Abstract
AbstractGroundwater transit time is an essential hydrologic metric for groundwater resources management. However, especially in tropical environments, studies on the transit time distribution (TTD) of groundwater infiltration and its corresponding mean transit time (mTT) have been extremely limited due to data sparsity. In this study, we primarily use stable isotopes to examine the TTDs and their mTTs of both vertical and horizontal infiltration at a riverbank infiltration area in the Vietnamese Mekong Delta (VMD), representative of the tropical climate in Asian monsoon regions.Precipitation, river water, groundwater, and local ponding surface water were sampled for 3 to 9 years and analysed for stable isotopes (δ18O and δ2H), providing a unique data set of stable isotope records for a tropical region. We quantified the contribution that the two sources contributed to the local shallow groundwater by a novel concept of two‐component lumped parameter models (LPMs) that are solved using δ18O records.The study illustrates that two‐component LPMs, in conjunction with hydrological and isotopic measurements, are able to identify subsurface flow conditions and water mixing at riverbank infiltration systems. However, the predictive skill and the reliability of the models decrease for locations farther from the river, where recharge by precipitation dominates, and a low‐permeable aquitard layer above the highly permeable aquifer is present. This specific setting impairs the identifiability of model parameters. For river infiltration, short mTTs (<40 weeks) were determined for sites closer to the river (<200 m), whereas for the precipitation infiltration, the mTTs were longer (>80 weeks) and independent of the distance to the river.The results not only enhance the understanding of the groundwater recharge dynamics in the VMD but also suggest that the highly complex mechanisms of surface–groundwater interaction can be conceptualized by exploiting two‐component LPMs in general. The model concept could thus be a powerful tool for better understanding both the hydrological functioning of mixing processes and the movement of different water components in riverbank infiltration systems.
Highlights
Environmental isotopes have been used commonly to identify the dynamics of groundwater systems
Results in Test 2 were compared with the best-fit results in Test 1, considering the model efficiency (Figure 6), the fractions of water components contributing to the shallow groundwater (Figure 5 i–k), and the behavioural solutions of optimized mean transit time (mTT) (Figure 7)
This study investigated groundwater transit times and subsurface flow conditions at the riverbank infiltration areas in the Vietnamese Mekong Delta (VMD)
Summary
Environmental isotopes have been used commonly to identify the dynamics of groundwater systems. Environmental isotope techniques can provide insights into the origin of water (Maloszewski, 2000), the interaction between surface and groundwater (e.g., Stichler, Maloszewski, Bertleff, & Watzel, 2008; Stichler, Maloszewski, & Moser, 1986), subsurface flow conditions Stewart & Thomas, 2008), water transport K. Stewart, Mehlhorn, & Elliott, 2007), and recharge mechanisms (Koeniger, Gaj, Beyer, & Himmelsbach, 2016) in the subsurface system. Given that the hydraulic properties of aquifers are poorly known and spatially variable, environmental tracer methods can provide more accurate groundwater flow velocities and recharge rates than traditional hydraulic methods (Cook & Böhlke, 2000). Numerical flow models can overestimate or underestimate the flow velocity depending on the aquifer thickness, the hydraulic conductivity, and the effective porosity (Zuber, Różanski, Kania, & Purtschert, 2011)
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