%0 Conference Paper %B Geological Society of America - Northeastern section %D 2016 %T Latest Paleozoic through Mesozoic faults in north-central Massachusetts and their correlations with New Hampshire %A Kopera J.P. %A Roden-Tice, M.K. %A Robert P Wintsch %K #Bibliography %K #StaffPubs %K AFT %K apatite %K apatite fission track %K brittle %K Campbel Hill %K Clinton Newbury %K Cretaceous %K extension %K fault %K fault zone %K fault zones %K faults %K fission track %K Fitchburg %K Fitchburg Plutons %K Flint Hill %K I-290 %K Johnny Appleseed %K Jurassic %K merrimack %K mesozoic %K Nashua Trough %K Normal Faults %K Oakdale formation %K Permian %K Pinnacle %K Rt 2 %K Sterling %K Stodge Meadow Pond %K Triassic %K Wachusett %K Wekepeke %K Worcester Formation %X

Several faults in south-central New Hampshire can be extended into Massachusetts (MA) as a result of detailed mapping in both states since publication of the MA state bedrock geologic map in 1983. Many of these faults delineate and/or cut Devonian metamorphic isograds in the Silurian Merrimack Belt in northern MA, and juxtapose chlorite-grade rocks in the Nashua sub-belt (NSB) between lithologically similar middle- to upper amphibolite-facies rocks on either side.

Recent mapping in the NSB, combined with previous studies, suggest it may represent a graben initially formed during latest Paleozoic transtension contemporaneous with formation of the Narragansett Basin in southeastern MA and RI. Mylonites along the Silver Hill-Wekepeke Fault (Robinson, 1981), bounding the western edge of the NSB, show east-side-down normal motion and west-side down normal motion along the Clinton-Newbury Fault Zone (CNFZ; Goldstein, 1994) which bounds the NSB’s southeastern margin. A possible extension of the Flint Hill fault system (NH) forms the eastern edge of the NSB offsetting the CNFZ with normal west-side down motion near Ayer, MA. Late brittle normal faults in the NSB are abundant. Late, low-T˚, west-side-down shear zones in the Nashoba Terrane and similar rocks to the south may also be related to down-dropping of the NSB.

AFT ages were collected across north-central MA to constrain its late uplift history. A ~127 Ma AFT age in the NSB is discontinuous with AFT ages in the belts adjoining it, with ~182-144 Ma ages west across the Wekepeke fault and ~160-167 Ma east across the CNFZ. To the west, the brittle southern extension of the Pinnacle Fault in NH (Stodge Meadow Pond fault of Peterson, 1984) follows the western edge of the Fitchburg plutons in MA while a well-exposed west-side down brittle normal fault system, possibly the southward extension of the Campbell Hill Fault (NH), is developed along their eastern edge. AFT ages of ~144-136 Ma immediately west of the Pinnacle Fault in MA are discontinuous with ~117-115 Ma ages immediately to the east within the Fitchburg plutons. A single ~106 Ma age in the plutons west of the Campbell Hill Fault in MA is discontinuous with ~128-123 Ma ages to the east of it. The discontinuities amongst AFT ages across these faults suggest that they may have been active through the Cretaceous.

 

 

%B Geological Society of America - Northeastern section %I Geological Society of America %C Albany, NY %G eng %U https://gsa.confex.com/gsa/2016NE/webprogram/Paper272576.html %R 10.1130/abs/2016NE-272576 %0 Report %D 1923 %T The commercial granites of New England %A Dale, T. Nelson %K #Bibliography %K #LegacyPublications %K Acton %K Becket %K Braintree %K Brockton %K Cohasset %K Dartmouth %K Fall River %K Fitchburg %K granite %K Groton %K Hingham %K joints %K Leominster %K Lynn %K Lynnfield %K Milford %K Milton %K Monson %K New Bedford %K Northbridge %K Otis %K Peabody %K Pelham %K quarries %K quarry %K Quincy %K Revere %K Rockport %K Stoughton %K Townsend %K Uxbridge %K Westford %K Wrentham %X

A report on the commerical granites of New England, their properties (jointing, rift, grain, etc...) and descriptions of active quarries in the towns of Acton, Becket, Braintree, Brockton, Cohasset, Dartmouth, Fall River, Fitchburg, Groton, Hingham, Leominster, Lynn, Lynnfield, Milford, Milton, Monson, New Bedford, Northbridge, Otis, Peabody, Pelham, quarries, quarry, Quincy, Revere, Rockport, Stoughton, Townsend, Uxbridge, Westford, and Wrentham.

KEYWORDS: granite, joint, quarry, quarries

%I United States Geological Survey %C Washington DC %P 448 %G eng %U https://pubs.er.usgs.gov/publication/b738 %9 Bulletin %0 Report %D 1982 %T Geomorphology of New England %A C.S. Denny %K #Bibliography %K #LegacyPublications %K coastal plain %K Cretaceous %K Eocene %K geomorphology %K landscape %K Miocene %K New England %K physiography %K plateau %K Pleistocene %K provinces %K river valleys %K rivers %K shallow bedrock %K uplands %X

Widely scattered terrestrial deposits of Cretaceous or Tertiary age and extensive nearshore and fluvial Coastal Plain deposits now largely beneath the sea indicate that the New England region has been above sea level during and since the Late Cretaceous. Estimates of rates of erosion based on sediment load in rivers and on volume of sediments in the Coastal Plain suggest that if the New England highlands had not been uplifted in the Miocene, the area would now be largely a lowland. If the estimated rates of erosion and uplift are of the right order of magnitude, then it is extremely unlikely that any part of the present landscape dates back before Miocene time. The only exception would be lowlands eroded in the early Mesozoic, later buried beneath Mesozoic and Cenozoic deposits, and exhumed by stream and glacial erosion during the later Cenozoic. Many of the rocks in the New England highlands are similar to those that underlie the Piedmont province in the central and southern Appalachians, where the relief over large areas is much less than in the highlands of New England. These comparisons suggest that the New England highlands have been upwarped in late Cenozoic time. The uplift took place in the Miocene and may have continued into the Quaternary. The New England landscape is primarily controlled by the underlying bedrock. Erosion and deposition during the Quaternary, related in large part to glaciation, have produced only minor changes in drainage and in topography. Shale and graywacke of Ordovician, Cambrian, and Proterozoic age forming the Taconic highlands, and akalic plutonic rocks of Mesozoic age are all highland makers. Sandstone and shale of Jurassic and Triassic age, similar rocks of Carboniferous age, and dolomite, limestone, and shale of Ordovician and Cambrian age commonly underlie lowlands. High-grade metapelites are more resistant than similar schists of low metamorphic grade and form the highest mountains in New England. Feldspathic rocks tend to form lowlands. Alkalic plutonic rocks of Mesozoic age underlie a large area in the White Mountains of New Hampshire and doubtless are a factor in their location and relief. Where the major streams flow across the regional structure of the bedrock, the location of the crossings probably is related to some other characteristic of the bedrock, such as joints or cross faults. The course of the Connecticut River is the result of the adjustment of the drainage to the bedrock geology during a long period of time. There is no ready explanation why many of the large rivers do not cross areas of calcalkalic plutonic rock, but rather take a longer course around such areas, which tend to include segments of the divide between the streams. The presence of coarse clastic materials in Miocene rocks of the emerged Coastal Plain of the Middle Atlantic States suggests uplift of the adjacent Piedmont and of the Adirondack Mountains at that time. The Miocene rocks of the submerged Coastal Plain in the Gulf of Maine and south of New England are fine grained and contain only small amounts of fluvial gravel. Perhaps the coarse clastic materials shed by the New England highlands in late Cenozoic time are buried by or incorporated in the Pleistocene glacial deposits.

%B USGS Professional Paper %I U.S. Geological Survey %C Reston, VA %P 18 %8 1982 %G eng %U https://pubs.er.usgs.gov/publication/pp1208