scholarly journals Groundwater Age Determination- Insight into Groundwater Recharge, Flow Systems and Contamination Studies

2021 ◽  
Vol 16 (2) ◽  
pp. 346-347
Author(s):  
Dr. Gopal Krishan
Keyword(s):  
Groundwater Recharge ◽  
Groundwater Age ◽  
Age Determination ◽  
Flow Systems ◽  
Insight Into

Groundwater age from multi-level bores: What it can tell about the aquifers

2021 ◽  
Author(s):  
Uwe Morgenstern ◽  
Zara Rawlinson
Keyword(s):  
Groundwater Flow ◽  
Groundwater Recharge ◽  
Sea Level ◽  
Preferential Flow ◽  
Groundwater Age ◽  
Geological Processes ◽  
Recharge Sources ◽  
Transient Electromagnetic ◽  
Geophysical Surveys ◽  
Multi Level

<p>Geologic data to provide information on the functioning of aquifers is often scars. For the aquifers underlying the Heretaunga Plains, Hawkes Bay, one of New Zealand’s most important groundwater systems, we used groundwater age (tritium, SF6, 14C) to inform the geologic model and to provide information on groundwater flow through alternating strata of permeable river gravel beds and fine impermeable beds that form an interconnected unconfined–confined aquifer system with complex groundwater flow processes.</p><p>The aquifers are a result of geological processes responding to climate change cycles from cold glacial when sea level was more than 100m below present sea level, to warm interglacial periods with sea level similar to present day. Glacial climate strata are river gravel, sand and silt deposits and include the artesian aquifers. The interglacial strata form the aquicludes and are marine sand, silt, and clay deposits with interbedded estuarine, swamp and coastal fluvial silt, clay, peat and gravel deposits.</p><p>We have re-visited tracer data sampled during the drilling of multi-level observation well in the early 1990s, and collected new samples from these multi-level bores in order to understand in 3D the groundwater recharge sources, groundwater recharge and flow rates, connection to the rivers, and potential groundwater discharge out to sea. Consistently young water (c. 25 years) at depth greater than 100m indicates preferential flow paths, likely related to paleo-river channels. The flow pattern obtained from the water tracer data improves the geologic information from the drill-holes, and fits with information from recent airborne transient electromagnetic (SkyTEM) geophysical surveys.</p>

scholarly journals A multi-environmental tracer study to determine groundwater residence times and recharge in a structurally complex multi-aquifer system

2020 ◽  
Vol 24 (1) ◽  
pp. 249-267 ◽  
Author(s):  
Cornelia Wilske ◽  
Axel Suckow ◽  
Ulf Mallast ◽  
Christiane Meier ◽  
Silke Merchel ◽  
...  
Keyword(s):  
Groundwater Flow ◽  
Groundwater Recharge ◽  
Groundwater Age ◽  
Age Distribution ◽  
Dead Sea ◽  
Artificial Sweetener ◽  
Environmental Tracers ◽  
Jordan Valley ◽  
Aquifer System ◽  
Lumped Parameter

Abstract. Despite being the main drinking water resource for over 5 million people, the water balance of the Eastern Mountain Aquifer system on the western side of the Dead Sea is poorly understood. The regional aquifer consists of fractured and karstified limestone – aquifers of Cretaceous age, and it can be separated into a Cenomanian aquifer (upper aquifer) and Albian aquifer (lower aquifer). Both aquifers are exposed along the mountain ridge around Jerusalem, which is the main recharge area. From here, the recharged groundwater flows in a highly karstified aquifer system towards the east and discharges in springs in the lower Jordan Valley and Dead Sea region. We investigated the Eastern Mountain Aquifer system for groundwater flow, groundwater age and potential mixtures, and groundwater recharge. We combined 36Cl ∕ Cl, tritium, and the anthropogenic gases SF6, CFC-12 (chlorofluorocarbon) and CFC-11, while using CFC-113 as “dating” tracers to estimate the young water components inside the Eastern Mountain Aquifer system. By application of lumped parameter models, we verified young groundwater components from the last 10 to 30 years and an admixture of a groundwater component older than about 70 years. Concentrations of nitrate, simazine (pesticide), acesulfame K (ACE-K; artificial sweetener) and naproxen (NAP; drug) in the groundwater were further indications of infiltration during the last 30 years. The combination of multiple environmental tracers and lumped parameter modelling helped to understand the groundwater age distribution and to estimate recharge despite scarce data in this very complex hydrogeological setting. Our groundwater recharge rates support groundwater management of this politically difficult area and can be used to inform and calibrate ongoing groundwater flow models.

Numerically Simulated Groundwater Age Distributions within Complex Flow Systems and Discrete Fracture Networks

2020 ◽  
Author(s):  
John Molson ◽  
Emil Frind
Keyword(s):  
Groundwater Age ◽  
Fractured Rock ◽  
Vertical Plane ◽  
Geochemical Evolution ◽  
Real Field ◽  
Fracture Networks ◽  
Complex Flow ◽  
Discrete Fracture Networks ◽  
Discrete Fracture ◽  
Flow Systems

<p>Numerical simulations of mean groundwater age are presented for a variety of complex flow systems including heterogeneous aquifers and discretely-fractured porous rock. We apply the finite element models FLONET/TR2 (in the 2D vertical plane) and SALTFLOW (in 3D systems), using the standard advection-dispersion equation with an age source term. The age simulations are applied in a variety of contexts including defining capture zones for pumping wells, characterizing fractured rock aquifers, and for improved understanding of flow systems and geochemical evolution. Applications include real field sites and hypothetical conceptual models. Comparisons are also made with advective particle-tracking derived ages which are much faster to compute but do not include dispersive age mixing. Control of numerical (age) dispersion is critical, especially within discrete fracture networks where high age gradients can develop between the fractures and matrix. The presentation will highlight the broad applications of mean groundwater age simulations and will show how they can be useful for providing insight into hydrogeological systems.</p>

scholarly journals Use of Radiocarbon Ages to Narrow Groundwater Recharge Estimates in the Southeastern Mojave Desert, USA

Hydrology ◽  
2018 ◽  
Vol 5 (3) ◽  
pp. 51 ◽  
Author(s):  
Adam Love ◽  
Andy Zdon
Keyword(s):  
Groundwater Recharge ◽  
Land Surface ◽  
Mojave Desert ◽  
Groundwater Age ◽  
Age Dating ◽  
Local Climate ◽  
Site Model ◽  
Conceptual Site Model ◽  
Isotopic Analyses ◽  
Wide Range

Estimating groundwater recharge in arid or semiarid regions can be a difficult and complex task, since it is dependent on a highly variable set of spatial and temporal hydrologic parameters and processes that are dependent on the local climate, the land surface properties, and subsurface characteristics. As a result, traditional methods for estimating the recharge can result in a wide range of derived values. This is evident in the southeastern Mojave Desert, where calculated recharge estimates by previous investigators that range over an order of magnitude (from ~2500 to ~37,000 acre feet per year) are reported. To narrow down this large span of recharge estimates to narrower and more plausible values, this study evaluates the previous recharge estimates in this region, to examine the sources of variability in the reported results and to constrain the recharge estimates based on the hydrologic conditions and the radiocarbon age-dating of spring flows—even without knowledge of the precise subsurface hydrology. The groundwater age and perennial flow characteristics of springs in this study could not be derived from waters sourced solely from local recharge. Therefore, the springs in this study require a significant groundwater contribution to their overall discharge. A previously described conceptual site model in the region established that Bonanza Spring is similarly hydrologically connected to the regional basin-fill aquifer, based on geologic and geochemical/isotopic analyses, and this conceptual site model for where perennial spring water is sourced should readily be extended to these other perennial springs in this region.

Catchment-scale groundwater age stratification reveals groundwater recharge and discharge processes

2020 ◽  
Author(s):  
Tamara Kolbe ◽  
Jean Marçais ◽  
Jean-Raynald de Dreuzy ◽  
Thierry Labasque ◽  
Kevin Bishop
Keyword(s):  
Groundwater Recharge ◽  
Water Table ◽  
Groundwater Age ◽  
Discharge Zone ◽  
Return Flow ◽  
Catchment Scale ◽  
Analytical Approximations ◽  
Sampling Locations ◽  
Basal Till ◽  
Age Stratification

<p>The distribution of groundwater ages with depth provides information about subsurface structures and flow dynamics. Upslope measured groundwater age stratifications are commonly used to estimate groundwater recharge rates, whereas downslope measured age stratifications are influenced by recharge conditions, the aquifer structure and interactions between groundwater and surface water. In our study we address the question whether downslope measured groundwater ages from different locations can provide spatial and temporal information about catchment-scale groundwater dynamics and the relationship between groundwater recharge and discharge.<br>We derived an overall groundwater age stratification, representative for the Svartberget subcatchment (0.47 km<sup>2</sup>) located within the Krycklan study site, by measuring CFCs from 9 different sampling locations with depths of 2 m to 18 m. All sampling locations were downslope and located in basal till which is overlain by ablation till. <br>The CFC-based groundwater age stratification reveals an unexpected pattern, with groundwater ages of already 30 years immediately below the water table. Groundwater ages increase then with depth. We could reproduce the observed groundwater age stratification by using a groundwater flow model and show that the lag of rejuvenation, noticeable in groundwater ages of 30 years at the water table, derives from return flow of groundwater at a subsurface discharge zone that evolves at the interface between the two soil types (basal and ablation till). Furthermore, we demonstrate by varying the infiltration rate how the extent of the discharge zone and the partitioning of the infiltration amount to the two layers change, i.e. young runoff in the upper layer (ablation till) and old groundwater circulation through the deeper layer (basal till).<br>By providing a simple analytical approximations of the observed groundwater age stratification, we show that the extent of the subsurface discharge zone is a powerful indicator of the relation between the recharge and discharge zone, while the vertical gradient of the age-depth relationship provides information about the overall aquifer recharge.</p>

Sensitivity to long-term climate change of subpermafrost groundwater systems in Svalbard

2010 ◽  
Vol 73 (2) ◽  
pp. 393-402 ◽  
Author(s):  
Sylvi Haldorsen ◽  
Michael Heim ◽  
Barrie Dale ◽  
Jon Y. Landvik ◽  
Martine van der Ploeg ◽  
...  
Keyword(s):  
Groundwater Flow ◽  
Groundwater Recharge ◽  
High Arctic ◽  
Fracture Systems ◽  
Flow Systems ◽  
Groundwater Systems ◽  
Spring System ◽  
Flow Through ◽  
Permafrost Thawing

Deep subpermafrost aquifers are highly climate-dependent, with the permafrost as an aquitard preventing groundwater recharge and discharge. A study from the high-arctic island of Spitsbergen, Svalbard, shows that during a glacial to interglacial phase, both the permafrost and the glacier regime will respond to climatic changes, and a glacier-fed groundwater flow system will vary accordingly. A full glaciation results in the melting of permafrost, and groundwater can flow through pores and fracture systems in the rocks and sediments below the temperate zones of glaciers. These groundwater flow systems will mainly be localized to fjords and valleys and form low-lying terrestrial springs when the relative sea level drops during deglaciation due to glacio-isostatic rise. During an interglaciation, permafrost develops and thickens and the groundwater recharge and discharge areas will thereby be gradually reduced to a minimum reached at the warmest part of an interglaciation. An already frozen spring system cannot reopen before the permafrost melts. Only groundwater springs related to permanently warm-based glacial ice will persist into the next glaciation. During a new glaciation, flow systems that terminated during the previous interglaciation may become revitalized if overridden by warm-based ice causing permafrost thawing.

scholarly journals Halon-1301 – further evidence of its performance as an age tracer in New Zealand groundwater

2017 ◽  
Vol 21 (8) ◽  
pp. 4213-4231 ◽  
Author(s):  
Monique Beyer ◽  
Uwe Morgenstern ◽  
Rob van der Raaij ◽  
Heather Martindale
Keyword(s):  
New Zealand ◽  
Groundwater Age ◽  
Contaminated Sites ◽  
Mixing Models ◽  
Residence Times ◽  
Halon 1301 ◽  
Groundwater Environment ◽  
Groundwater Samples ◽  
Mean Residence Times ◽  
Insight Into

Abstract. We recently discovered a new groundwater age tracer, Halon-1301, which can be used to date groundwater recharged after the 1970s. In a previous study, we showed that Halon-1301 reliably inferred groundwater age at the majority of groundwater sites studied. At those sites, ages inferred from Halon-1301 agreed with those inferred from SF6 and tritium, two reliable widely applied groundwater age tracers. A few samples, however, showed reduced concentrations of Halon-1301, preventing meaningful age interpretation from its concentration. These reduced concentrations were likely a result of degradation or retardation of Halon-1301 in the aquifer. However, we could not provide full evidence for this due to the limited number of groundwater samples analysed (18 in total). In this study, we assess the potential of Halon-1301 as a groundwater age tracer for a larger dataset of groundwater samples under specific groundwater conditions, including highly anoxic young groundwater which can significantly degrade Halon-1301, to gain more information on the magnitude of occurrence and the causes of reduced Halon-1301 concentrations. In this study, we analysed 302 groundwater samples for Halon-1301, SF6, tritium and the CFCs CFC-11, CFC-12 and CFC-113. Comparison of age information inferred from the concentrations of these tracers allows assessment of the performance of Halon-1301 compared to other well established and widely used age tracers. The samples are taken from different groundwater environments in New Zealand and include anoxic and oxic waters with mean residence times ranging from < 2 years to over 150 years (tritium-free). The majority of assessed samples have reduced or elevated concentrations of CFCs, which makes it impossible to infer a reliable age using the CFCs for these samples. Halon-1301, however, reliably infers ages for CFC-contaminated waters. Three other groundwater samples were found to have elevated SF6 concentrations (contaminated). Again, at these SF6-contaminated sites, ages inferred from Halon-1301 agree with ages inferred from tritium. A few samples (14 sites) exhibit reduced concentrations of Halon-1301, which result in elevated inferred Halon-1301 ages in comparison to those inferred from SF6, tritium and/or CFC-113. Assessment of the groundwater environment at these sites gives further insight into the potential causes of Halon-1301 reduction in groundwater. Overall, Halon-1301 gives age information that matches ages inferred from SF6 and/or tritium for the majority (97 %) of the assessed groundwater sites. These findings suggest that Halon-1301 is a reasonably reliable groundwater age tracer, and is in particular significantly more reliable than the CFCs, which may have contamination and degradation problems. Halon-1301 thus has potential to become a useful groundwater age tracer where SF6 and the CFCs are compromised, and where additional independent tracers are needed to constrain complex mixing models.

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