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Volume 40 Issue 3
Jun.  2021
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Article Navigation >  CARSOLOGICA SINICA  > 2021  >  40(3): 420-429
WANG Dawei, QIAO Xiaojuan, GAO Bo, JIA Xiaojun. Dynamic characteristics and influence factors of discharge of the Longzici karst spring in Shanxi Province[J]. CARSOLOGICA SINICA, 2021, 40(3): 420-429.
Citation: WANG Dawei, QIAO Xiaojuan, GAO Bo, JIA Xiaojun. Dynamic characteristics and influence factors of discharge of the Longzici karst spring in Shanxi Province[J]. CARSOLOGICA SINICA, 2021, 40(3): 420-429.
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Dynamic characteristics and influence factors of discharge of the Longzici karst spring in Shanxi Province

  • 1.

    School of Earth and Planetary Sciences, University of Chinese Academy of Sciences

  • 2.

    School of Earth and Planetary Sciences, University of Chinese Academy of Sciences/Laboratory of Computational Geodynamics, University of Chinese Academy of Sciences

  • 3.

    Guozhuang Spring Management Office, Shanxi Province

  • 4.

    Hydrology and Water Resources Investigation Bureau

  • Publish Date: 2021-06-25
    Abstract
  • The Longzici spring is located in front of the Xishan mountains, 13 km southwest of Linfen City, Shanxi Province. The spring area is 2,250 km2. The exposed strata are dominated by Cambrian and Ordovician, Carboniferous Permian, Triassic and Cenozoic Quaternary. Overall, the geological structure of the spring area is featured by uplift on the north and south sides, and a depression in the central part. The north is the Longzici syncline, which forms syncline mountains in topography, and the south is an underground structure sloping to the north or northeast. The recharge in this area is dominated by precipitation infiltration in the exposed carbonate rock area, followed by surface runoff infiltration recharge from the Carboniferous-Permian sand shale area. The aquifer is dominated by the Cambrian-Ordovician carbonate water-bearing rock group.In order to explore the spatial-temporal variation characteristics and response laws of spring dynamics in karst water-bearing systems, this paper uses a 65-year time series of spring water flow and precipitation monitoring data from 1954 to 2018 and mining data from 1990 to 2018, and employs the stepwise analysis of multiple regression methods to establish the response relationship models of spring discharge, precipitation and mining in stages. Then using the models we simulate and predict spring discharge over a long time sequence. The research results of this paper can provide data support for the prevention and control of the flow attenuation in the Longzici spring area. The conclusions of this article are as follows,(1) The precipitation ranges 287.2-868.7 mm with a multi-year average 541.1 mm in the spring area. More precipitation occurred after 1990 than before, and there was a four-month time lag in the response of spring flow to precipitation replenishment during the year. The average extraction volume of karst water for many years is 3.233 million cubic meters, and the average extraction volume of pore water in the piedmont area is 8.243 million cubic meters. When the extraction volume remains at a relatively high level, the spring flow generally shows a significant downward trend.(2) The spring flow fluctuates between 2.94-8.39 m3·s-1, and the multi-year average flow is 4.74 m3·s-1. Before 1990, the average flow was 5.61m3·s-1, while after 1990 it was 3.68 m3·s-1. In addition to factors such as mining and precipitation that affect spring flow, local coal mining activities also affect spring flow dynamics, which need to be analyzed in subsequent studies.(3) The results of multiple regression show that the main influencing factors of spring flow in the first stage (1954-1989) were the precipitations of the previous year and the previous two years. In the second stage (1990-2018), the spring flow was restricted by both precipitation and mining and was negatively correlated with the mining volume of the year, most strongly affected by it; followed by the precipitation of the previous year and the previous two years. Error analysis shows that the flow error in the entire time series is 11.62%, implying a good simulation effect.

     

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