Suitability of temperature, hydraulic heads, and acesulfame to quantify wastewater‐related fluxes in the hyporheic and riparian zone
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Henning Prommer | Catherine Moore | Thomas A. Ternes | Irina Engelhardt | Christoph Schüth | H. Prommer | T. Ternes | C. Moore | C. Schüth | I. Engelhardt | M. Schulz | Manoj Schulz
[1] F. Swanson,et al. An Ecosystem Perspective of Riparian ZonesFocus on links between land and water , 1991 .
[2] Solute and Heat Transport Model of the Henry and Hilleke Laboratory Experiment , 2010, Ground water.
[3] M. Taniguchi. Estimated Recharge Rates From Groundwater Temperatures In The Nara Basin, Japan , 1994 .
[4] Christian Zwiener,et al. Tracking artificial sweeteners and pharmaceuticals introduced into urban groundwater by leaking sewer networks. , 2012, The Science of the total environment.
[5] C. Zheng,et al. Utility of bromide and heat tracers for aquifer characterization affected by highly transient flow conditions , 2012 .
[6] U. Dünnbier,et al. Identification and significance of phenazone drugs and their metabolites in ground- and drinking water. , 2002, Chemosphere.
[7] F. Lange,et al. Analysis and occurrence of seven artificial sweeteners in German waste water and surface water and in soil aquifer treatment (SAT) , 2009, Analytical and bioanalytical chemistry.
[8] Paul P. Wang,et al. MT3DMS: A Modular Three-Dimensional Multispecies Transport Model for Simulation of Advection, Dispersion, and Chemical Reactions of Contaminants in Groundwater Systems; Documentation and User's Guide , 1999 .
[9] A. Binley,et al. Temporal and spatial variability of groundwater–surface water fluxes: Development and application of an analytical method using temperature time series , 2007 .
[10] T. Ternes,et al. Pharmaceuticals and personal care products in the environment: agents of subtle change? , 1999, Environmental health perspectives.
[11] Mashfiqus Salehin,et al. A multiscale model for integrating hyporheic exchange from ripples to meanders , 2010 .
[12] M. Hill. A computer program (MODFLOWP) for estimating parameters of a transient, three-dimensional ground-water flow model using nonlinear regression , 1992 .
[13] J. Lewandowski,et al. Fate of organic micropollutants in the hyporheic zone of a eutrophic lowland stream: results of a preliminary field study. , 2011, The Science of the total environment.
[14] G. Michael Shook,et al. Predicting thermal breakthrough in heterogeneous media from tracer tests , 2001 .
[15] E. Helmers,et al. Hospital effluents as a source of gadolinium in the aquatic environment , 2000 .
[16] Mary P Anderson,et al. Heat as a Ground Water Tracer , 2005, Ground water.
[17] S. Stadler,et al. Comparison of tracer methods to quantify hydrodynamic exchange within the hyporheic zone , 2011 .
[18] Richard J. Williams,et al. Decreasing boron concentrations in UK rivers: insights into reductions in detergent formulations since the 1990s and within-catchment storage issues. , 2010, The Science of the total environment.
[19] C. Zheng,et al. Effects of Density and Viscosity in Modeling Heat as a Groundwater Tracer , 2009, Ground water.
[20] C. Schmidt,et al. Characterization of spatial heterogeneity of groundwater-stream water interactions using multiple depth streambed temperature measurements at the reach scale , 2006 .
[21] B. Conant,et al. Delineating and Quantifying Ground Water Discharge Zones Using Streambed Temperatures , 2004, Ground water.
[22] O. Johansen. Thermal Conductivity of Soils , 1977 .
[23] Robert Horton,et al. An Improved Model for Predicting Soil Thermal Conductivity from Water Content at Room Temperature , 2007 .
[24] D. Nordstrom,et al. Aqueous stability of gadolinium in surface waters receiving sewage treatment plant effluent, Boulder Creek, Colorado. , 2005, Environmental science & technology.
[25] Jozsef Hecht-Méndez,et al. Evaluating MT3DMS for Heat Transport Simulation of Closed Geothermal Systems , 2010, Ground water.
[26] Jesús Carrera,et al. Simulation of groundwater age distributions , 1998 .
[27] T. C. Winter,et al. Ground Water and Surface Water: A Single Resource , 1999 .
[28] T. Ternes. Occurrence of drugs in German sewage treatment plants and rivers 1 Dedicated to Professor Dr. Klaus , 1998 .
[29] U. Karst,et al. Speciation analysis of gadolinium chelates in hospital effluents and wastewater treatment plant sewage by a novel HILIC/ICP-MS method. , 2009, Environmental science & technology.
[30] David W. Pollock,et al. A Controlled Experiment in Ground Water Flow Model Calibration , 1998 .
[31] C. Tiedeman,et al. Effective Groundwater Model Calibration , 2007 .
[32] Christian D. Langevin,et al. Addition of simultaneous heat and solute transport and variable fluid viscosity to SEAWAT , 2006, Comput. Geosci..
[33] Daniel J. Goode,et al. Direct Simulation of Groundwater Age , 1996 .
[34] Jim Constantz,et al. Heat as a tool for studying the movement of ground water near streams , 2003 .
[35] Thomas Heberer,et al. Tracking persistent pharmaceutical residues from municipal sewage to drinking water , 2002 .
[36] Patrick Meire,et al. Transient or steady‐state? Using vertical temperature profiles to quantify groundwater–surface water exchange , 2009 .
[37] L. Lebbe,et al. Conservative Solute Versus Heat Transport in Porous Media During Push-pull Tests , 2009 .
[38] T. Poiger,et al. Ubiquitous occurrence of the artificial sweetener acesulfame in the aquatic environment: an ideal chemical marker of domestic wastewater in groundwater. , 2009, Environmental science & technology.
[39] S. Solomon. The Physical Science Basis : Contribution of Working Group I to the Fourth Assessment Report of the Intergovernmental Panel on Climate Change , 2007 .
[40] A. W. Harbaugh. MODFLOW-2005 : the U.S. Geological Survey modular ground-water model--the ground-water flow process , 2005 .
[41] E. Sudicky,et al. Thermal transport modelling in a fully integrated surface/subsurface framework , 2009 .
[42] L. Puckett,et al. Transport and fate of nitrate and pesticides: hydrogeology and riparian zone processes. , 2005, Journal of environmental quality.
[43] Christian D Langevin,et al. Quantifying Data Worth Toward Reducing Predictive Uncertainty , 2010, Ground water.
[44] I. Antigüedad,et al. Influence of upwelling on the shallow water chemistry in a small wetland riparian zone (Basque Country) , 2012 .
[45] Jirka Simunek,et al. Indirect estimation of soil thermal properties and water flux using heat pulse probe measurements: Geometry and dispersion effects , 2002 .
[46] J. Doherty,et al. Role of the calibration process in reducing model predictive error , 2005 .
[47] F. Triska,et al. RETENTION AND TRANSPORT OF NUTRIENTS IN A THIRD-ORDER STREAM IN NORTHWESTERN CALIFORNIA: HYPORHEIC PROCESSES' , 1989 .
[48] J. Fleckenstein,et al. A 3D analysis algorithm to improve interpretation of heat pulse sensor results for the determination of small-scale flow directions and velocities in the hyporheic zone , 2012 .