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Open Access

Tracing runoff components in the headwater area of Heihe River by isotopes and hydrochemistry

Han Zhang1,2,4Zong-yu Chen3( )Chang-yuan Tang4
Key Laboratory of Groundwater Sciences and Engineering, Ministry of Natural Resources. Zhengding 050803, Hebei, China
Institute of Hydrogeology and Environmental Geology, Chinese Academy of Geological Sciences, Shijiazhuang 050061, China
Comprehensive Survey and Management Center for Natural Resources, China Geological Survey, Beijing 100055, China
Chiba University, Matsudo 648, 2718510, Chiba, Japan
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Abstract

Since water resources of the Heihe River Basin are primarily in the form of surface runoff in the Qilian Mountains, identifying its sources and components is essential for researchers to understand water cycling and transformation in the basin. It will help to properly exploit water resources, and contribute to ecological environment construction. The paper uses the isotope data of hydrogen and oxygen in water and hydrochemistry data collected at a high altitude to trace the sources of surface runoff in Heihe River in rainy season and uses the three-component mixing model to estimate the contribution of each component to runoff. Results indicate that surface water consists of precipitation, melt water and groundwater, with precipitation being the primary component and contributing to 59%–64% of runoff. Melt water and groundwater account for 15%–25% and 12%–22%, respectively. Precipitation accounts for 60%, groundwater for 22% and glacial melt water for 18% of the outflow in the main stream of the Heihe River. The composition is of great significance for water cycling and conversion research as well as water resource evaluation and management.

Keywords

Qilian MountainsComponents of surface runoffIsotopeMixing model

References

 

Chang Q, Ma R, Sun Z, et al. 2018. Using isotopic and geochemical tracers to determine the contribution of glacier-snow meltwater to streamflow in a partly glacierized alpine-gorge catchment in northeastern Qinghai-Tibet Plateau. Journal of Geophysical Research: Atmospheres, 123: 10037−10056.
Crossref Google Scholar
 
Chen ZY, Qi JX, Zhang ZJ, et al. 2010. Application of isotopic hydrogeology in typical basins in North China. Beijing: Science Press.
 
Clark ID, Fritz P. 1997. Environmental isotopes in Hydrogeology. Lewis Publishers.
 

Ding HW, He ML, Cao BY, et al. 2000. The environmental geological problems of the water resources during the development and using in the area of middle and lower reaches of Heihe. Arid zone research, 17(4): 12−16. (in Chinese)
Google Scholar
 

Gui J, ZongjieLi ZJ, Yuan RF, et al. 2019. Hydrograph separation and the influence from climate warming on runoff in the north-eastern Tibetan Plateau. Quaternary International, 525: 45−53.
Crossref Google Scholar
 

Herath IK, Wu SJ, Ma MH, et al. 2019. Tracing controlling factors of riverine chemistry in a headwater tributary of the Yangtze River, China, inferred from geochemical and stable isotopic signatures. Environment Science Pollution Research, 26: 23899−23922.
Crossref Google Scholar
 

Fan XP. 1991. Characteristics of the stream-aquifer systems and rational utilization of water resources in the Heihe River. Gansu Geology, 12: 1−16. (in Chinese)
Google Scholar
 

Fang JZ, Yi P, Stockinger M, et al. 2022. Investigation of factors controlling the runoff generation mechanism using isotope tracing in large-scale nested basins. Journal of Hydrology, 615(Part A): 128728.
Crossref Google Scholar
 
Gao QZ, Li FX, 1991. Development and utilization of water resources in Heihe River catchment. Lanzhou: Gansu science and technology press.
 
Kendall C, Mcdonnell JJ. 1998. Isotope tracers in catchment hydrology. Elsevier, Amsterdam.
 

Lan YC, Kang ES, Zhang JS, et al. 2002. Study on the water resources and its rational development and utilization in Heihe River basin. Journal of Lanzhou University (Natural Sciences), 38(5): 108−114. (in Chinese)
Google Scholar
 

Li X, Cheng G, Fu B, et al. 2022. Linking critical zone with watershed science: The example of the Heihe River basin. Earth’s Future, 10: e2022EF002966.
Crossref Google Scholar
 

Li ZJ, Li ZX, Fan XJ, et al. 2020. The sources of supra-permafrost water and its hydrological effect based on stable isotopes in the third pole region. Science of The Total Environment, 715: 136911.
Crossref Google Scholar
 

Liu ZW, Chen RS, Song YX, et al. 2014. Water holding capacity of mosses under alpine shrubs in Qilian Mountains. Arid Land Geography, 37(4): 696−703. (in Chinese)
Google Scholar
 

Nie ZL, Chen ZY, Shen JM, et al. 2005. Environmental isotopes as tracers of hydrological cycle in the recharge area of the Heihe River. Geography and Geo-Information Science, 21(1): 104−108. (in Chinese)
Google Scholar
 

Pan Z, Ma R, SunZY, et al. 2022. Integrated hydrogeological and hydrogeochemical dataset of an alpine catchment in the northern Qinghai–Tibet Plateau. Earth System Science Data, 14: 2147−2165.
Crossref Google Scholar
 

Pan Z, Sun ZY, Ma R, et al. 2018. Isotopic investigation of rainfall-runoff generation in an Alpine catchment in headwater regions of Heihe river, Northeast Qinghai-Tibet Plateau. Earth Science, 43(11): 4226−4236. (in Chinese)
Google Scholar
 

Shi DP, Tan HB, Chen X, et al. 2021. Uncovering the mechanisms of seasonal river–groundwater circulation using isotopes and water chemistry in the middle reaches of the Yarlungzangbo River, Tibet. Journal of Hydrology, 603(Part C): 127010.
Crossref Google Scholar
 
Sophocleous M. 2002. Interactions between groundwater and surface water: The state of the science. Hydrogeology Journal, 10: 52–67.
Crossref
 
Wang GX, Cheng GD, 1998. Changes of hydrology and ecological environment during late 50 years in the heihe River basin. Journal of desert research, 18(3): 233-238. (in Chinese)
 

Wang JY, Che KJ, Yan KL, et al. 1999. Analysis of the runoff components in the forestry areas of the Qilian Mountains and their temporal and spatial variation. Journal of glaciology and geocryology, 21(1): 59−63. (in Chinese)
Google Scholar
 

Wu B, Wang S, Wang WX, et al. 2019. Impact of future climate change on water resources in the arid regions of Northwest China based on surface water-groundwater coupling model: A case study of the middle reaches of the Heihe River. Geology in China, 46(2): 369−380. (in Chinese)
Google Scholar
 

Zhao LJ, Eastoe CJ, Liu XH, et al. 2018. Origin and residence time of groundwater based on stable and radioactive isotopes in the Heihe River Basin, northwestern China. Journal of Hydrology: Regional Studies, 18: 31−49.
Crossref Google Scholar
 

Zhao LJ, Yin L, Xiao HL, et al. 2011. Isotopic evidence for the moisture origin and composition of surface runoff in the headwaters of the Heihe River basin. Chinese Science Bulletin: 56. (in Chinese)
Crossref Google Scholar
 

Zhang H, Chen ZY, Tang CY. 2021. Quantifying groundwater recharge and discharge for the middle reach of Heihe River of China using isotope mass balance method. Journal of Groundwater Science and Engineering, 9(3): 225−232.
Google Scholar
Journal of Groundwater Science and Engineering
Volume 10 Issue 4,
December 2022
Pages 405-412
DOI: 10.19637/j.cnki.2305-7068.2022.04.008
Cite this article:
Zhang H, Chen Z-y, Tang C-y. Tracing runoff components in the headwater area of Heihe River by isotopes and hydrochemistry. Journal of Groundwater Science and Engineering, 2022, 10(4): 405-412. https://doi.org/10.19637/j.cnki.2305-7068.2022.04.008

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Received: 06 July 2022
Accepted: 03 November 2022
Published: 27 December 2022
© 2022 Journal of Groundwater Science and Engineering Editorial Office
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