Howard W Reeves
Howard W. Reeves is a Research Hydrologist with the Upper Midwest Water Science Center. Recent work includes regional assessment of groundwater availability for the U.S. Great Lakes Basin and the glacial aquifer system.
Professional Experience
2011 – present U.S. Geological Survey, USGS Michigan Water Science Center, Research Hydrologist
2010 – 2014 Michigan Technological University, Houghton, Michigan, Ad Hoc Graduate Faculty, Department of Geological and Mining, Engineering and Sciences
2007 – 2014 Michigan State University, East Lansing, Michigan, Adjunct/Visiting Assistant Professor, Department of Civil Engineering
2003 – 2011 U.S. Geological Survey, USGS Michigan Water Science Center, Research Hydrologist, Groundwater Specialist
2002 – 2003 U.S. Geological Survey, Water Resources Discipline, Michigan District, Hydrologist
1994 – 2001 Northwestern University, Evanston, Illinois, Assistant Professor, Department of Civil Engineering
1991 – 1994 University of South Carolina, Columbia, South Carolina, Assistant Professor, Department of Geological Sciences
1996 – 1997 Argonne National Laboratory, Argonne, Illinois, Faculty Appointment, Environmental Research Division
1991 – 1994 U.S. Geological Survey, Water Resources Division, South Carolina District, Hydrologist, Faculty Appointment
Education and Certifications
University of Notre Dame, Chemical Engineering, B.S. 1983
University of Notre Dame, Environmental Engineering, M.S. 1985
The University of Michigan, Environmental Engineering, Ph.D. 1993
Science and Products
STRMDEPL08 - An extended version of STRMDEPL with additional analytical solutions to calculate streamflow depletion by nearby pumping wells
Summary of hydrogeologic conditions by county for the state of Michigan
Use of models to map potential capture of surface water
Summary of recovered historical ground-water-level data for Michigan, 1934-2005
Atrazine concentrations in stream water and streambed sediment pore water in the St. Joseph and Galien River basins, Michigan and Indiana, May 2001-September 2003
Great Lakes basin water availability and use: a study of the National Assessment of Water Availability and Use Program
Hydrogeology and simulation of regional ground-water-level declines in Monroe County, Michigan
Seasonal patterns in the soil water balance of a Spartina marsh site at North Inlet, South Carolina, USA
Non-USGS Publications**
**Disclaimer: The views expressed in Non-USGS publications are those of the author and do not represent the views of the USGS, Department of the Interior, or the U.S. Government.
Science and Products
- Publications
Filter Total Items: 32
STRMDEPL08 - An extended version of STRMDEPL with additional analytical solutions to calculate streamflow depletion by nearby pumping wells
STRMDEPL, a one-dimensional model using two analytical solutions to calculate streamflow depletion by a nearby pumping well, was extended to account for two additional analytical solutions. The extended program is named STRMDEPL08. The original program incorporated solutions for a stream that fully penetrates the aquifer with and without streambed resistance to ground-water flow. The modified progAuthorsHoward W. ReevesSummary of hydrogeologic conditions by county for the state of Michigan
Summaries of the major hydrogeologic features for each county in Michigan are presented. Each summary includes a listing of the major watersheds in the county and a description of the hydrogeology of the major aquifers in the county. Aquifer properties reported in the literature are given if available. Reports describing the hydrogeology of each county are cited. This work was prepared to provideAuthorsBeth A. Apple, Howard W. ReevesUse of models to map potential capture of surface water
The effects of ground-water withdrawals on surface-water resources and riparian vegetation have become important considerations in water-availability studies. Ground water withdrawn by a well initially comes from storage around the well, but with time can eventually increase inflow to the aquifer and (or) decrease natural outflow from the aquifer. This increased inflow and decreased outflow is refAuthorsStanley A. LeakeSummary of recovered historical ground-water-level data for Michigan, 1934-2005
This report documents ground-water-level data-recovery efforts performed by the USGS Michigan Water Science Center and provides nearly three-hundred hydrographs generated from these recovered data. Data recovery is the process of verifying and transcribing data from paper files into the USGS National Water Information System (NWIS) electronic databases appropriate for ground-water-level data. EnteAuthorsCassaundra L. Cornett, Suzanne L. Crowley, Rose M. McGowan, Stephen P. Blumer, Howard W. ReevesAtrazine concentrations in stream water and streambed sediment pore water in the St. Joseph and Galien River basins, Michigan and Indiana, May 2001-September 2003
The U.S. Geological Survey (USGS) sampled multiple stream sites across the St. Joseph and Galien River Basins to detect and quantify the herbicide atrazine using a field enzyme-linked immunosorbent assay (ELISA) triazine test. In May 2001, July 2001, April 2002, August 2002, August 2003 and September 2003, composite samples were collected across streams at USGS streamflow-gaging stations. ConcentrAuthorsJoseph W. Duris, Howard W. Reeves, James L. KieslerGreat Lakes basin water availability and use: a study of the National Assessment of Water Availability and Use Program
No abstract available.AuthorsNorman G. Grannemann, Howard W. ReevesHydrogeology and simulation of regional ground-water-level declines in Monroe County, Michigan
Observed ground-water-level declines from 1991 to 2003 in northern Monroe County, Michigan, are consistent with increased ground-water demands in the region. In 1991, the estimated ground-water use in the county was 20 million gallons per day, and 80 percent of this total was from quarry dewatering. In 2001, the estimated ground-water use in the county was 30 million gallons per day, and 75 percenAuthorsHoward W. Reeves, Kirsten V. Wright, J.R. NicholasSeasonal patterns in the soil water balance of a Spartina marsh site at North Inlet, South Carolina, USA
Time series of ground-water head at a mid-marsh site near North Inlet, South Carolina, USA can be classified into five types of forcing signatures based on the dominant water flux governing water-level dynamics during a given time interval. The fluxes that can be recognized are recharge by tides and rain, evapotranspiration (ET), seepage into the near surface soil from below, and seepage across thAuthorsL. R. Gardner, Howard W. ReevesNon-USGS Publications**
Lee, Jejung, Graettinger, A.J., Moylan, John, and Reeves, H.W., 2009, Directed site exploration for permeable reactive barrier design: Journal of Hazardous Materials, v. 162, no. 1, p. 222–229.Lee, Jejung, Reeves, H.W., and Dowding, C.H., 2008, The nodal failure index approach to ground-water remediation design (technical note): ASCE Journal of Geotechnical and Geoenvironmental Engineering, v. 134, no. 10, p. 1554–1557.Moran, Brian, Kulkarni, S.S., and Reeves, H.W., 2007, A path-independent integral for the characterization of solute concentration and flux at biofilm detachments: International Journal of Fracture, v. 143, no. 3, p. 291–300.Graettinger, A.J., Lee, Jejung, Reeves, H.W., and Dethan, Deepu, 2006, Quantitative methods to direct exploration based on hydrogeologic information: Journal of Hydroinformatics, v. 8, no. 2, p. 77–90.Graettinger, A.J., Reeves, H.W., Lee, Jejung, and Dethan, Deepu, 2003, Use of input uncertainty and model sensitivity to guide site exploration: Mishra, S., ed., Groundwater Quality Modeling and Management Under Uncertainty: Proceedings of the Probabilistic Approaches & Groundwater Modeling Symposium held during the World Water and Environmental Resources Congress in Philadelphia, Pennsylvania, June 24-26, 2003: Washington, D.C., American Society of Civil Engineers, p. 215–225.Glasgow, H.S., Fortney, M.D., Lee, Jejung, Graettinger, A.J., and Reeves, H.W., 2003, MODFLOW-2000 head uncertainty, a first-order second-moment method: Ground Water, v. 41, no. 3, p. 342–350.Kozak, J.A., Reeves, H.W., and Lewis, B.A., 2003, Modeling radium and radon transport through soil and vegetation: Journal of Contaminant Hydrology, v. 66, p. 179–200.Schulenberg, J.W., and Reeves, H.W., 2002, Axisymmetric simulation of soil vapor extraction before and after fracturing: Journal of Contaminant Hydrology, v. 57, no. 3-4, p. 189–222.Lee, Jejung, Reeves, H.W., and Dowding, C.H., 2002, Integrating site characterization with aquifer and soil remediation design in Lipnick, R.L., Mason, R.P., Phillips, M.L., and Pittman, C.U., Jr., eds., Fate and Transport of Chemicals in the Environment: Impacts, Monitoring, and Remediation, ACS Symposium Series 806: Washington, D.C., American Chemical Society, p. 384–396.Graettinger, A.J., Lee, Jejung, and Reeves, H.W., 2002, Efficient conditional modeling for geotechnical uncertainty evaluation: International Journal for Numerical and Analytical Methods in Geomechanics, v. 26, no. 2, p. 163–179.Gardner, L.R., and Reeves, H.W., 2002, Spatial patterns in soil water fluxes along a forest-marsh transect in the southeastern United States: Aquatic Sciences, v. 64, no. 2, p. 141–155.Gardner, L.R., and Reeves, H.W., 2002, Seasonal patterns in the soil water balance of a Spartina marsh site at North Inlet, South Carolina, USA: Wetlands, v. 22, no. 3, p. 467–477.Gardner, L.R., Reeves, H.W., and Thibodeau, P.M., 2002, Groundwater dynamics along forest-marsh transects in a southeastern salt marsh, USA— description, interpretation and challenges for numerical modeling: Wetlands Ecology and Management, v. 10, p. 145–159.Reeves, H.W., and Moran, Brian, 2000, Meshless methods in contaminant hydrology: in Bentley, L.R., Sykes, J.F., Brebbia, C.A., Gray, W.G., and Pinder, G.F., eds., Proceedings of the XIII International Conference on Computational Methods in Water Resources, Volume 2: Computational Methods, Surface Water Systems and Hydrology: Rotterdam, A.A. Balkema, p. 713–718.Reeves, H.W., Thibodeau, P.M., Underwood, R.G., and Gardner, L.R., 2000, Incorporation of total stress changes into the groundwater model SUTRA: Ground Water, v. 38, no. 1, p. 89–98.Reeves, H.W., Lee, Jejung, Dowding, C.H., and Graettinger, A.J., 2000, Reliability-based evaluation of groundwater remediation strategies: in Stauffer, F., Kinzelbach, W., Kovar, K., and Hoehn, E., eds., Calibration and Reliability in Groundwater Modelling–Coping with Uncertainty, Proceedings of the ModelCARE ’99 Conference, Zürich, September, 1999: IAHS Publication no. 265, Wallingford, Oxfordshire, UK, IAHS Press, p. 304–309.Dowding, C.H., Reeves, H.W., Graettinger, A.J., and Lee, J., 2000, Inclusion of the performance model to direct and control site characterization: in Mayne, P.W., and Hyrciw, R.D., eds., Innovations and Applications in Geotechnical Site Characterization: Geo-Institute of the American Society of Civil Engineers, Geotechnical Special Publication Number 97, Reston, Virginia, ASCE, p. 130–141.Rittmann, B.E., Pettis, M., Reeves, H.W., and Stahl, D.A., 1999, How biofilm clusters affect substrate flux and ecological selection: Water Science Technology, v. 39, no. 7, p. 99–105.Thibodeau, P.M., Gardner, L.R., and Reeves, H.W., 1998, The role of groundwater flow in controlling the spatial distribution of soil salinity and rooted macrophytes in a southeastern salt marsh, USA: Mangroves and Salt Marshes, v. 2, no. 1, p. 1–13.Schulenberg, J.W., and Reeves, H.W., 1998, Modeling soil vapor extraction using preferential flow: in Inyang, H.I., and Ogunro, V.O., eds., Proceedings of the 4TH International Symposium on Environmental Geotechnics and Global Sustainable Development, August 9-13, 1998, Boston, Massachusetts, USA: Lowell, MA, University of Massachusetts, Lowell, p. 946–955.Abbasi, Samira, and Reeves, H.W., 1998, Modeling sequential electron accepting processes in groundwater bioremediation: in Inyang, H.I., and Ogunro, V.O., eds., Proceedings of the 4TH International Symposium on Environmental Geotechnics and Global Sustainable Development, August 9-13, 1998, Boston, Massachusetts, USA: Lowell, MA, University of Massachusetts, Lowell, p. 905–914.Widdowson, M.W., Haney, O.R., Reeves, H.W., Aelion, C.M., and Ray, R.P., 1997, A multi-level soil vapor extraction test for heterogeneous soils: ASCE Journal of Environmental Engineering, v. 123, no. 2, p. 160–168.Reeves, H.W., and Fairborn, L.W., 1996, Application of an inverse model, SUTRAP, to a tidally-driven groundwater system: in Kovar, K., and van der Heijde, P., eds., Calibration and Reliability in Groundwater Modelling, ModelCARE ’96: IAHS Publication no. 237, Wallingford, Oxfordshire, UK, IAHS Press, p. 115–124.Reeves, H.W., Lough, K.A., and Goñi, M.A., 1996, An experimental investigation of organic solvent infiltration into a natural clay: in Reddy, K.R., ed., The Fourth Great Lakes Geotechnical/Geoenvironmental Conference: In-Situ Remediation of Contaminated Sites: Chicago, University of Illinois at Chicago, p. 95–106.Keenan, R.S., Dickerson, J., Gardner, L.R., and Reeves, H.W., 1996, Inexpensive multi-channel electronic water level recorders for hydrologic studies: Groundwater Monitoring and Remediation, v. 16, no. 2, p. 77–83.Aelion, C.M., Shaw, J.N., Ray, R.P., Widdowson, M.A., and Reeves, H.W., 1996, Simplified methods for monitoring petroleum-contaminated ground water and soil vapor: Journal of Soil Contamination, v. 4, no. 3, p. 225–241.Widdowson, M.W., Aelion, C.M., Ray, R.P., and Reeves, H.W., 1995, Soil vapor extraction pilot study at a piedmont UST site: in Hinchee, R.E., Miller, R.N., and Johnson, P.C., eds., In Situ Aeration: Air Sparging, Bioventing, and Related Remediation Processes: Columbus, OH, Battelle Press, p. 455–461.Widdowson, M.A., Ray, R.P., Reeves, H.W., and Aelion, C.M., 1995, Integrated site characterization for SVE design: in Acar, Y.B., and Daniel, D.E., eds., Geoenvironment 2000, Volume 2: ASCE, Geotechnical Special Publication 48, New York, American Society of Civil Engineers, p. 1291–1305.Widdowson, M.A., Ray, R.P., Aelion, C.M., Reeves, H.W., and Holbrooks, K.D., 1995, Investigation of soil-venting based remediation at a UST site in the Appalachian Piedmont in Schepart, B.S., ed., Bioremediation of Pollutants in Soil and Water, ASTM STP 1235: Philadelphia, American Society for Testing and Materials, p. 135–148.Aelion, C.M., Widdowson, M.A., Ray, R.P., Reeves, H.W., and Shaw, J.N., 1995, Biodegradation, vapor extraction, and air sparging in low-permeability soils: in Hinchee, R.E., Miller, R.N., and Johnson, P.C., eds., In Situ Aeration: Air Sparging, Bioventing, and Related Remediation Processes: Columbus, OH, Battelle Press, p. 127–134.Reeves, H.W., and Abriola, L.M., 1994, An iterative-compositional model for subsurface multiphase flow: Journal of Contaminant Hydrology, v. 15, no. 1, p. 249–276.Abriola, L.M., Fen, C.-S., and Reeves, H.W., 1992, Numerical simulation of unsteady organic vapor transport in porous media using the dusty gas model: Weyer, K.U., ed., Proceedings of the International Conference on Subsurface Contamination by Immiscible Fluids, April 18-20, 1990, Calgary, Alberta, Canada: Rotterdam, A.A. Balkema, p. 195–202Kirkner, D.J., and Reeves, H.W., 1990, A penalty function method for computing chemical equilibria: Computers & Geosciences, v. 16, no. 1, p. 21–40.Abriola, L.M., and Reeves, H.W., 1990, Slightly miscible organic chemical migration in porous media— present and future directions in modeling: in Murarka, I.P., and Cordle, S., eds., Proceedings: Environmental Research Conference on Groundwater Quality and Waste Disposal: Electric Power Research Institute Report EN-6749, Palo Alto, California, EPRI, section 15-1.Reeves, H.W., and Abriola, L.M., 1988, A decoupled approach to the simulation of flow and transport of non-aqueous phase contaminants through porous media: in Celia, M.A., Ferrand, L.A., Brebbia, C.A., Gray, W.G., and Pinder, G.F., eds., Computational Methods in Water Resources, Vol. 1 Modeling Surface and Sub-surface Flows, Proceedings of the VII International Conference: Amsterdam: Elsevier, Co-published with Computational Mechanics Publications, Southampton, p. 147–152.Reeves, Howard, and Kirkner, D.J., 1988, Multicomponent mass transport with homogeneous and heterogeneous chemical reactions— The effect of chemistry on the choice of numerical algorithm, Part II. Numerical results: Water Resources Research, v. 24, no. 10, p. 1730–1739.Kirkner, D.J., and Reeves, Howard, 1988, Multicomponent mass transport with homogeneous and heterogeneous chemical reactions— The effect of chemistry on the choice of numerical algorithm, Part I. Theory: Water Resources Research, v. 24, no. 10, p. 1719–1729.Kirkner, D.J., Reeves, H.W., and Jennings, A.A., 1984, Finite element analysis of multicomponent contaminant transport including precipitation-dissolution reactions: in Laible, J.P., Brebbia, C.A., Gray, W., and Pinder, G.F., eds., Finite Elements in Water Resources, Proceedings of the 5th International Conference, Burlington, Vermont, June, 1984: Berlin, Springer-Verlag, p. 309–318.**Disclaimer: The views expressed in Non-USGS publications are those of the author and do not represent the views of the USGS, Department of the Interior, or the U.S. Government.
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