Unraveling hydrochemical formation and evolution mechanism of river water and groundwater in an arid inland river basin (northwest China): A multi-technique approach
Nuan Yang, Xinming Song, Enke Hou, Guangcai Wang, Liang Guo
Abstract
The Delingha Basin is located on the northeastern Qinghai-Tibet Plateau, a climate-sensitive transitional zone. Hydrochemical compositions of river water and groundwater contain abundant hydrological cycle information, while controlling mechanisms remain poorly quantified. This study integrates multivariate statistics including correlation analysis, Self-Organizing Maps (SOM), Principal Component Analysis (PCA) and Positive Matrix Factorization (PMF) with main ions and stable isotopes to decipher recharge source, hydrochemical characteristics and controlling factors for elucidating hydrochemical evolution mechanism. New hydrological insights for the region: River water and groundwater are recharged by mountain precipitation. SOM-PCA-PMF indicate hydrochemical characteristics vary spatially due to water-rock interaction. PMF further reveals distinct spatial patterns in five hydrochemical contribution factors (calcite and dolomite, gypsum, halite, mirabilite, cation exchange). A difference–similarity–difference pattern is observed along the flow path in the great contributions (>25 %) to river water and groundwater hydrochemistry. The hydrochemical compositions in the mid-rear alluvial-proluvial plain are governed by gypsum and halite for river water, but additional carbonate and cation exchange influences for phreatic water, indicating groundwater recharge via river seepage and lateral runoff. Further downgradient, similar contributing factors (calcite, dolomite, gypsum, cation exchange) indicate groundwater discharge. Consistent controls and stable isotopes confirm hydraulic connection between phreatic and confined water, resulting in the recurrence of different dominant contributions. These findings enhance hydrological cycle cognition and water resources allocation in arid/semi-arid areas • Coupling SOM-PCA-PMF reveal river water and groundwater chemistry evolution. • River water and groundwater chemistry compositions exhibit spatial variations. • Water-rock interaction, evaporation and mixing are major controlling factors. • There is a certain hydraulic relationship between water bodies.