| China Geological Survey Chinese Academy of Geological Sciences | Host |
| 科学出版社 | Publish |
| Citation: |
WANG Jingbing, WEI Xiaofeng, ZHANG Huiqiong, GAN Fengwei. 2020. The eco-geological survey based on geological formation, exemplified by integrated geological survey of National Ecological Civilization Demonstration Area in Chengde City, Hebei Province[J]. Geology in China, 47(6): 1611-1624. doi: 10.12029/gc20200601
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The eco-geological survey based on geological formation, exemplified by integrated geological survey of National Ecological Civilization Demonstration Area in Chengde City, Hebei Province
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Abstract
Eco-geology is a science that studies the interaction between ecology and geological environment and its mechanism. The technical frameworks for eco-geological surveys based on geological formation for mountainous areas are summarized, through the project of "Comprehensive Geological Survey of National Ecological Civilization Demonstration Area in Chengde City". According to the three levels of survey, i.e., background (baseline) survey-small watershed survey -research on ecological critical zone, the eco-geological characteristics and function rules of Chengde City are gradually deepened. The survey at the 1:250000 scale can quickly identify the eco-geological background (baseline) of the whole area, recognize the eco-geological units, and quickly screen the eco-geological targets (dominant ecological resource areas and ecological environment risk areas) through the geological formation analysis and mapping; the survey with a key small watershed unit (at the scale of 1:50, 000) is carried out for the selected target areas so as to identify the characteristics of dominant resources and evaluate the risks of ecological environment; surveys and researches on ecological critical zones of typical geological formation (at the scale of 1:10000) are carried out to reveal the three-dimensional characteristics and interaction mechanism of the eco-geological system and provide a basis for comprehensive monitoring and prediction of the evolution trend. The framework of "Demand-Survey-Application" is demonstrated based on the survey results, and corresponding suggestions are proposed for the land spatial planning, ecological industry development and ecological protection and restoration for Chengde City.
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References
Anderson R S. 2015. Pinched topography initiates the critical zone[J]. Science, 350(6260):506-507. doi: 10.1126/science.aad2266 Chen Liwei, Xu Xiaochun, Wang Jun, Chen Fang. 2014. Distribution of Heavy Metals in Xiangsi River Valley of Tongling, China[J]. Environmental Science, 35(8):2967-2973(in Chinese with English abstract). Golodhaber M B, Mills C T, Morrison J M, Stricker C A, Mushet D M, Labaugh J W, 2014. Hydrogeochemistry of prairie pothole region wetlands:Role of long-term critical zone processes[J]. Chemical Geology, 387:170-183 doi: 10.1016/j.chemgeo.2014.08.023 Geological Dictionary Office of the Ministry of Geology and Mineral Resources. 1983. Geological Dictionary(1):General Geology and Tectonic Geology (volume 2)[M]. Beijing:Geological Publishing House, 116(in Chinese). Hahm W J, Riebe C S, Lukens C E. 2014. Bedrock composition regulates mountain ecosystems and landscape evolution[J]. Proceedings of the National Academy of Sciences, 111(9):3338-3343. doi: 10.1073/pnas.1315667111 Lukasz Pawlik, Jonathan D Phillips, Pavel Samonil. 2016. Root, rock, and regolith:Biomechanical and biochemical weathering by trees and its impact on hillslopes-A critical literature review[J].EarthScience Reviews, 159:142-159 Hahm W J, Rempe D M, Dralle D N, Dawson T E, Lovill S M, Bryk A B, Bish D L, Schieber J, Dietrich W E. 2018. Lithologically controlled subsurface crtical zone thickness and water sorage capacity determine regional plant community composition[J]. Water Resources Research, 55.https://dio.org/10.1029/wr023760. He Zhengwei, Huang Runqiu, Sun Chuanmin, Wu Boqing, Hang Lingling, He Fenqin, Sun Yujiang, Yi Jianzhong, Liu Shaojun Zhao Yinbing. 2003. A brief discussion on"eco-geology"[J].Scientific and Technological Management of Land and Resources, 3(20):69-72(in Chinese with English abstract).. Huang Runqiu 2001. Basic characteristics and technical support of the eco-environmental geology[J]. Geology in China, 28(11):20-24(in Chinese). Jiang Hongqiang, Wu Wenjun, Yao Yanling, Liu Nianlei, Wang Jinnan, Bi Jun, Yao Ruihua. 2015. Coupling watershed environmental model with optimizing method to provide least cost alternatives in environmental planning and management[J]. Ecology and Environmental Sciences, 24(3):539-546 (in Chinese with English abstract). Li Jinfa. 2014. Geological survey for ecological civilization[J]. Resources Environment & Engineering, 28(1):1-4(in Chinese with English abstract). Li Yue, Qi Shi. 2018. Ecological civilization small watershed of construction of soil and water conservation[J]. China Population, Resources And Environment, 28(S2):14-17 (in Chinese with English abstract). Li Junqi, Ma Teng, Deng Yamin, Du Yao, Wang Zhiqiang, Jiang Yuehua. 2019. Progresses on monitoring network construction of Earth's Critical Zone in Jianghan Plain[J].Geological Survey of China, 6(5):115-123(in Chinese with English abstract). Li Tingdong. 1999. Strengthening study and geological mapping of the earth sureface system[J]. Quaternary Sciences, (3):191-196(in Chinese with English abstract) Ma Shouxian, Meng Qingren, Qu Yongqiang. 2011. A study of detrital zircons of Late Carboniferous-Middle Triassic strata in the northern margin of North China block and its geological implication[J]. Geological Bulletin of China, 30(10):1485-1500(in Chinese with English abstract). Mou Baolei. 1999. Elemental Geochemistry[M]. Beijing:Peking University Press(in Chinese). Shi Jiansheng, Ma Rong, Ma Zhen. 2019. Regional investigation of the earth's critical zone[J]. Acta Geoscientica Sinica, 40(6):767-780(in Chinese with English abstract). Sun Xiangyang. 2005. Soil Science[M] Beijing:China Forestry Publishing House(in Chinese). Yang Jianfeng, Zhang Cuiguang. 2014. Earth's critical zone:A holistic framework for geo-environmental researches[J]. Hydrogeology & Engineering Geology, 41(3):98-106(in Chinese with English abstract). Yang Zhanjun, Zhang Senqi, Li Bangmin, Wang Yonggui, An Yong, Shi Weidong, Xin Yuanhong. 2008. On the method of geologic investigation and mapping in Qinghai-tibet plateau.Northw estern geology, 41(3):112-131(in Chinese with English abstract). Trofimov V T, Andreeva T V. 2010. Ecological geological systems and their types, position in the ecosytems structure and tasks of the investigation[J].Earth Science Frontiers, 17(2):425-438 陈莉薇, 徐晓春, 王军, 陈芳.2014.铜陵相思河流域重金属分布特征研究[J].环境科学, 35(08):2967-2973. 地质矿产部地质辞典办公室.1983.地质辞典(一):普通地质构造地质分册[M].北京:地质出版社. 何政伟, 黄润秋, 孙传敏, 吴柏青, 韩玲玲, 贺奋勤, 孙渝江, 尹建忠, 刘少军, 赵银兵.浅议"生态地质学"[J].国土资源科技管理, 2003, 3(20):69-72. 黄润秋.2001.生态环境地质的基本特点与技术支撑[J].中国地质, 28(11):20-24 蒋洪强, 吴文俊, 姚艳玲, 刘年磊, 王金南, 毕军, 姚瑞华.2015.耦合流域模型及在中国环境规划与管理中的应用进展[J].生态环境学报, 24(3):539-546. 李金发.2014.为生态文明服务的地质调查工作[J].资源环境与工程, 28(1):1-4. 李俊琦, 马腾, 邓娅敏, 杜尧, 王志强, 姜月华. 2019.江汉平原地球关键带监测网建设进展[J].中国地质调查, 6 (5):115-123. 李廷栋. 1999.加强地球表层系统的研究和地质制图工作[J].第四纪研究, 3:191-196. 李月, 齐实. 2018.建设水土保持生态文明小流域的思考[J].中国人口·资源与环境, 28(S2):14-17. 马收先, 孟庆任, 曲永强. 2011.华北地块北缘上石炭统-中三叠统碎屑锆石研究及其地质意义[J].地质通报, 30(10):1486-1500. 牟保磊. 1999.元素地球化学[M].北京大学出版社. 孙向阳.2005.土壤学[M].北京:中国林业出版社. 石建省, 马荣, 马震. 2019.区域地球多圈层交互带调查探索研究[J].地球学报, 40(6):767-780. 杨建锋, 张翠光. 2014.地球关键带:地质环境研究的新框架[J].水文地质工程地质, 41(3):98-106. 杨站君, 张森琦, 李邦民, 王永贵, 安勇, 石维栋, 辛元红. 2008.青藏高原升天环境地质调查与填图技术方法研究.西北地质, 41(3):112-131. -
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WANG Jingbing, WEI Xiaofeng, ZHANG Huiqiong, GAN Fengwei. 2020. The eco-geological survey based on geological formation, exemplified by integrated geological survey of National Ecological Civilization Demonstration Area in Chengde City, Hebei Province[J]. Geology in China, 47(6): 1611-1624. doi: 10.12029/gc20200601
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Figure 1.
Traffic location map (a), topography map (b), eco-geological background profile of plateau-plain transition zone in Chengde City
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Figure 2.
Deployment framework on three levels of eco-geological survey, Chengde City
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Figure 3.
Distribution patterns of plant nutrient elements(10-6)in bedrock-weathered layer-soil layer in different geological formations
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Figure 4.
Geological formation map of Chengde City (1:250000)
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Figure 5.
Element geochemistry of Chengde City (1:250000)
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Figure 6.
Geological formation nesting analysis and eco-geological unit zoning in Chengde City
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Figure 7.
Schematic diagram of Wulie River watershed in Chengde City
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Figure 8.
Schematic diagram of eco-geological system model and ecological critical zone
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Figure 9.
Schematic diagram of "Demand-Survey-Application" system for eco-geological survey in Chengde City
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Figure 10.
Scheme for optimizing the planting areas for typical forests and fruits in the southern part of Chengde City