Emerging risk assessment of areas subject to land subsidence in the southern plain of Tianjin, China

doi:10.6046/zrzyyg.2022153

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Abstract

The development of emerging technologies poses some risks while improving urban construction and human life, thus further causing urban safety problems. Tianjin is a coastal city in China, where the coastal sea level keeps increasing, water cycling is changed by the water supply of the South-to-North Water Diversion Project, and the underground space is subject to development and utilization. These factors, coupled with land subsidence, are all critical for the assessment of emerging risks in Tianjin. This study extracted information on the land subsidence of the southern plain in Tianjin and then predicted the retreat of the natural coastline in Tianjin by combining the sea level rise rate. Accordingly, this study predicted the high-risk factors brought by relative sea level rise in Tianjin using a machine learning method (XGBoost). In addition, this study analyzed the emerging risks caused by the South-to-North Water Diversion Project and the development and utilization of underground space and revealed the response patterns of the water supply and the construction and operation of subways to the urban safety of Tianjin. The study on the emerging risks brought about by the combination of land subsidence and modern human activities will provide a scientific basis for regional disaster prevention and mitigation and improve cities’ ability to resist disasters.

Keywords land subsidence emerging risk relative sea level rise XGBoost

ZTFLH:	TP79
	P237

Issue Date: 07 July 2023

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	Hairuo YU
	Huili GONG
	Beibei CHEN
	Chaofan ZHOU

Cite this article:

Hairuo YU,Huili GONG,Beibei CHEN, et al. Emerging risk assessment of areas subject to land subsidence in the southern plain of Tianjin, China[J]. Remote Sensing for Natural Resources, 2023, 35(2): 182-192.

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https://www.gtzyyg.com/EN/10.6046/zrzyyg.2022153 OR https://www.gtzyyg.com/EN/Y2023/V35/I2/182

Fig.1 Location of Tianjin and the coverage of images

Fig.2 Technical flow chart

Fig.3 Distribution of accumulated settlement in Tianjin from 2012 to 2018

Fig.4 Comparison of the leveling deformation and the annual deformation of InSAR

Fig.5 Comparison of the annual deformation derived from Radarsat-2-A and Radarsat-2-B

Fig.6 The inundated area of Tianjin coastal area under the superimposed action

Fig.7 Present situation of land use in southern plain area of Tianjin

Fig.8 XGBoost regression curve

Fig.9 Superimposing the urban safety results on the ground subsidence and the groundwater funnel

Fig.10 Importance ranking of factors affecting urban safety

Fig.11 Subsidence of water plant of Tianjin South-to-North Water Diversion Project

Fig.12 Annual settlement of water plant of Tianjin South-to-North Water Diversion Project

Fig.13 Annual settlement of Tianjin metro line buffer zone

[1]	于海若, 宫辉力, 陈蓓蓓, 等. 新水情下利用InSAR-GRACE卫星的新兴风险预警与城市地下空间安全展望[J]. 国土资源遥感, 2020, 32(4):16-22.doi:10.6046/gtzyyg.2020.04.03. doi: 10.6046/gtzyyg.2020.04.03
[1]	Yu H R, Gong H L, Chen B B, et al. Emerging risks and the prospect of urban underground space security based on InSAR -GRACE satellite under the new hydrological background[J]. Remote Sensing for Land and Resources, 2020, 32(4):16-22.doi:10.6046/gtzyyg.2020.04.03. doi: 10.6046/gtzyyg.2020.04.03
[2]	胡俊杰, 蒙爱军. 天津地区的相对海平面上升与地面沉降[J]. 海洋信息, 2005(2):17-19,7.
[2]	Hu J J, Meng A J. Relative sea level rise and land subsidence in Tianjin[J]. Ocean Information, 2005(2):17-19,7.
[3]	吕传振, 刘凯旋. 天津地区地铁沿线地面沉降特征分析[J]. 北京测绘, 2020, 34(9):3.
[3]	Lyu C Z, Liu K X. Analysis of land subsidence characteristics along subway in Tianjin[J]. Beijing Surveying and Mapping, 2020, 34 (9):3.
[4]	Cole G. A discussion on problems associated with the subsidence of southeastern England:The east coast and London tidal flood warning systems[J]. Philosophical Transactions of the Royal Society of London, 1972, 272(1221):173-178.
[5]	Mazzotti S, Lambert A, Kooij M V D. Impact of anthropogenic subsidence on relative sea-level rise in the Fraser River delta[J]. Geology, 2009, 37(9):771-774. doi: 10.1130/G25640A.1 url: https://pubs.geoscienceworld.org/geology/article/37/9/771-774/29938
[6]	Mazzotti S, Lambert T, Kooij M V D. Coastal subsidence and relative sea-level rise in the Fraser River delta,Greater Vancouver,BC,from a combined CTM-InSAR,GPS,leveling,and tide gauge analysis[C]// AGU Fall Meeting Abstracts, 2008.
[7]	Esra E, Cristian R. The worsening impacts of land reclamation assessed with Sentinel-1:The Rize (Turkey) test case[J]. International Journal of Applied Earth Observation and Geoinformation, 2006(74):57-64.
[8]	Miller K G, Sugarman P J, Browning J V. Sea-level rise in New Jersey over the past 5000 years:Implications to anthropogenic changes[J]. Global and Planetary Change, 2009, 66(1-2):10-18. doi: 10.1016/j.gloplacha.2008.03.008 url: https://linkinghub.elsevier.com/retrieve/pii/S0921818108001707
[9]	Sannekevan A, Gilles E, Esther S, et al. The relative contribution of peat compaction and oxidation to subsidence in built-up areas in the Rhine-Meuse delta,the Netherlands[J]. Science of the Total Environment, 2018(636):177-191.
[10]	Sun H, Grandstaff D, Shagam R. Land subsidence due to groundwater withdrawal:Potential damage of subsidence and sea level rise in southern New Jersey[J]. USA.Environmental Geology, 1999, 37(4):290-296.
[11]	Abidin H Z, Andreas H, Gamal M. Land subsidence characteristics of the Jakarta basin (Indonesia) and its relation with groundwater extraction and sea level rise[J]. Groundwater Response to Changing Climate, 2010(1):113-130.
[12]	Abidin H Z, Andreas H, Gumilar I. Land subsidence of Jakarta (Indonesia) and its relation with urban development[J]. Natural Hazards, 2011, 59(3):1753-1771. doi: 10.1007/s11069-011-9866-9 url: http://link.springer.com/10.1007/s11069-011-9866-9
[13]	Abidin H Z, Andreas H, Gumilar I. On correlation between urban development,land subsidence and flooding phenomena in Jakarta[J]. IAHS-AISH Proceedings and Reports, 2015, 370:15-20.
[14]	李响, 段晓峰, 张增健, 等. 中国沿海地区海平面上升脆弱性区划[J]. 灾害学, 2016, 31(4):103-109.
[14]	Li X, Duan X F, Zhang Z J, et al. Vulnerability zoning of sea level rise in coastal areas of China[J]. Disaster Science, 2016, 31 (4):103-109.
[15]	谢翠娜, 许世远, 胡蓓蓓, 等. 地面沉降对天津滨海地区风暴潮灾危险性影响评价. 世界地理研究, 2009, 18(4):126-133.
[15]	Xie C N, Xu S Y, Hu B B, et al. Assessment of land subsidence influence on storm surge risk in Tianjin Binhai area[J]. World Regional Studies, 2009, 18 (4):126-133.
[16]	张永红, 丁炜, 何静, 等. 基于XGBoost的雅江流域孕灾环境危险性分析[J]. 长江科学院院报, 2021, 3(9):1-10.
[16]	Zhang Y H, Ding W, He J, et al. Risk analysis of hazard-pregnant environment in Brahmaputra based on XGBoost[J]. Journal of Yangtze River Scientific Research Institute, 2021, 3(9):1-10.
[17]	宫思艺, 孔宪光, 刘丹, 等. 融入复杂地层动态识别的盾构施工地表沉降预测方法研究[J]. 仪器仪表学报, 2019, 40(6):228-236.
[17]	Gong S Y, Kong X G, Liu D, et al. An approach for predicting shield construction ground surface settlement of complex stratum using dynamical strata identification[J]. Chinese Journal of Scientific Instrument, 2019, 40(6):228-236.
[18]	林报嘉, 刘晓东, 杨川, 等. XGBoost机器学习模型与GIS技术结合的公路崩塌灾害易发性研究[J]. 公路, 2020, 65(7):20-26.
[18]	Lin B J, Liu X D, Yang C, et al. Avalanche susceptibility assessment of highway based on XGBoost machine learning model and GIS technology[J]. Highway, 2020, 65(7):20-26.
[19]	Zhao T A, Zheng S H, Li W L, et al. A study of the credit risk analysis based on XGBoost[J]. Software Engineering, 2018, 21(6):29-32.
[20]	Guo L, Gong H L, Zhu F. Analysis of the spatiotemporal variation in land subsidence on the Beijing plain,China[J]. Remote Sensing, 2019, 11(10):1170. doi: 10.3390/rs11101170 url: https://www.mdpi.com/2072-4292/11/10/1170
[21]	郭良迁, 薄万举, 陈宇坤, 等. 天津地区的垂直形变与构造活动研究[J]. 大地测量与地球动力学, 2009, 29(5):1-5.
[21]	Guo L Q, Bo W J, Chen Y K, et al. Vertical deformation and tectonic activity in Tianjin area[J]. Journal of Geodesy and Geodynamics, 2009, 29 (5):1-5.
[22]	白泽朝, 靳国旺, 张红敏, 等. 天津地区Sentinel-1A雷达影像PS-InSAR地面沉降监测[J]. 测绘科学技术学报, 2017, 34(3):6.
[22]	Bai Z C, Jin G W, Zhang H M, et al. Subsidence monitoring of Tianjin using PS-InSAR technique with Sentinel-1A[J]. Journal of Geomatics Science and Technology, 2017, 34(3):6.
[23]	邵继彭. 扩大天津东部防潮防线范围完善防潮体系探讨[J]. 海河水利, 2019(1):18-19,29.
[23]	Shao J P. Discussion on expanding the scope of dampproof defense line in the east of Tianjin and perfecting the dampproof system[J]. Haihe Water Conservancy, 2019(1):18-19,29.
[24]	王威, 王淼, 韦劲松, 等. 南水北调中线工程与天津地面沉降防治关系研究[J]. 南水北调与水利科技, 2012, 10(3):22-26.
[24]	Wang W, Wang M, Wei J S, et al. Relationship between the middle route of South-to-North Water Diversion Project and land subsidence control in Tianjin[J]. South-to-North Water Diversion and Water Science and Technology, 2012, 10(3):22-26.

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