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Hydrogeology Journal

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01.12.2010 | Report

A field study (Massachusetts, USA) of the factors controlling the depth of groundwater flow systems in crystalline fractured-rock terrain

verfasst von: David F. Boutt, Patrick Diggins, Stephen Mabee

Erschienen in: Hydrogeology Journal | Ausgabe 8/2010

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Abstract

Groundwater movement and availability in crystalline and metamorphosed rocks is dominated by the secondary porosity generated through fracturing. The distributions of fractures and fracture zones determine permeable pathways and the productivity of these rocks. Controls on how these distributions vary with depth in the shallow subsurface (<300 m) and their resulting influence on groundwater flow is not well understood. The results of a subsurface study in the Nashoba and Avalon terranes of eastern Massachusetts (USA), which is a region experiencing expanded use of the fractured bedrock as a potable-supply aquifer, are presented. The study logged the distribution of fractures in 17 boreholes, identified flowing fractures, and hydraulically characterized the rock mass intersecting the boreholes. Of all fractures encountered, 2.5% are hydraulically active. Boreholes show decreasing fracture frequency up to 300 m depth, with hydraulically active fractures showing a similar trend; this restricts topographically driven flow. Borehole temperature profiles corroborate this, with minimal hydrologically altered flow observed in the profiles below 100 m. Results from this study suggest that active flow systems in these geologic settings are shallow and that fracture permeability outside of the influence of large-scale structures will follow a decreasing trend with depth.

Vorheriger Artikel Using multiple chemical indicators to characterize and determine the age of groundwater from selected vents of the Silver Springs Group, central Florida, USA

Nächster Artikel Simulated impacts of artificial groundwater recharge and discharge on the source area and source volume of an Atlantic Coastal Plain stream, Delaware, USA

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Anderson M (2005) Heat as a ground water tracer. Ground Water 43(6):951–968CrossRef

Bandis S, Lumsden A, Barton N (1983) Fundamentals of rock joint deformation. Int J Rock Mech Min Sci Geomech Abstr 20(6):249–268CrossRef

Barton C (1996) Characterizing bed rock fractures in outcrop for ground-water hydrology studies: an example from Mirror Lake, Grafton County, New Hampshire. In: Morganwalp D, Aronson D (eds) U.S. Geological Survey Toxic Substances Hydrology Program-Proceedings of the technical meeting, Colorado Springs, Colo. US Geol Surv Water Resour Invest Rep 94-4015

Batu V (1999) Aquifer hydraulics: a comprehensive guide to hydrogeologic data analysis. Wiley, New York

Bell K, Alvord D (1976) Pre-Silurian stratigraphy of northeastern Massachusetts, Memoir 148, Geological Society of America, Boulder, CO

Brown S, Scholz C (1986) Closure of rock joints. J Geophys Res Solid Earth 91(B5):4949–4948CrossRef

Caine J, Tomusiak S (2003) Brittle structures and their role in controlling porosity and permeability in a complex Precambrian crystalline-rock aquifer system in the Colorado Rocky Mountain Front Range. Geol Soc Am Bull 115(11):1410–1424CrossRef

Caine J, Evans J, Forster C (1996) Fault zone architecture and permeability structure. Geology 24:1025–1028CrossRef

Castle R, Dixon J, Grew E, Griscom A, Zeitz I (1976) Structural dislocations in Eastern Massachusetts, US Geol Surv Bull 1410

Davis S, Turk L (1964) Optimum depth of wells in crystalline rock. Ground Water 2:6–11CrossRef

Evans KF, Moriya H, Niitsuma H, Jones RH, Phillips WS, Genter A, Sausse J, Jung R, Baria R (2005) Microseismicity and permeability enhancement of hydrogeologic structures during massive fluid injections into granite at 3 km depth at the Soultz HDR site. Geophys J Int 160:388–412

Gillespie PA, Howard C, Walsh LL, Watterson L (1993) Measurement and characterisation of spatial distributions of fractures. Tectonophysics 226:113–141CrossRef

Gillespie PA, Walsh JJ, Watterson J, Bonson CG, Manzocchi T (2001) Scaling relationships of joint and vein arrays from The Burren, Co. Clare, Ireland. J Struct Geol 23:183–201CrossRef

Goldsmith R (1991) Stratigraphy of the Nashoba zone, Eastern Massachusetts: an enigmatic terrane. US Geol Surv Prof Pap 1366-E-J

Hatch N (ed) (1991) The bedrock map of Massachusetts, US Geol Surv Prof Pap 1366A-J

Hillis R (1987) The influence of fracture stiffness and the in situ stress field on the closure of natural fractures. Petrol Geosc 4(1):57–65CrossRef

Hsieh P (1996) An overview of field investigations of fluid flow in fractured crystalline rocks on the scale of hundreds of meters. In: Stevens P, Nicholson T (eds) Joint U.S. Geological Survey, Nuclear Regulatory Commission Workshop on Research Related to Low-Level Radioactive Waste Disposal, May 4–6, 1993. US Geol Surv Sci Invest Rep 95-4015

Hsieh P, Shapiro A (1996) Hydraulic characteristics of fractured bedrock under lying the FSE well field at the Mirror Lake site, Grafton County, New Hampshire. In: Morganwalp D, Aronson D (eds) U.S. Geological Survey Toxic Substances Hydrology Program: proceedings of the technical meeting, Colorado Springs, Colo. US Geol Surv Sci Invest Rep 94-4015, pp 127–130

Johnson C, Dunstan A (1998) Lithology and fracture characterization from drilling investigations in the Mirror Lake area from 1979 through 1995 in Grafton County New Hampshire. US Geol Surv Water Resour Invest Rep 98-4183

Johnson C, Williams J (2003) Hydraulic logging methods: a summary and field demonstration in Conyers, Rockdale County, Georgia. In: Williams L (ed) Methods used to assess the occurrence and availability of ground water in fractured-crystalline bedrock: an excursion into areas of Lithonia Gneiss in eastern metropolitan Atlanta, Georgia, vol 23. Georgia Geologic Survey, Atlanta, GA, pp 40-47

Legrand H (1954) Geology and ground water in the Statesville area, North Carolina. Bulletin, North Carolina Division of Mineral Resources, Raleigh, NC

Legrand H (1967) Ground water of the Piedmont and Blue Ridge provinces in the southeastern states. US Geol Surv Circ 528

Lyford FP, Carlson CS, Hansen BP (2003) Delineation of water sources for three public-supply wells in three fractured-bedrock aquifer systems in Massachusetts. US Geol Surv Water Resour Invest Rep 02-4290, 114 pp

Mabee S, Salamoff S (2006) Fracture characterization map of the Marlborough quadrangle, Massachusetts, Geologic Map GM06-02, Massachusetts Geological Survey, Cambridge, MA

Mabee SB, Hardcastle KC, Wise DU (1994) A method of collecting and analyzing lineaments for regional-scale fractured-bedrock aquifer studies. Ground Water 32(6):884–894CrossRef

Mackie D (2002) An integrated structural and hydrogeologic investigation of the fracture system in the upper Cretaceous Nanaimo group, southern Gulf Islands. MSc Thesis, Simon Fraser University, Canada

Manda A, Mabee S, Wise D (2008) Influence of rock fabric on fracture attribute distribution and implications for groundwater flow in the Nashoba terrane, eastern Massachusetts. J Struct Geol 30:464–477CrossRef

Maréchal JC, Dewandel B, Subrahmanyam K (2004) Use of hydraulic tests at different scales to characterize fracture network properties in the weathered-fractured layer of a hard rock aquifer. Water Resour Res 40, W11508. doi:10.1029/2004WR003137

Mazurek M (2000) Geological and hydraulic properties of water-conducting features in crystalline rocks. In: Stober I, Bucher K (eds) Hydrogeology of crystalline rocks. Kluwer, Dordrecht, The Netherlands, pp 3–26

Mazurek M, Jakob A, Bossart P (2003) Solute transport in crystalline rocks at Äspö: geological basis and model calibration. J Contam Hydrol 61:157–174CrossRef

Meinzer O (1923) The occurrence of ground water in the United States. US Geol Surv Water Suppl Pap 489

National Research Council (1996) Rock fractures and flow: contemporary understanding and applications. National Academy Press, Washington, DC

Paillet F (1985) Geophysical well log data for study of water flow in fractures near Mirror Lake. US Geol Surv Open-File Rep 85-340

Paillet F, Kapucu K (1989) Fracture characterization and fracture-permeability estimates from geophysical logs in the Mirror Lake watershed, New Hampshire. US Geol Surv Water Resour Invest Rep 89-4058

Park Y-J, Cornaton F, Normani S, Sykes J, Sudicky E (2008) Use of groundwater lifetime expectancy for the performance assessment of a deep geologic radioactive repository: 2. application to a Canadian shield environment. Water Resour Res 44(4), W04407. doi:10.1029/2007WR006, 212 pp

Robinson P, Goldsmith R (1991) Stratigraphy of the Merrimack belt, central Massachusetts. In: Hatch N (ed) The bedrock geology of Massachusetts, part II. US Geol Surv Prof Pap 1366E-J, pp G1–G37

Robinson P, Ratcliffe NM, Hepburn JC (1993) A tectonic-stratigraphic transect across the New England Caledonides of Massachusetts. In: Cheney JT, Hepburn J (eds) Guidebook for field trips in the northeastern United States, Geological Society of America Annual Meeting in Boston. University of Massachusetts, Amherst, MA, Contribution No. 67-1, pp C1–C47

Ruqvist J, Stephansson O (2003) The role of hydromechanical coupling in fractured rock engineering. Hydrogeol J 11(1):7–40

Seaton W, Burbey T (2005) Influence of ancient thrust faults on the hydrogeology of the Blue Ridge province. Ground Water 43(3):301–313CrossRef

Shapiro A, Hsieh P (1991) Research in fractured-rock hydrogeology: characterizing fluid movement and chemical transport in fractured rock at the mirror lake drainage basin, New Hampshire. In: U.S. Geol. Survey Toxic Substances Hydrology Program: Proc. of the technical meeting, Monterey, California, March 11–15, 1991. US Geol Surv Water Resour Invest Rep 91-4034

Shapiro A, Hsieh P (1994) Hydraulic characteristics of fractured bedrock underlying the FSE well Field at the mirror lake site, Grafton county, New Hampshire. In: U.S. Geological Survey Toxic Substance Hydrology Program: proceedings of the technical meeting, Colorado Springs, Colorado, September 20–24, 1993. US Geol Surv Water Resour Invest Rep 94-4015

Shapiro A, Hsieh P (1998) How good are estimates of transmissivity from slug tests in fractured rock. Ground Water 36(1):37–48CrossRef

Shapiro A, Hsieh P, Burton W, Walsh G (2007) Integrated multi-scale characterization of ground-water flow and chemical transport in fractured crystalline rock at the Mirror Lake site, New Hampshire. In: Hyndman F, Day-Lewis DW, Singha K (eds) Subsurface hydrology: data integration for properties and processes. Geophysical Monograph Series 171, American Geophysical Union, Washington, DC, pp 201–225

Snow D (1968) Rock fracture spacings, openings, and porosities. J Soil Mech Found Div 94(SM 1):73–91

Stober I, Bucher K (2004) Fluid sinks within the earth’s crust. Geofluids 4:143–151CrossRef

Surrette M, Allen D (2008) Quantifying heterogeneity in fractured sedimentary rock using a hydrostructural domain approach. Geol Soc Am Bull 120(1/2):225–235CrossRef

Surrette M, Allen D, Journeay M (2007) Regional evaluation of hydraulic properties in variably fractured rock using a hydrostructural domain approach. Hydrogeol J 16(1)11–30. doi:10.1007/s10,040-007-0206-9

Tiedeman C, Hsieh P (2001) Assessing an open-well aquifer test in fractured crystalline rock. Ground Water 39(1):68–78CrossRef

Wise D (2005) Rift and grain in basement: thermally triggered snapshots of stress fields during erosional unroofing of the Rocky Mountains of Montana and Wyoming. Rocky Mt Geol 40(2):193–209CrossRef

Wise DU, McCrory TA (1982) A new method of fracture analysis: azimuth versus traverse distance plots. Geol Soc Am Bull 93:889–897CrossRef

Wise DU, Funiciello R, Parotto M, Salvini F (1985) Topographic lineament swarms: clues to their origin from domain analysis of Italy. Geol Soc Am Bull 96:952–967CrossRef

Titel: A field study (Massachusetts, USA) of the factors controlling the depth of groundwater flow systems in crystalline fractured-rock terrain
verfasst von: David F. Boutt
Patrick Diggins
Stephen Mabee
Publikationsdatum: 01.12.2010
Verlag: Springer-Verlag
Erschienen in: Hydrogeology Journal / Ausgabe 8/2010
Print ISSN: 1431-2174
Elektronische ISSN: 1435-0157
DOI: https://doi.org/10.1007/s10040-010-0640-y

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