2006 Philadelphia Annual Meeting (22–25 October 2006)

Paper No. 28
Presentation Time: 6:00 PM-8:00 PM

A NEW WAY OF LOOKING AT, AND MAPPING, BEDROCK: THE HYDROSTRUCTURAL DOMAIN MAP OF THE AYER QUADRANGLE, NORTHEASTERN MASSACHUSETTS


KOPERA, Joseph, Sunderland, MA 01375 and MABEE, Stephen B., Office of the Massachusetts State Geologist, Dept. of Geosciences, University of Massachusetts-Amherst, Morrill Science Center, 611 North Pleasant Street, Amherst, MA 01003, jkopera@geo.umass.edu

While traditional bedrock geologic maps contain valuable information, they commonly lack data on fractures and physical properties of the rock. The increased need for better understanding of groundwater behavior in bedrock aquifers has made this data critical. Hydrostructural domain maps reclassify bedrock based on fracture systems and physical properties that may have implications for groundwater flow and recharge. These maps are constructed from detailed field observations and measurements of 2000-3000 fractures from 60-70 stations across a 7.5' quadrangle. Hydrostructural domains are displayed on the map as traditional lithologic units would be, with detailed descriptions and photos of the fracture characteristics and physical properties of each hydrostructural “unit”. In the Ayer quadrangle, such domains closely correspond with bedrock lithology and ductile structural history. Steeply dipping metasedimentary rocks of the Merrimack Belt have pervasive, closely spaced, throughgoing fractures developed parallel to foliation, and therefore provide an excellent potential for vertical recharge. Where these rocks are intensely cut by a strong subhorizontal cleavage, a parallel fracture set dominates providing an opportunity for lateral flow. Massive granites generally have a well developed, widely-spaced orthogonal network of fracture zones which may provide excellent local recharge. High-grade gneisses of the Nashoba terrane have poorly developed fracture sets except near regional shear zones, where foliation parallel fractures and cross-joints may provide good vertical recharge and provide a strong northeast trending flow anisotropy. These maps are intended to provide a regional-scale information to assist in site-specific groundwater investigations. We believe that such maps are an example of how new types of geologic maps can, and must, be developed to address changing societal needs.