TY - Generic T1 - Geochemistry of gneisses and amphibolites in the Uchee Belt of western Georgia and eastern Alabama; an ACRES progress report T2 - Abstracts with Programs - Geological Society of America Y1 - 2000 A1 - Joseph P Kopera A1 - Nicholas, Brian A1 - Todd, Dave A1 - Davison, Jeff A1 - Hanley, Tom A1 - Kar, Aditya A1 - La Tour, Timothy E. A1 - Edwards, Tonya KW - #StaffPubs KW - Alabama KW - amphibolite KW - chemical composition KW - Columbus Georgia KW - dikes KW - Georgia KW - gneisses KW - Igneous and metamorphic petrology 05A KW - inclusions KW - intrusions KW - metamorphic rocks KW - Muscogee County Georgia KW - Uchee Belt KW - United States KW - xenoliths AB - Undergraduate students, high school teachers, and university faculty representing ACRES (Atlanta Consortium for Research in Earth Sciences) studied lineated gneiss (LG) exposed at Flat Rock Park (FRP) and vicinity in Columbus, GA, and Motts gneiss (MG) in eastern Alabama. The LG and MG are mineralogically and geochemically granitoidal lineated orthogneisses. They contain deformed mafic xenoliths, as well as aplitic, granitic and pegmatoidal dikes that cut the dominant lineation. Based on chemical analyses, the LG from FRP and the MG plot as granite on the IUGS diagrams and the Le Bas diagram. Similarity in incompatible trace element ratios (e.g., Zr/Nb) and highly evolved characteristics of aplite with respect to the host gneisses, indicate there is probably a genetic link between the MG and the FRP LG. These rocks are chemically distinct from other nearby felsic gneiss. Phenix City gneiss amphibolites from Lindsey Creek and North Highland Mills dam in Columbus were also analyzed for major and trace elements. These amphibolites are low K tholeiitic rocks with an island arc affinity and are similar to rocks from the area that have already been analyzed. The amphibolites show a wide range of fractionation (41 to 62 percent SiO (sub 2) ). Consistency in incompatible element ratios over a wide range of fractionation of some of the samples show a probable genetic relationship among the various amphibolites of Lindsey Creek. Future work should involve more extensive collecting and analysis of both felsic rocks and amphibolites in the Uchee belt. More time should also be spent describing the thin sections of the existing collection and comparing the REE patterns for the FRP, MG and other felsic rocks in the Uchee belt. JF - Abstracts with Programs - Geological Society of America PB - Geological Society of America (GSA) : Boulder, CO, United States CY - United States VL - 32 SN - 00167592 IS - 22 N1 - Accession Number: 2002-039126; Conference Name: Geological Society of America, Southeastern Section, 49th annual meeting; Charleston, SC, United States; Conference Date: 20000323; Language: English; Coordinates: N322800N322800W0845900W0845900; Coden: GAAPBC; Collation: 1; Collation: 31; Publication Types: Abstract Only; Serial; Conference document; Updated Code: 200214; Monograph Title: Geological Society of America, Southeastern Section, 49th annual meeting; Monograph Author(s): Anonymous; Reviewed Item: Analytic JO - Abstracts with Programs - Geological Society of America ER - TY - Generic T1 - Granite as a geothermal resource in the Northeast T2 - Abstracts with Programs - Geological Society of America Y1 - 2012 A1 - John Michael Rhodes A1 - Koteas, G. Christopher A1 - Stephen B Mabee KW - #StaffPubs KW - Cammenallis Pluton KW - Cornwall England KW - Eastern U.S. KW - Economic geology, geology of energy sources 29A KW - energy sources KW - England KW - Europe KW - geothermal energy KW - geothermal exploration KW - granites KW - Great Britain KW - heat flow KW - hydrothermal conditions KW - igneous rocks KW - intrusions KW - Northeastern U.S. KW - plutonic rocks KW - plutons KW - thermal conductivity KW - United Kingdom KW - United States KW - Western Europe AB - In the absence of volcano-derived hydrothermal activity and high heat flow, granitic plutons provide an alternative geothermal resource from which heat may be usefully extracted. Compared with other crustal rocks, granites contain higher concentrations of the heat producing elements (K, U, Th). Additionally, they are more homogeneous and have simpler fracture systems than surrounding country rock, allowing for stimulation through hydro-fracking of large (>1 km (super 3) ) geothermal reservoirs. However, not all granites are created equal! Those with heat production > 5 mu W/m (super 3) , or with deep batholithic roots, are the most promising. Estimated temperatures at a given depth are related to the heat production, thickness and thermal conductivity of the granite. For example, the Carnmenellis Pluton in Cornwall, England (which will be drilled in 2012) is estimated to have temperatures in excess of 170 degrees C at a depth of 5 km, which is sufficient for co-production of electricity and hot water for heating. More importantly, granite bodies that are buried beneath thick sequences of thermally insulating sediments are also potential geothermal targets. Most successful examples to date include the Soultz sur Foret project in France, with temperatures of 200 degrees C at a depth of 5 km. (and which is currently producing electricity), Innamincka, Australia, with temperatures of 250 degrees C at a depth of 4 km. (which will be producing in 2012), and the seismically ill-fated project in Basel, Switzerland. Surely, if such projects involving the geothermal potential of granites, can succeed elsewhere, they can succeed here in the granite-rich Northeast? The geothermal potential of the Conway Granite, NH has long been recognized. Other possibilities include the Fitchburg Pluton, MA, and granites buried beneath the Carboniferous sediments of the Narragansett Basin and the Triassic sediments of the Connecticut River valley. JF - Abstracts with Programs - Geological Society of America PB - Geological Society of America (GSA) : Boulder, CO, United States CY - United States VL - 44 SN - 00167592 UR - https://gsa.confex.com/gsa/2012NE/finalprogram/abstract_200603.htm IS - 22 N1 - Accession Number: 2012-090078; Conference Name: Geological Society of America, Northeastern Section, 47th annual meeting; Hartford, CT, United States; Conference Date: 20120318; Language: English; Coden: GAAPBC; Collation: 1; Collation: 76; Publication Types: Abstract Only; Serial; Conference document; Updated Code: 201247; Monograph Title: Geological Society of America, Northeastern Section, 47th annual meeting; Monograph Author(s): Anonymous; Reviewed Item: Analytic JO - Abstracts with Programs - Geological Society of America ER - TY - Generic T1 - Ground truth? Relationship between lineaments and bedrock fabric T2 - Abstracts with Programs - Geological Society of America Y1 - 1989 A1 - Stephen B Mabee A1 - Hardcastle, Kenneth C. A1 - Donald U Wise KW - #StaffPubs KW - aerial photography KW - BEDROCK KW - fabric KW - faults KW - fractures KW - granites KW - ground truth KW - igneous rocks KW - joints KW - lineaments KW - Maine KW - orientation KW - pegmatite KW - plutonic rocks KW - quartz veins KW - SLAR KW - structural analysis KW - Structural geology KW - Structural geology 16 KW - United States KW - veins JF - Abstracts with Programs - Geological Society of America PB - Geological Society of America (GSA) : Boulder, CO, United States CY - United States VL - 21 SN - 00167592 IS - 66 N1 - Accession Number: 1991-043915; Conference Name: Geological Society of America, 1989 annual meeting; St. Louis, MO, United States; Conference Date: 19891106; Language: English; Coden: GAAPBC; Collation: 1; Collation: A68; Publication Types: Abstract Only; Serial; Conference document; Updated Code: 1991; Monograph Title: Geological Society of America, 1989 annual meeting; Monograph Author(s): Dymek, Robert F. [chairperson]; Shelton, Kevin L. [chairperson]; Reviewed Item: Analytic JO - Abstracts with Programs - Geological Society of America ER - TY - Generic T1 - Guiding principles for use of digital technology in geologic data collection and distribution T2 - Abstracts with Programs - Geological Society of America Y1 - 2014 A1 - Joseph P Kopera A1 - House, P. Kyle A1 - Schmidt, Maxine A1 - Clark, Ryan KW - #StaffPubs KW - data KW - data preservation KW - databases KW - digital KW - digital data KW - digital geologic maps KW - geologic maps KW - GIS KW - migration AB - The past decade has seen a dramatic shift in the public perception of a map as a static paper document to a dynamic digital interface for addressing a specific geographic question. The adoption of digital technology for geologic data collection, compilation, and distribution has many advantages but requires a similar shift in attitudes towards the nature of data and resulting maps themselves to ensure that they remain accessible, viable, and relevant in this new paradigm. We propose a set of guiding principles for the use of digital technology in geologic data and map production: 1.) Utilize dedicated digital data professionals (DDPs): It is unreasonable to expect that geologists maintain expertise in their field and be thoroughly versed in complex and rapidly changing best practices for digital data. Following the recommendations of the National Research Council (2009), DDPs should be embedded in any research endeavor from its inception with geologists being savvy enough in digital technology to maintain productive engagement with DDPs. 2.) Use appropriate technology: Fully digital workflows and field equipment are not appropriate for all projects. Free or open-source software (FOSS) and easily available low-cost hardware (i.e., smartphones) have also met or surpassed the utility of many proprietary technology solutions thus reducing the price and increasing accessibility of data. 3.) Practice good data management: Digital data takes considerable resources and sustained effort to remain viable even shortly after its production. Best practices in data accessibility (data standards, open formats, etc.) and maintenance (refreshing, migration, etc.) in addition to robust metadata creation, through all phases of a project, are unquestionably necessary. 4.) Approach maps and digital data as living dynamic entities: Geologic data is out of date the moment it is published. A primary advantage of digital datasets is their ability to be easily updated, queried, and manipulated in infinite ways. Derivative products for specific applications are in arguably higher demand by end users than the data itself. Geologists must design for flexibility, appropriateness of use, and the persistence of their expert interpretations through development of all possible end products of and updates to the map and dataset. JF - Abstracts with Programs - Geological Society of America PB - Geological Society of America (GSA) : Boulder, CO, United States VL - 46 SN - 00167592 UR - https://gsa.confex.com/gsa/2014NE/webprogram/Paper236362.html JO - Abstracts with Programs - Geological Society of America ER - TY - DATA T1 - Geologic Fieldtrip Guidebook database for North America Y1 - 0 KW - educational resources KW - GEOLOGY KW - guidebooks KW - massachusetts PB - American Geolosciences Institute UR - http://guide.georef.org/dbtw-wpd/guidens.htm ER - TY - Generic T1 - Geomorphic effects of Tropical Storm Irene on western Massachusetts: Landslides and fluvial erosion along the Deerfield and Cold rivers, Charlemont and Savoy, MA Y1 - 2014 A1 - Stephen B Mabee KW - #Landslides KW - #MGSPub KW - #MGSPubs KW - #NaturalHazards KW - #Reports KW - #Water KW - 2011 KW - Charlemont KW - Cold River KW - Deerfield River KW - fluvial KW - fluvial erosion KW - hurricane irene KW - Irene KW - landslide KW - landslides KW - route 2 KW - Rt 2 KW - Savoy KW - tropical storm AB - A poster summarizing the effects of 2011 Tropical Storm Irene in western MA. PB - Massachusetts Geological Survey UR - http://www.geo.umass.edu/stategeologist/Products/reports/Landslide2_web.pdf ER - TY - RPRT T1 - Geomorphology of New England Y1 - 1982 A1 - C.S. Denny KW - #Bibliography KW - #LegacyPublications KW - coastal plain KW - Cretaceous KW - Eocene KW - geomorphology KW - landscape KW - Miocene KW - New England KW - physiography KW - plateau KW - Pleistocene KW - provinces KW - river valleys KW - rivers KW - shallow bedrock KW - uplands AB -

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.

JF - USGS Professional Paper PB - U.S. Geological Survey CY - Reston, VA UR - https://pubs.er.usgs.gov/publication/pp1208 ER - TY - RPRT T1 - A Guide to On-Line Geological Information and Publications for Use in GSHP Site Characterization Y1 - 2000 A1 - Kevin Rafferty KW - #Geothermal KW - #GeothermalHomeownerResources KW - geothermal KW - ground source heat pumps KW - GSHP AB - One of the first steps in the consideration of a GSHP system is a characterization of the site in terms of geology and groundwater availability. Information concerning aquifer (or aquifers) available at the site, their ability to produce water, depth to water, geology, depth to bedrock and the nature of the soil and rock (hydraulic and thermal properties) are key issues. This information guides the designer in the selection of the type of GSHP system to be used and in the design of the system. The ground source industry has not taken full advantage of available geological information resources in the past. This document is an effort to introduce GSHP designers to some of these information sources and the nature of the data that is available. A special emphasis has been placed on Internet based resources operated by government agencies--primarily the USGS and state geological surveys. The following section provides some background information on the maps and other information sources in general. This is followed by summaries of information available for the most active GSHP states. PB - Geo-Heat Center, Oregon Institute of Geology CY - Klamath Falls, Oregon UR - http://geoheat.oit.edu/otl/guidegshp.pdf ER - TY - COMP T1 - Geograph MA Y1 - 0 AB -

Do you know which state assembly district you are in? What kind of rock are you sitting on? Which school district is this house in? Where is the closest railroad? Are you in a floodable zone?

Geograph MA is the Massachusetts version of the first GIS (geographical information system) for the iPhone. With its 48 (and counting) layers of information, it will help you understand your surroundings and become aware of the geography around you.

JF - iPhone App PB - Integrity Logic UR - http://www.integrity-logic.com/GeographMA U1 -

 Massachusetts Geology/Geography on your iPhone!

ER - TY - Generic T1 - Geologic Fieldtrip Guidebook database for North America - (AGI) Y1 - 0 KW - #EducationalResources KW - #Fieldtrips KW - field trips KW - geologic KW - guidebooks KW - site KW - visit AB - A thorough and searchable database to all geologic fieldtrip guidebooks published for field trips in the united states. A great resource! PB - AGI UR - http://guide.georef.org/dbtw-wpd/guidens.htm ER - TY - Generic T1 - Geology Tours of National Parks Y1 - 0 KW - #EducationalResources KW - #Fieldtrips KW - activities KW - classroom KW - curricula KW - earth science KW - education KW - GEOLOGY KW - groundwater KW - K-12 KW - lesson plans KW - national parks KW - parks KW - schools KW - standards KW - teacher resources KW - teaching KW - water KW - water cycle AB - Provides information on the geology of national parks and related resources. PB - NPS UR - http://www2.nature.nps.gov/geology/tour/index.htm ER - TY - Generic T1 - Geothermal Heat Pump Information Y1 - 0 KW - #Geothermal KW - #GeothermalHomeownerResources KW - alternative energy KW - EGS KW - ehanced geothermal systems KW - geothermal KW - green energy KW - GSHP KW - hot dry rock KW - renewables AB - All things geothermal. From the U.S. Department of Energy. PB - U.S. Department of Energy UR - http://energy.gov/eere/geothermal/geothermal-energy-us-department-energy ER - TY - Generic T1 - Geothermal Heating and Cooling Technologies Y1 - 0 KW - #Geothermal KW - #GeothermalHomeownerResources KW - geothermal KW - Ground Source Heat Pump KW - GSHP AB - US-EPA primer for the homeowner on geothermal technologies with links to more resources. UR - http://www2.epa.gov/rhc/geothermal-heating-and-cooling-technologies#Ground ER - TY - Generic T1 - GRASS GIS Y1 - KW - #GISSoftware KW - #MapsDataPublications KW - GIS software KW - Open Source AB - GRASS GIS, commonly referred to as GRASS (Geographic Resources Analysis Support System), is a free Geographic Information System (GIS) software used for geospatial data management and analysis, image processing, graphics/maps production, spatial modeling, and visualization. GRASS GIS is currently used in academic and commercial settings around the world, as well as by many governmental agencies and environmental consulting companies. GRASS GIS is an official project of the Open Source Geospatial Foundation (OSGeo). PB - GRASS / OSGeo UR - http://grass.osgeo.org/ ER - TY - Generic T1 - Great Falls Discovery Center (Turner's Falls, MA) Y1 - KW - #EducationalResources KW - #Museums KW - dinosaurs KW - field trips KW - footprints KW - fossils KW - Massachusetts Geology KW - mesozoic KW - minerals KW - museums KW - natural history PB - Pioneer Valley Institute UR - http://greatfallsdiscoverycenter.org/ ER - TY - Generic T1 - gvSIG Y1 - KW - #GISSoftware KW - #MapsDataPublications KW - GIS software KW - Open Source AB - gvSIG is a Geographic Information System (GIS), that is, a desktop application designed for capturing, storing, handling, analyzing and deploying any kind of referenced geographic information in order to solve complex management and planning problems. gvSIG is known for having a user-friendly interface, being able to access the most common formats, both vector and raster ones. It features a wide range of tools for working with geographic-like information (query tools, layout creation, geoprocessing, networks, etc.), which turns gvSIG into the ideal tool for users working in the land realm. PB - gvSIG UR - http://www.gvsig.org/web/ ER -