿地效益研究[D]. 沈阳: 沈阳建筑大学, 2015. (LI Ya-na. Effect Evaluation of Ecological Restoration Project in Liaohe River Basin and Study on Wetland Benefit[D]. Shenyang: Shenyang Jianzhu University, 2015. (in Chinese)) Cited in this article [1]

[32]

中华人民共和国水利部. 2010中国水土保持公报[J]. 中华人民共和国水利部公报, 2012(1): 22-35.

(Ministry of Water Resources of the People’s Republic of China. Bulletin of China’s Soil and Water Conservation in 2010[J]. Gazette of the Ministry of Water Resources of the People’s Republic of China, 2012(1): 22-35. (in Chinese))

Cited in this article [1]

[33]

吴昊燊, 钱星妤, 祝栋林. 长江干流总氮时空分布特征分析[J]. 青海环境, 2023, 33(3): 137-141, 153.

(WU

Hao-shen

, QIAN

Xing-yu

, ZHU

Dong-lin

. Temporal and Spatial Distribution Characteristics of Total Nitrogen in the Main Stream of the Yangtze River[J]. Journal of Qinghai Environment, 2023, 33(3): 137-141, 153. (in Chinese))

Cited in this article [1]

[34]

陈峰, 李晓慧, 王文静, 等. 2018—2022年长江流域总磷时空变化特征研究[J]. 水利水电快报, 2023, 44(8): 91-97, 105.

(CHEN

Feng

, LI

Xiao-hui

, WANG

Wen-jing

, et al. Temporal and Spatial Variation Characteristics of Total Phosphorus in Yangtze River Basin from 2018 to 2022[J]. Express Water Resources & Hydropower Information, 2023, 44(8): 91-97, 105. (in Chinese))

Cited in this article [1]

[35]

沈志良, 刘群, 张淑美. 长江总氮和有机氮的分布变化与迁移[J]. 海洋与湖沼, 2003, 34(6): 577-585.

(SHEN

Zhi-liang

, LIU

Qun

, ZHANG

Shu-mei

. Distribution, Variation and Removal Patterns of Totalnitrogen and Organic Nitrogen in the Changjiang River[J]. Oceanologia et Limnologia Sinica, 2003, 34(6): 577-585. (in Chinese))

Cited in this article [1]

[36]

黄自强, 暨卫东. 长江口水中总磷、有机磷、磷酸盐的变化特征及相互关系[J]. 海洋学报(中文版), 1994(1): 51-60.

(HUANG

Zi-qiang

, JI

Wei-dong

. Variation Characteristics and Correlations of Total Phosphorus, Organic Phosphorus, and Phosphate Concentration in the Yangtze River Estuary[J]. Acta Oceanologica Sinica, 1994(1): 51-60. (in Chinese))

Cited in this article [1]

[37]	赵一宁, 李朝玺, 安彩妹, 等. 基于不同城镇污水处理厂的运行成本分析研究[J]. 给水排水, 2018, 54(增刊2): 48-50. (ZHAO Yi-ning, LI Chao-xi, AN Cai-mei, et al. Operation Costs of Wastewater Plants in Different TownsJ]. Water and Wastewater, 2018, 54(Supp.2): 48-50. (in Chinese)) Cited in this article [1]

[38]	刘桂金. 水利工程防洪经济效益的简易分析计算法[J]. 中国新技术新产品, 2011(3): 81. (LIU Gui-jin. Simple Analysis and Calculation Method of Flood Control Economic Benefits of Water Conservancy Projects[J]. New Technology & New Products of China, 2011(3): 81. (in Chinese)) Cited in this article [1]

[39]	王儒述. 论三峡工程的综合效益[J]. 水电与新能源, 2011(6): 74-78. (WANG Ru-shu. Discussing the Comprehensive Benefits of Three Gorges Project[J]. Hydropower and New Energy, 2011(6): 74-78. (in Chinese)) Cited in this article [1]

[40]	石泽云, 臧梧华. 江苏省已建供水水利工程在1986年抗旱斗争中的经济效益分析[J]. 水利经济, 1987(2): 22-26,41. (SHI Ze-yun, ZANG Wu-hua. Economic Benefits of Existing Water Supply Projects in the Drought Relief in 1986[J]. Journal of Economics of Water Resources, 1987(2): 22-26,41. (in Chinese)) Cited in this article [1]

[41]

乔红杰, 吴敬文, 蒋咏, 等. 长江口咸潮对饮用水水源地的影响及应对措施[C]// 《中国防汛抗旱》杂志社,水利部防洪抗旱减灾工程技术研究中心(水旱灾害防御中心).2022—2023年度全国典型洪旱过程应对技术经验交流会论文集.宁波, 2023: 157-164.

(QIAO

Hong-jie

, WU

Jing-wen

, JIANG

Yong

, et al. Influence of Salt Tide in the Yangtze River Estuary on Drinking Water Sources and Response Measures[C]// Editorial Department of China Flood and Drought Management, and Research Center of Ministry of Water Resources on Flood Control and Drought Relief Engineering Technology (Flood and Drought Disaster Prevention Center). Proceedings of the 2022-2023 Experience Exchanging Meeting on National Typical Flood and Drought Prevention Technologies. Ningbo, 2023: 157-164. (in Chinese))

Cited in this article [1]