Your search keyword '"Nicolaas Peter Hendrikus Unland"' showing total 6 results

1. Dynamic river-groundwater exchange in the presence of a saline, semi-confined aquifer

Author

Ian Cartwright, Alexander Paul Atkinson, Benjamin Gilfedder, Edoardo Daly, and Nicolaas Peter Hendrikus Unland

Subjects

Hydrology, geography, geography.geographical_feature_category, Baseflow, MODFLOW, Drainage basin, Environmental science, Aquifer, Groundwater model, Surface water, Bank, Groundwater, Water Science and Technology

Abstract

Understanding groundwater–surface water exchange in river banks is crucial for effective water management and a range of scientific disciplines. While there has been much research on bank storage, many studies assume idealized aquifer systems. This paper presents a field-based study of the Tambo Catchment (southeast Australia) where the Tambo River interacts with both an unconfined aquifer containing relatively young and fresh groundwater ( 2500 μS/cm and >10 000 years old). Continuous groundwater elevation and electrical conductivity monitoring within the different aquifers and the river suggest that the degree of mixing between the two aquifers and the river varies significantly in response to changing hydrological conditions. Numerical modelling using MODFLOW and the solute transport package MT3DMS indicates that saline water in the river bank moves away from the river during flooding as hydraulic gradients reverse. This water then returns during flood recession as baseflow hydraulic gradients are re-established. Modelling also indicates that the concentration of a simulated conservative groundwater solute can increase for up to ~34 days at distances of 20 and 40 m from the river in response to flood events approximately 10 m in height. For the same flood event, simulated solute concentrations within 10 m of the river increase for only ~15 days as the infiltrating low-salinity river water drives groundwater dilution. Average groundwater fluxes to the river stretch estimated using Darcy's law were 7 m3/m/day compared with 26 and 3 m3/m/day for the same periods via mass balance using Radon (222Rn) and chloride (Cl), respectively. The study shows that by coupling numerical modelling with continuous groundwater–surface water monitoring, the transient nature of bank storage can be evaluated, leading to a better understanding of the hydrological system and better interpretation of hydrochemical data. Copyright © 2015 John Wiley & Sons, Ltd.

Published

2015

2. Residence times and mixing of water in river banks: implications for recharge and groundwater–surface water exchange

Author

Robert Chisari, Dioni I. Cendón, Nicolaas Peter Hendrikus Unland, and Ian Cartwright

Subjects

lcsh:GE1-350, Hydrology, geography, geography.geographical_feature_category, Baseflow, Hydrogeology, lcsh:T, lcsh:Geography. Anthropology. Recreation, Aquifer, Groundwater recharge, lcsh:Technology, lcsh:TD1-1066, Infiltration (hydrology), lcsh:G, lcsh:Environmental technology. Sanitary engineering, Surface water, Bank, lcsh:Environmental sciences, Groundwater, Geology

Abstract

Bank exchange processes within 50 m of the Tambo River, southeast Australia, have been investigated through the combined use of 3H and 14C. Groundwater residence times increase towards the Tambo River, which suggests the absence of significant bank storage. Major ion concentrations and δ2H and δ18O values of bank water also indicate that bank infiltration does not significantly impact groundwater chemistry under baseflow and post-flood conditions, suggesting that the gaining nature of the river may be driving the return of bank storage water back into the Tambo River within days of peak flood conditions. The covariance between 3H and 14C indicates the leakage and mixing between old (~17 200 years) groundwater from a semi-confined aquifer and younger groundwater (

Published

2014

3. Using 14C and 3H to understand groundwater flow and recharge in an aquifer window

Author

Alexander Paul Atkinson, Ian Cartwright, Benjamin Gilfedder, Dioni I. Cendón, Harald Hofmann, and Nicolaas Peter Hendrikus Unland

Subjects

Hydrology, geography, geography.geographical_feature_category, Groundwater flow, Water table, Depression-focused recharge, Groundwater discharge, Aquifer, Groundwater recharge, Groundwater model, Geology, Groundwater

Abstract

Knowledge of groundwater residence times and recharge locations is vital to the sustainable management of groundwater resources. Here we investigate groundwater residence times and patterns of recharge in the Gellibrand Valley, southeast Australia, where outcropping aquifer sediments of the Eastern View Formation form an "aquifer window" that may receive diffuse recharge from rainfall and recharge from the Gellibrand River. To determine recharge patterns and groundwater flow paths, environmental isotopes (3H, 14C, δ13C, δ18O, δ2H) are used in conjunction with groundwater geochemistry and continuous monitoring of groundwater elevation and electrical conductivity. The water table fluctuates by 0.9 to 3.7 m annually, implying recharge rates of 90 and 372 mm yr−1. However, residence times of shallow (11 to 29 m) groundwater determined by 14C are between 100 and 10 000 years, 3H activities are negligible in most of the groundwater, and groundwater electrical conductivity remains constant over the period of study. Deeper groundwater with older 14C ages has lower δ18O values than younger, shallower groundwater, which is consistent with it being derived from greater altitudes. The combined geochemistry data indicate that local recharge from precipitation within the valley occurs through the aquifer window, however much of the groundwater in the Gellibrand Valley predominantly originates from the regional recharge zone, the Barongarook High. The Gellibrand Valley is a regional discharge zone with upward head gradients that limits local recharge to the upper 10 m of the aquifer. Additionally, the groundwater head gradients adjacent to the Gellibrand River are generally upwards, implying that it does not recharge the surrounding groundwater and has limited bank storage. 14C ages and Cl concentrations are well correlated and Cl concentrations may be used to provide a first-order estimate of groundwater residence times. Progressively lower chloride concentrations from 10 000 years BP to the present day are interpreted to indicate an increase in recharge rates on the Barongarook High.

Published

2014

4. A multi-tracer approach to quantifying groundwater inflows to an upland river; assessing the influence of variable groundwater chemistry

Author

Nicolaas Peter Hendrikus Unland, Dioni I. Cendón, Ben Gilfedder, Ian Cartwright, Harald Hofmann, Robert Chisari, and Alexander Paul Atkinson

Subjects

Hydrology, geography, geography.geographical_feature_category, Baseflow, Streamflow, Drainage basin, Environmental science, Aquifer, Groundwater discharge, Spatial variability, Groundwater recharge, Groundwater, Water Science and Technology

Abstract

Understanding the behaviour and variability of environmental tracers is important for their use in estimating groundwater discharge to rivers. This study utilizes a multi-tracer approach to quantify groundwater discharge into a 27 km upland reach of the Gellibrand River in southwest Victoria, Australia. Ten sampling campaigns were conducted between March 2011 and June 2012, and the distribution of 222Rn activities, Cl and 3H concentrations imply the river receives substantial groundwater inflows. Mass balances based on 222Rn, Cl and 3H yield estimates of groundwater inflows that agree to within ± 12%, with cumulative inflows in individual campaigns ranging from 24 346 to 88 467 m3/day along the studied river section. Groundwater discharge accounts for between 10 and 50% of river flow dependent on the time of year, with a high proportion (>40 %) of groundwater sustaining summer flows. Groundwater inflow is largely governed by regional groundwater flowpaths; between 50 and 90% of total groundwater inflows occur along a narrow 5–10 km section where the river intersects the Eastern View Formation, a major regional aquifer. Groundwater 222Rn activities over the 16 month period were spatially heterogeneous across the catchment, ranging between 2000 Bq/m3 and 16 175 Bq/m3. Although groundwater 222Rn activities display temporal variation, spatial variation in groundwater 222Rn is a key control on 222Rn mass balances in river catchments where groundwater and river 222Rn activities are within an order of magnitude of each other. Calculated groundwater discharges vary from 8.4 to 15 m3/m/day when groundwater 222Rn activities are varied by ± 1 σ. Copyright © 2013 John Wiley & Sons, Ltd.

Published

2013

5. Investigating the spatio-temporal variability in groundwater and surface water interactions: a multi-technique approach

Author

Alexander Paul Atkinson, Martin S. Andersen, Nicolaas Peter Hendrikus Unland, Ian Cartwright, Harald Hofmann, Jennifer Anne Reed, Gabriel C. Rau, and Benjamin Gilfedder

Subjects

Hydrology, lcsh:GE1-350, Baseflow, Groundwater sampling, Discharge, lcsh:T, lcsh:Geography. Anthropology. Recreation, lcsh:Technology, lcsh:TD1-1066, Infiltration (hydrology), lcsh:G, TRACER, Environmental science, Groundwater discharge, lcsh:Environmental technology. Sanitary engineering, Surface water, Groundwater, lcsh:Environmental sciences

Abstract

The interaction between groundwater and surface water along the Tambo and Nicholson rivers, southeast Australia, was investigated using 222Rn, Cl, differential flow gauging, head gradients, electrical conductivity (EC) and temperature profiles. Head gradients, temperature profiles, Cl concentrations and 222Rn activities all indicate higher groundwater fluxes to the Tambo River in areas of increased topographic variation where the potential to form large groundwater–surface water gradients is greater. Groundwater discharge to the Tambo River calculated by Cl mass balance was significantly lower (1.48 × 104 to 1.41 × 103 m3 day−1) than discharge estimated by 222Rn mass balance (5.35 × 105 to 9.56 × 103 m3 day−1) and differential flow gauging (5.41 × 105 to 6.30 × 103 m3 day−1) due to bank return waters. While groundwater sampling from the bank of the Tambo River was intended to account for changes in groundwater chemistry associated with bank infiltration, variations in bank infiltration between sample sites remain unaccounted for, limiting the use of Cl as an effective tracer. Groundwater discharge to both the Tambo and Nicholson rivers was the highest under high-flow conditions in the days to weeks following significant rainfall, indicating that the rivers are well connected to a groundwater system that is responsive to rainfall. Groundwater constituted the lowest proportion of river discharge during times of increased rainfall that followed dry periods, while groundwater constituted the highest proportion of river discharge under baseflow conditions (21.4% of the Tambo in April 2010 and 18.9% of the Nicholson in September 2010).

Published

2013

6. Assessing the hydrogeochemical impact and distribution of acid sulphate soils, Heart Morass, West Gippsland, Victoria

Author

Nicolaas Peter Hendrikus Unland, Barrie Bolton, Ian Cartwright, and Helen L Taylor

Subjects

Hydrology, Soil classification, engineering.material, Pollution, δ34S, Geochemistry and Petrology, Soil pH, Environmental chemistry, Soil water, engineering, Environmental Chemistry, Soil horizon, Pyrite, Leaching (agriculture), Surface water, Geology

Abstract

The hydrogeochemical processes associated with the precipitation and oxidation of pyrite during the development of acid sulphate soils was investigated in the coastal floodplain environment of the Heart Morass, Victoria, Australia. During drought conditions in 2009, low-lying areas of the floodplain (0–2 m elevation) were the most affected by acid sulphate soils, with a median soil pH (pHF) of 3.56 to approximately 50 cm depth. Soils below ∼100 cm depth in these areas contain pyrite and have reduced inorganic S concentrations of up to 0.85 wt%. Higher areas of the floodplain (2–6 m) do not contain acid sulphate soils, with a median pH of 4.74 to approximately 50 cm depth, an average neutralising capacity of 3.87 kg H2SO4/t, and no appreciable unoxidised pyrite. In low-lying areas concentrations of Co, Ni, Zn, Mn and Fe in soil increased from

Published

2012