2D seismic and high-density resistivity sounding reveal the shallow three-dimensional geological structure characteristics of Xiong'an New Area

LONG Hui; XIE Xing-Long; LI Feng-Zhe; REN Zheng-Wei; WANG Chun-Hui; GUO Shu-Jun

doi:10.11720/wtyht.2022.1319

2022 Vol. 46, No. 4

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Article navigation > Geophysical and Geochemical Exploration > 2022 > 46(4): 808-815

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LONG Hui, XIE Xing-Long, LI Feng-Zhe, REN Zheng-Wei, WANG Chun-Hui, GUO Shu-Jun. 2022. 2D seismic and high-density resistivity sounding reveal the shallow three-dimensional geological structure characteristics of Xiong'an New Area. Geophysical and Geochemical Exploration, 46(4): 808-815. doi: 10.11720/wtyht.2022.1319

Citation:

LONG Hui, XIE Xing-Long, LI Feng-Zhe, REN Zheng-Wei, WANG Chun-Hui, GUO Shu-Jun. 2022. 2D seismic and high-density resistivity sounding reveal the shallow three-dimensional geological structure characteristics of Xiong'an New Area. Geophysical and Geochemical Exploration, 46(4): 808-815. doi: 10.11720/wtyht.2022.1319

2D seismic and high-density resistivity sounding reveal the shallow three-dimensional geological structure characteristics of Xiong'an New Area

Center for Hydrogeology and Environmental Geology Survey,China Geology Survey,Baoding 071051,China

Received Date: 11 June 2021

Revised Date: 20 August 2022

Publish Date: 17 August 2022

Abstract

Abstract

The Xiong'an New Area is located in the middle part of the Jizhong Plain.The Cenozoic strata in the underground structure of the area have a large thickness,good stratification,and relatively stable tectonic activities.To finely determine the shallow geological structures,ascertain the fault structure characteristics,and improve the shallow exploration accuracy,this study combined two-dimensional seismic surveys and high-density resistivity sounding and made the following important progress.①This study finely determined the geological structure and the spatial distribution characteristics of fault structures at a depth of less than 200 m in the Xiong'an New Area;②This study constructed a three-dimensional visualized geological structure model,which intuitively displays the stratigraphic fluctuation pattern of Cenozoic strata and the spatial distribution of main fault structures;③This study analyzed and summarized the application of geophysical methods under the background of urbanization-induced high disturbance,including their exploration depths,horizontal and vertical resolution,response characteristics of geological bodies,and applicability.This study effectively supports and serves the planning,construction,and underground-space development and utilization in the Xiong'an New Area and serves as a reference for the geophysical exploration of urban underground space in hugely thick sedimentary basins.
- Xiong'an New Area /
- 2D seismic /
- high-density resistivity sounding /
- 3D geological structure /
- fracture structure

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References

[1]	孙冬胜, 刘池阳, 杨明慧, 等. 渤海湾盆地冀中坳陷中区中新生代复合伸展构造[J]. 地质论评, 2004, 50(5):484-491. Google Scholar
[2]	Sun D S, Liu C Y, Yang M H, et al. Study on complex extensional structures in the middle Jizhong depression in the Bohai bay basin[J]. Geological Review, 2004, 50(5):484-491. Google Scholar
[3]	于长春, 乔日新, 张迪硕. 雄安新区航磁推断的三维基底构造特征[J]. 物探与化探, 2017, 41(3):385-391. Google Scholar
[4]	Yu C C, Qiao R X, Zhang D S. The basement tectonic characteristics from interpretation of aeromagnetic data in Xiong'an region[J]. Geophysical and Geochemical Exploration, 2017, 41(3):385-391. Google Scholar
[5]	杨百存, 秦四清, 薛雷, 等. 雄安新区地震危险性评估[J]. 地球物理学报, 2017, 60(12):4644-4654. Google Scholar
[6]	Yang B C, Qin S Q, Xue L, et al. Seismic hazard assessment in the Xiongan New Area[J]. Chinese Journal of Geophysics, 2017, 60(12):4644-4654. Google Scholar
[7]	何登发, 单帅强, 张煜颖, 等. 雄安新区的三维地质结构:来自反射地震资料的约束[J]. 中国科学, 2018, 48(9):1207-1222. Google Scholar
[8]	He D F, Shan S Q, Zhang Y Y, et al. 3-D geologic architecture of Xiongan New Area: Constraints from seismic reflection data[J]. Science China, 2018, 48(9):1207-1222. Google Scholar
[9]	佘雅文, 付广裕, 高原, 等. 华北地区中东部岩石圈挠曲与均衡特性以及地震活动性分析[J]. 地球物理学报, 2018, 61(11):4448-4458. Google Scholar
[10]	She Y W, Fu G Y, Gao Y, et al. Flexure of the lithosphere,isostatic characteristic and seismicity in middle east area of North China[J]. Chinese Journal of Geophysics, 2018, 61(11):4448-4458. Google Scholar
[11]	商世杰, 丰成君, 谭成轩, 等. 雄安新区附近主要隐伏断裂第四纪活动性研究[J]. 地球学报, 2019, 40(6):836-846. Google Scholar
[12]	Shang S J, Feng C J, Tan C X, et al. Quaternary activity study of major buried faults near Xiongan New Area[J]. Acta Geoscientica Sinica, 2019, 40(6):836-846. Google Scholar
[13]	邓起东. 城市活动断裂探测和地震危险性评价问题[J]. 地震地质, 2002, 24(4):601-605. Google Scholar
[14]	Deng Q D. Exploration and seismic hazard assessment of active faults in urban areas[J]. Seismology and Geology, 2002, 24(4):601-605. Google Scholar
[15]	张迪, 吴中海, 李家存, 等. 综合多频率地质雷达天线探测活断层浅层结构——以玉树活动断裂为例[J]. 地质力学学报, 2019, 25(6):1138-1149. Google Scholar
[16]	Zhang D, Wu Z H, Li J C, et al. The application of multi-frequency GPR antenna for imaging the shallow subsurface features in the Yushu active fault[J]. Journal of Geomechanics, 2019, 25(6):1138-1149. Google Scholar
[17]	赵镨, 姜杰, 王秀荣. 城市地下空间探测关键技术及发展趋势[J]. 中国煤炭地质, 2017, 29(9):61-66. Google Scholar
[18]	Zhao P, Jiang J, Wang X R. Urban underground space exploration key technologies and development trend[J]. Coal Geology of China, 2017, 29(9):61-66. Google Scholar
[19]	刘永生, 龙桃城, 刘仁义. 瞬变电磁法在城市地质调查应用中有关问题的探讨[J]. 岩土工程技术, 2019, 33(3):173-177. Google Scholar
[20]	Liu Y S, Long T C, Liu R Y. Discussion on relevant problems in application of TEM in urban geological survey[J]. Geotechnical Engineering Technique, 2019, 33(3):173-177. Google Scholar
[21]	张保卫, 张凯, 岳航羽, 等. 江苏滩涂区浅层地震探测方法技术应用[J]. 物探与化探, 2018, 42(1):144-153. Google Scholar
[22]	Zhang B W, Zhang K, Yue H Y, et al. Application of shallow seismic exploration method in Tidal-flat region of Jiangsu Province[J]. Geophysical and Geochemical Exploration, 2018, 42(1):144-153. Google Scholar
[23]	张晓波, 王成善, 王志辉, 等. 广东省潼湖生态智慧区浅层地球物理探测与地层物性分析[J]. 地质学报, 2019, 93(11):2935-2946. Google Scholar
[24]	Zhang X B, Wang C S, Wang Z H, et al. Shallow geophysical exploration and stratigraphic properties analysis of the Tonghu ecological smart zone,Guangdong Province[J]. Acta Geologica Sinica, 2019, 93(11):2935-2946. Google Scholar
[25]	王朱亭, 张超, 姜光政, 等. 雄安新区现今地温场特征及成因机制[J]. 地球物理学报, 2019, 62(11):4313-4322. Google Scholar
[26]	Wang Z T, Zhang C, Jiang G Z, et al. Present-day geothermal field of Xiongan New Area and its heat source mechanism[J]. Chinese Journal of Geophysics, 2019, 62(11):4313-4322. Google Scholar
[27]	万天丰. 中国大地构造学[M]. 北京: 地质出版社, 2011. Google Scholar
[28]	Wan T F. The tectonics of China[M]. Beijing: Geological Publishing, 2011. Google Scholar
[29]	徐杰, 高战武, 宋长青, 等. 太行山山前断裂带的构造特征[J]. 地震地质, 2000, 22(2):111-122. Google Scholar
[30]	Xu J, Gao Z W, Song C Q, et al. The structural characters of the piedmont fault zone of Taihang Mountain[J]. Seismology and Geology, 2000, 22(2):111-122. Google Scholar
[31]	杨明慧, 刘池阳, 杨斌谊, 等. 冀中坳陷古近纪的伸展构造[J]. 地质论评, 2002, 48(1):58-67. Google Scholar
[32]	Yang M H, Liu C Y, Yang B Y, et al. Extensional structures of the Paleogene in the central Hebei Basin[J]. China Geological Review, 2002, 48(1):58-67. Google Scholar
[33]	范玉璐, 谭成轩, 张鹏, 等. 雄安新区现今地应力环境及其对构造稳定性影响研究[J]. 地球学报, 2020, 41(4):482-491. Google Scholar
[34]	Fan Y L, Tan C X, Zhang P, et al. A study of current in-situ stress state and its influence on tectonic stability in the Xiongan New Area[J]. Acta Geoscientica Sinica, 2020, 41(4):482-491. Google Scholar
[35]	郝爱兵, 吴爱民, 马震, 等. 雄安新区地上地下工程建设适宜性一体化评价[J]. 地球学报, 2018, 39(5):513-522. Google Scholar
[36]	Hao A B, Wu A M, Ma Z, et al. A study of engineering construction suitability integrated evaluation of surface-underground space in Xiongan New Area[J]. Acta Geoscientica Sinica, 2018, 39(5):513-522. Google Scholar
[37]	张竞, 马震, 吴爱民, 等. 基于岩性光谱特征的雄安新区地面古河道识别研究[J]. 地球学报, 2018, 39(5):542-548. Google Scholar
[38]	Zhang J, Ma Z, Wu A M, et al. A study of paleochannels interpretation by the spectrum of lithology in Xiongan New Area[J]. Acta Geoscientica Sinica, 2018, 39(5):542-548. Google Scholar
[39]	马震, 夏雨波, 王小丹, 等. 雄安新区工程地质勘查数据集成与三维地质结构模型构建[J]. 中国地质, 2019, 46(S2):123-129. Google Scholar
[40]	Ma Z, Xia Y B, Wang X D, et al. Integration of engineering geological investigation data and construction of a 3D geological structure model in the Xiongan New Area[J]. Geology in China, 2019, 46(S2):123-129. Google Scholar
[41]	酆少英, 龙长兴, 高锐, 等. 高分辨折射和浅层反射地震方法在活断层探测中的联合应用[J]. 地震学报, 2010, 32(6):718-724,767. Google Scholar
[42]	Feng S Y, Long C X, Gao R, et al. Joint application of high-resolution refraction and shallow reflection exploration approach to active fault survey[J]. Acta Seismologica Sinica, 2010, 32(6):718-724,767. Google Scholar
[43]	严加永, 孟贵祥, 吕庆田, 等. 高密度电阻率测深的进展与展望[J]. 物探与化探, 2012, 36(4):576-584. Google Scholar
[44]	Yan J Y, Meng G X, Lyu Q T, et al. The progress and prospect of the electrical resistivity imaging survey[J]. Geophysical and Geochemical Exploration, 2012, 36(4):576-584. Google Scholar
[45]	马岩, 李洪强, 张杰, 等. 雄安新区城市地下空间探测技术研究[J]. 地球学报, 2020, 41(4):535-542. Google Scholar
[46]	Ma Y, Li H Q, Zhang J, et al. Geophysical technology for underground space exploration in Xiongan New Area[J]. Acta Geoscientica Sinica, 2020, 41(4):535-542. Google Scholar
[47]	邓小娟, 酆少英, 朱学申, 等. 利用二维活断层探测资料构建焦作地区浅层三维构造模型[J]. 大地测量与地球动力学, 2020, 40(7):682-687. Google Scholar
[48]	Deng X J, Feng S Y, Zhu X S, et al. Using the 2D active fault seismic data to construct the shallow 3D structural model of Jiaozuo area[J]. Journal of Geodesy and Geodynamics, 2020, 40(7):682-687. Google Scholar
[49]	刘顺昌, 徐德馨, 张春梅. 武汉都市发展区工程地质三维模型建设及应用[J]. 城市勘测, 2016(4):160-163. Google Scholar
[50]	Liu S C, Xu D X, Zhang C M. Build and application of the 3D geological model in WuHan urban development Zone[J]. Urban Geotechnical Investigation & Surveying, 2016(4):160-163. Google Scholar