Conversion of precipitation， surface water， groundwater and mine water affected by coal mining in the Hailiutu River Basin， Inner Mongolia， China

doi:10.7522/j.issn.1000-694X.2022.00027

Journal of Desert Research ›› 2022, Vol. 42 ›› Issue (5): 146-157.DOI: 10.7522/j.issn.1000-694X.2022.00027

Previous Articles Next Articles

Conversion of precipitation， surface water， groundwater and mine water affected by coal mining in the Hailiutu River Basin， Inner Mongolia， China

Qian Li(), Long Ma(), Tingxi Liu, Shuo Wang

College of Water Conservancy and Civil Engineering，Inner Mongolia Agricultural University，Hohhot 010018，China

Received:2021-10-15 Revised:2022-03-02 Online:2022-09-20 Published:2022-09-22
Contact: Long Ma

Abstract

Abstract:

Coal mining changes the hydrogeological conditions of the basin. It is of great significance to study the transformation relationship between precipitation， surface water， groundwater and mine water under the influence of coal mining. Taking the Hailiutu basin as the study area. The transformation relationship of precipitation surface water groundwater mine water under the influence of coal mining is analyzed by mathematical statistics， Piper trigram and hydrogen and oxygen isotope diagram. The results show that the content of $S O 4 2 -$ 、 $N a +$ 、 $M g 2 +$ in surface water increases greatly under the influence of coal mining； The transformation relationship between precipitation， surface water and groundwater in natural watershed is mainly the recharge of groundwater by surface water infiltration， with an average contribution rate of 56.7%； The conversion relationship between different water in Hailiutu and Nalin basin is mainly the recharge of surface water to groundwater in the mining area and its downstream. The average contribution rate increased to 69.3% and 59.4% compared with the upstream natural watershed. The main source of mine water is groundwater of the overlying Sarausu Formation with a recharge ratio of 72.4%. Coal mining speeds up the confluence of groundwater from overlying aquifer to goaf.

Key words: mine water, groundwater, surface water, conversion relationship

CLC Number:

P641.1

Qian Li, Long Ma, Tingxi Liu, Shuo Wang. Conversion of precipitation， surface water， groundwater and mine water affected by coal mining in the Hailiutu River Basin， Inner Mongolia， China[J]. Journal of Desert Research, 2022, 42(5): 146-157.

Figures/Tables 10

Fig.1 Location of the studied area and sample points

Fig.2 Sketch map of hydrogeologic section

Fig.3 pH， TDS， EC and ion trends of surface water （A） and groundwater （B） in the study area

Fig.4 Different water samples of Piper trilinear diagram

Fig.5 The hydrogen and oxygen isotopes of precipitation

Fig.6 The hydrogen and oxygen isotopes of surface water， groundwater and mine water

Fig.7 Variation of TDS and δ18O concentration of surface water and groundwater in natural basin

Fig.8 Variation of TDS and δ18O concentration of surface water， ground water and mine water in the mining area

Fig.9 Variation of TDS and δ18O concentration of surface water and groundwater in the downstream of the mine

Fig.10 Different water samples of Gibbs plots in the study area

References 48

1	Sun W Y， Mu X M， Song X Y，et al.Changes in extreme temperatureand precipitation events in the Loess Plateau （China） during 1960-2013 under global warming［J］.Atmospheric Research，2016，168（22）：33-48.
2	Almnaserr N， Sankarasubramanian A.Role of climate variability in modulating the surface water and ground-water interaction over the southeast United States［J］.Journal of Hydrologic Enginee-ring，2012，17（9）：1001-1010.
3	黄元，岳德鹏，于强，等.磴口县地表水与地下水时空变化特征及交互作用［J］.中国沙漠，2019，39（1）：161-170.
4	刘芳，曹广超，曹生奎，等.祁连山南坡主要流域河水稳定同位素特征及补给关系［J］.中国沙漠，2020，40（6）：151-161.
5	Guang Y， He X L， Li X L，et al.Transformation of surface water and groundwater and water balance in the agricultural irrigation area of the Manas River Basin，China［J］.International Journal of Agricultural and Biological Engineering，2017，10（4）：107-118.
6	Sun X S， Lu S， Gao R M，et al.Groundwater flow path determination during riverbank filtration affected by groundwater exploition：a case study of Liao River，Northeast China［J］.Hydrological Science Journal，2017，62（14）：2331-2347.
7	Hao S， Li F， Li Y，et al.Stable isotope evidence for identifying the recharge mechanisms of precipitation，surface water，and groundwater in the Ebinur Lake basin［J］.Science of the Total Environment，2019，657（20）：1041-1050.
8	Qin W， Han D， Song X，et al.Environmental isotopes （δ ¹⁸O，δ ²H，²²²Rn） and hydrochemical evidence for understanding rainfall-surface water-groundwater transformations in a polluted karst area［J］.Journal of Hydrology，2021，592：125748.
9	孙从建，陈伟.基于稳定同位素的海河源区地下水与地表水相互关系分析［J］.地理科学，2018，38（5）：790-799.
10	雷义珍，曹生奎，曹广超，等.基于氢氧稳定同位素和水化学的青藏高原高寒内陆河流域水文过程示踪研究［J］.地理研究，2021，40（5）：1239-1252.
11	Katsanou K， Lambrakis N， D'AlesssandroL W，et al.Chemical parameters as natural tracers in hydrogeology：a case study of Louros karst system，Greece［J］.Hydrogeology Journal，2017（25）：487-499.
12	孔令健，姜春露，郑刘根，等.淮北临涣矿采煤沉陷区不同水体水化学特征及其影响因素［J］.湖泊科学，2017，29（5）：1158-1167.
13	Daniele P， Josie G， Luis A H，et al.Water sources for root water uptake：using stable isotopes of hydrogen and oxygen as a research tool in agricultural and agroforestry systems［J］.Agriculture Ecosystems & Environment，2020，291：106790.
14	Fu C C， Lu X Q， Ma J F，et al.A hydrochemistry and multi-isotopic study of groundwater origin and hydrochemical evolution in the middle reaches of the Kuye River basin［J］.Applied Geochemistry，2018，98：82-93.
15	Lin Y J， Zheng M P， Ye C Y.Hydromagnesite precipitation in the Alkaline Lake Dujiali，central Qinghai-Tibetan Plateau： constraints on hydromagnesite precipitation from hydrochemistry and stable isotopes［J］.Applied Geochemistry，2017，78：139-148.
16	韩玉，卢文喜，李峰平，等.浑河流域地表水地下水水质耦合模拟［J］.中国环境科学，2020，40（4）：1677-1686.
17	Yang Q， Mu H， Guo J，et al.Temperature and rainfall amount effects on hydrogen and oxygen stable isotope in precipitation［J］.Quaternary International，2019，519：25-31.
18	Xia C， Liu G， Mei J，et al.Characteristics of hydrogen and oxygen stable isotopes in precipitation and the environmental controls in tropical monsoon climatic zone［J］.International Journal of Hydrogen Energy，2019，44（11）：5417-5427.
19	Gammons C H， Poulson O S R， Pellicori D A，et al.The hydrogen and oxygen isotopic composition of precipitation，evaporated mine water，and river water in Montana，USA［J］.Journal of Hydrology，2006，328（1/2）：319-330.
20	Bethke P M， Rye R O.Environment of ore deposition in the Creede mining district，San Juan Mountains，Colorado：part IV，source of fluids，from oxygen，hydrogen，and carbon isotope studies［J］.Economic Geology，1979，74（8）：1832-1851.
21	Wo E K P， Wirmvem M J， Fantong W Y，et al.Isotopic composition of precipitation and groundwater onshore of the Rio del Rey Basin，southwest Cameroon：local meteoric lines and recharge［J］.Applied Water Science，2021，11（8）：1-14.
22	Reynaga D K M， Millaire J F， Baldras X C，et al.Building Mexican isoscapes：oxygen and hydrogen isotope data of me-teoric water sampled across Mexico［J］.Data in Brief，2021，36：101296.
23	姜海宁，谷洪彪，迟宝明，等.新疆昭苏-特克斯盆地地表水与地下水转化关系研究［J］.干旱区地理，2016，39（5）：1078-1088.
24	杜明亮，吴彬，胡钟林，等.霍景涅里辛沙漠地下水化学和同位素特征［J］.中国沙漠，2018，38（4）：858-864.
25	Chu H B， Wei J， Wang R，et al.Characterizing the interaction of groundwater and surface water in the karst aquifer of Fangshan，Beijing （China）［J］.Hydrogeology Journal，2017，25（2）：575-588.
26	曾妍妍，周金龙，贾瑞亮，等.新疆祁漫塔格地区地表水水化学特征及成因分析［J］.干旱区资源与环境，2017，31（6）：64-70.
27	Chen J S， Sun X X， Gu W Z，et al.Isotopic and hydroche-mical data to restrict the origin of the groundwater in the Badain Jaran Desert，Northern China［J］.Geochemistry International，2012，50（5）：455-465.
28	Zhu B Q， Yang X P.The origin and distribution of soluble salts in the sand seas of northern China［J］.Geomorphology，2010，123（3）：232-242.
29	Bajracharya R， Nakamura A T， Ghimre S，et al.Identifying groundwater and river water interconnections using hydro-chemistry，stable isotopes，and atatistical methods in Hanu-mante River，Kathmandu Valley，Central Nepal［J］.Water，2020，12（6）：1524.
30	Wang P， Yu J J， hang Y C，et al.Groundwater recharge and hydrogeochemical evolution in the Ejina Basin，northwest China［J］.Journal of Hydrology，2013，476：72-86.
31	Xing L N， Guo H N， Zhan Y H.Groundwater hydroche-mical characteristics and processes along flow paths in the North China Plain［J］.Journal of Asian Earth Sciences，2013，70/71（1）：250-264.
32	孙亚军，崔思源，徐智敏，等.西部典型侏罗系富煤区地下水补径排的同位素特征［J］.煤炭学报，2017，42（2）：293-299.
33	Jahanshahi R， Zare M.Delineating the origin of groundwater in the Golgohar Mine Area of Iran using stable isotopes of ²H and ¹⁸O and hydrochemistry［J］.Mine Water and the Environment，2017，36（4）：550-563.
34	He S Y， Richards K.Stable isotopes in monsoon precipitation and water vapour in Nagqu，Tibet，and their implications for monsoon moisture［J］.Journal of Hydrology，2016，540：615-622.
35	Li W， Wang Q Q， Liu S L，et al.Study on the creep permeabi-lity of miningcracked N₂ laterite as the key aquifuge for presserv-ing water resources in Northwestern China［J］.Inter-national Journal of Coal Science & Technology，2018，5（3）：315-327.
36	刘佳驹，郭怀成.雅鲁藏布江河水氢氧同位素时空变化特征［J］.中国环境科学，2021，41（11）：5194-5200.
37	Craig H.Isotopic variations in meteoric waters［J］.Science，196，133（3465）：1702-1730.
38	Nofal S， Travi Y， Cognardplancq A L，et al.Impact of infiltrating irrigation and surface water on a Mediterranean alluvial aquifer in France using stable isotopes and hydrochemistry，in the context of urbanization and climate change［J］.Hydrogeology Journal，2019，27（6）：2211-2229.
39	Zhu G， Wu X， Ge J，et al.Influence of mining activities on gr-oundwater hydrochemistry and heavy metal migration using a self-oganizing map （SOM）［J］.Journal of Cleaner Produ-ction，2020，257：120664.
40	谷洪彪，迟宝明，王贺，等.柳江盆地地表水与地下水转化关系的氢氧同位素和水化学证据［J］.地球科学进展，2017（8）：789-799.
41	郭巧玲，熊新芝，姜景瑞.窟野河流域地表水-地下水的水化学特征［J］.环境化学，2016，35（7）：1372-1380.
42	殷晓曦，陈陆望，谢文苹，等.采动影响下矿区地下水主要水-岩作用与水化学演化规律［J］.水文地质工程地质，2017，44（5）：33-39.
43	Gibbs R J.Meachanisms controlling world water chemistry［J］.Science，1970（3962）：1088-1090.
44	李书鉴，韩晓，王文辉，等.无定河流域地表水地下水的水化学特征及控制因素［J］.环境科学，2022，43（1）：220-229.
45	Yang Z， Zhou Y， Wenninger J，et al.Groundwater and surface-water interactions and impacts of human activities in the Hailiutu catchment，northwest China［J］.Hydrogeology Journal，2017，25（5）：1341-1355.
46	曾帝，吴锦奎，李洪源，等.西北干旱区降水中氢氧同位素研究进展［J］.干旱区研究，2020，37（4）：857-869.
47	冀瑞君，彭苏萍，范立民，等.神府矿区采煤对地下水循环影响：以窟野河中下游流域为例［J］.煤炭学报，2015，40（4）：938-943.
48	Zhang X， Li X， Gao X.Hydrochemistry and coal mining activity induced karst water quality degradation in the Niangziguan karst water system，China［J］.Environmental Science and Pollution Research，2016，23（7）：6286-6299.

[1]	Qi Zhang, Yonghong Su, Qi Feng, Tengfei Yu, Xiaohong Ma. Estimation of groundwater evapotranspiration of Populus euphratica forest ecosystem along desert river banks based on groundwater level dynamics [J]. Journal of Desert Research, 2022, 42(6): 243-254.
[2]	Lin Li, Hu Liu, Chengpeng Sun, Wenzhi Zhao. Groundwater evapotranspiration estimation based on soil moisture and water table measurements [J]. Journal of Desert Research, 2022, 42(6): 277-287.
[3]	Shenghui Zhou, Tingxi Liu, Limin Duan, Ru Ji, Chunyu Zhang. Hydrogeological characteristics of underwater aquifer in the Hailiutu River Basin [J]. Journal of Desert Research, 2021, 41(5): 103-110.
[4]	Lichao Zhuang, Naiang Wang, Xunhe Zhang, Liqiang Zhao, Xianbao Su. Analysis on the difference of the spatial model of lake ice freezing and melting in the Badain Jaran Desert [J]. Journal of Desert Research, 2021, 41(3): 214-223.
[5]	Wenbing Yang, Tao Wang, Wei Xiong, Hui Zou, Wei Feng, Yiben Cheng, Honglin Lian. Overview of hydrological principle of low vegetation coverage sand control [J]. Journal of Desert Research, 2021, 41(3): 75-80.
[6]	Jianhua He, Wenhua Qin, Jiabing Guo, Peiyuan Chen, Jinzhu Ma. The characteristics of groundwater trace elements and its controlling factors in Dunhuang Oasis [J]. Journal of Desert Research, 2021, 41(2): 109-119.
[7]	Tianyan Su, Wenjie Liu, Qiu Yang, Wei Mao. Review on response of soil carbon cycle to groundwater level change [J]. Journal of Desert Research, 2020, 40(5): 180-189.
[8]	Wang Lixiang, Cai Mingyu, Bai Xuelian, Qiao Rongrong, Ji Shuxin, Chang Xueli. Lake fluctuation and driving factors in the Wulanbuhe Desert of China [J]. Journal of Desert Research, 2020, 40(2): 59-67.
[9]	Sheng Danrui, Wen Xiaohu, Feng Qi, Wu Jun, Si Jianhua, Wu Min. Groundwater Nitrate Pollution and Human Health Risk Assessment in the Zhangye Basin, Gansu, China [J]. Journal of Desert Research, 2019, 39(5): 37-44.
[10]	Yang Yufan, Cao Shengkui, Feng Qi, Cao Guangchao, Liu Ying, Lei Yizhen. Spatial Distribution Characteristics of Composition of Stable Hydrogen and Oxygen Isotopes of Shallow Groundwater in Shaliu River Basin of Qinghai Lake [J]. Journal of Desert Research, 2019, 39(5): 45-53.
[11]	Huang Yuan, Yue Depeng, Yu Qiang, Zhang Qibin, Ma Huan. Spatiotemporal Variability and Interaction of Surface Water and Groundwater in Dengkou County [J]. Journal of Desert Research, 2019, 39(1): 161-170.
[12]	Du Mingliang, Wu Bin, Hu Zhonglin, Yu Liang, Wang Long, Guo Kaizheng. Characteristics of Hydrochemistry and Isotopes of Groundwater in the Hopenne Lee Sin Desert and Indicator Effects [J]. Journal of Desert Research, 2018, 38(4): 858-864.
[13]	Wu Min, Wen Xiaohu, Feng Qi, Yin Zhengliang, Yang Linshan. Assessment of Groundwater Quality Based on Random Forest Model in Arid Oasis Area [J]. Journal of Desert Research, 2018, 38(3): 657-663.
[14]	Yue Ning, Wei Guoxiao, Sun Peng, Dong Jun, Dang Huihui, Wang Gang, Huang Shaowen. Rainfall Infiltration Recharge and Its Responses to Climate Change in the Ulan Buh Desert [J]. JOURNAL OF DESERT RESEARCH, 2017, 37(5): 1016-1025.
[15]	Bai Yufeng, Xu Hailiang, Zhang Pei, Zhang Guangpeng, Ling Hongbo. Relation of Desert Vegetation Species Diversity and Aboveground Biomass to Groundwater Depth in the Lower Reaches of Tarim River [J]. JOURNAL OF DESERT RESEARCH, 2017, 37(4): 724-732.

Conversion of precipitation， surface water， groundwater and mine water affected by coal mining in the Hailiutu River Basin， Inner Mongolia， China

RichHTML

PDF

Knowledge

Abstract

Cite this article

share this article

Figures/Tables 10

References 48

Related Articles 15

Recommended Articles

Metrics

Comments