U.S. Geological Survey 2018 vector digital data data release DOI:10.5066/P9E9EFNE Reston, VA U.S. Geological Survey https://doi.org/10.5066/P9E9EFNE https://www.sciencebase.gov/catalog/item/5bfd6064e4b0815414ca39e1 Elizabeth A. Pendleton Wayne E. Baldwin David S. Foster Seth D. Ackerman Brian D. Andrews Laura L. Brothers William C. Schwab 2018 data release DOI:10.5066/P9E9EFNE Reston, VA U.S. Geological Survey Suggested citation: Pendleton, E.A., Baldwin, W.E., Foster, D.F., Ackerman, S.D., Andrews, B.D, Brothers, L.L., and Schwab, W.C., 2018, Geospatial data layers of shallow geology, sea-floor texture, and physiographic zones from the inner continental shelf of Martha's Vineyard from Aquinnah to Wasque Point, and Nantucket from Eel Point to Great Point: U.S. Geological Survey data release, https://doi.org/10.5066/P9E9EFNE. https://doi.org/10.5066/P9E9EFNE https://www.sciencebase.gov/catalog/item/5afee3bfe4b0da30c1bfbd28 Geologic, sediment texture, and physiographic zone maps characterize the sea floor south and west of Martha's Vineyard and north of Nantucket, Massachusetts. These maps were derived from interpretations of seismic-reflection profiles, high-resolution bathymetry, acoustic-backscatter intensity, bottom photographs, and surficial sediment samples. The interpretation of the seismic stratigraphy and mapping of glacial and Holocene marine units provided a foundation on which the surficial maps were created. This mapping is a result of a collaborative effort between the U.S. Geological Survey and the Massachusetts Office of Coastal Zone Management to characterize the surface and subsurface geologic framework offshore of Massachusetts. These sea floor sediment texture distributions were created from geophysical and sample data collected from south of Martha's Vineyard and north of Nantucket, and are used to characterize the sea floor in the area. Sediment texture maps are important data layers for marine resource managers charged with protecting fish habitat, delineating marine boundaries, and assessing environmental change due to natural or human impacts. This data release is a companion publication to USGS OFR 2018-1181: Pendleton, E.A., Baldwin, W.E., Ackerman, S.D, Foster, D.S., Andrews, B.D., Schwab, W.C., and Brothers, L.L. 2018, Sea-floor texture and physiographic zones of the inner continental shelf from Aquinnah to Wasque Point, Martha’s Vineyard, and Eel Point to Great Point, Nantucket Island, Massachusetts: U.S. Geological Survey Open-File Report 2018–1181, https://doi.org/10.3133/ofr20181181. The data in the source contributions used for this compilation are from field activities 2007-011-FA (https://cmgds.marine.usgs.gov/fan_info.php?fan=2007-011-FA), 2011-004-FA (https://cmgds.marine.usgs.gov/fan_info.php?fan=2011-004-FA), and 2013-003-FA (https://cmgds.marine.usgs.gov/fan_info.php?fan=2013-003-FA). 20070809 20130611 ground condition of the source data used for the interpretation Complete None planned -70.8627 -70.0341 41.3894 41.1958 USGS Metadata Identifier USGS:5bfd6064e4b0815414ca39e1 None U.S. Geological Survey USGS Coastal and Marine Geology Program CMGP Woods Hole Coastal and Marine Science Center WHCMSC Massachusetts Office of Coastal Zone Management CZM Sea floor Marine Geology Interpretation Bathymetry Backscatter Slope Topography Esri Shapefile Bottom type Sediment Cover Sediment Texture Sediment Distribution Bottom Photographs Sediment Samples Seismic-reflection Profiles U.S. Geological Survey Open-File Report 2008-1288 U.S. Geological Survey Open-File Report 2012-1006 U.S. Geological Survey Open-File Report 2016-1168 USGS Thesaurus marine geology unconsolidated deposits sea-floor characteristics sand deposits gravel deposits clay deposits sedimentology grain-size analysis surficial geologic units rocks and deposits maps and atlases geospatial datasets scientific interpretation ISO 19115 Topic Category oceans geoscientificInformation None Vineyard Sound Nantucket Sound Atlantic Ocean Martha's Vineyard Nantucket Cape Cod Aquinnah Chilmark Squibnocket Point Squibnocket Beach Gay Head South Beach Katama Beach Wasque point Chappaquiddick Island Long Point Wildlife Refuge Tisbury Nomans Land Lucy Vincent Beach Tisbury Great Pond Beach Muskeget Island Tuckernuck Island Eel Point Dionis Beach Children's Beach Coatue Great Point Nantucket Harbor Wasque Shoal Muskeget Channel Tuckernuck Bank Tuckernuck Shoal Shovelful Shoal Massachusetts None Sea floor None Public domain data from the U.S. Government are freely redistributable with proper metadata and source attribution. Please recognize the U.S. Geological Survey (USGS) as the source of this information. Additionally, there are limitations associated with qualitative sediment mapping interpretations. Because of the scale of the source geophysical data and the spacing of samples, not all changes in sea floor texture are captured. The data were mapped between 1:8,000 and 1:25,000, but the recommended scale for application of these data is 1:25,000. Elizabeth A. Pendleton U.S. Geological Survey Geologist mailing and physical address

384 Woods Hole Rd.

Woods Hole MA 02543 USA 508-548-8700 x2226 508-457-2310 ependleton@usgs.gov https://www.sciencebase.gov/catalog/file/get/5bfd6064e4b0815414ca39e1/?name=MV_ACK_sedtexture_browse.png Image of the sediment texture shapefile for offshore of western and southern Martha's Vineyard and north of Nantucket. The browse graphic is derived from the companion OFR (Pendleton and others, 2018). PNG Kelley, J.T. Barnhardt, W.A. Belknap, D.F. Dickson, S.M. Kelley, A.R. 1998 Maine Geological Survey Open-File Report 96-6 Augusta, Maine Maine Geological Survey, Natural Resources Information and Mapping Center https://digitalmaine.com/mgs_publications/119/ Barnhardt, W.A. Kelley, J.T. Dickson, S.M. Belknap, D.F. 1998 Journal of Coastal Research 14(2) Royal Palm Beach, FL Coastal Education and Research Foundation, Inc. McMullen, K.Y. Paskevich, V.F. Poppe, L.J. 2014 3.0 Open-File Report 2005-1001 Reston, VA U.S. Geological Survey https://pubs.usgs.gov/of/2005/1001/ Ford, K.H. Voss, S.E 2010 Massachusetts Division of Marine Fisheries Technical Report TR-45 New Bedford, MA Massachusetts Division of Marine Fisheries U.S. Geological Survey 2013 Woods Hole Coastal and Marine Science Center, Woods Hole, MA U.S. Geological Survey, Coastal and Marine Geology Program Geologic mapping of the Massachusetts inner continental shelf is a cooperative effort that was initiated in 2003 by the U.S. Geological Survey (USGS) and the Massachusetts Office of Coastal Zone Management (CZM). The National Oceanic and Atmospheric Administration (NOAA-NOS) is also an important partner and contributes hydrographic data that are integrated into the maps. The overall goal of this cooperative is to determine the geologic framework of the sea floor inside the 3-mile limit of State waters, using high-resolution geophysical techniques, sediment sampling, and sea-floor photography. Any source data used to generate interpretative maps and data products are cited in detail in the source citation section of this metadata file. https://woodshole.er.usgs.gov/project-pages/coastal_mass/ Wayne E. Baldwin David S. Foster Elizabeth A. Pendleton Walter A. Barnhardt William C. Schwab Brian D. Andrews Seth Ackerman 2016 Open-File Report 2016-1119 Reston, VA US Geological Survey https://doi.org/10.3133/ofr20161119 David S. Foster Wayne E. Baldwin Walter A. Barnhardt William C. Schwab Seth D. Ackerman Brian D. Andrews Elizabeth A. Pendleton 2015 Open-File Report 2014-1220 Reston, VA U.S. Geological Survey https://doi.org/10.3133/ofr20141220 Elizabeth E. Pendleton Walter A. Barnhardt Wayne E. Baldwin David S. Foster William C. Schwab Brian D. Andrews Seth D Ackerman 2015 Open-File Report 2015-1153 Reston, VA U.S. Geological Survey https://doi.org/10.3133/ofr20151153 Elizabeth A. Pendleton Wayne E. Baldwin Walter A. Barnhardt Seth D. Ackerman David S. Foster Brian D. Andrews William C. Schwab 2013 Open-File Report 2012-1157 Reston, VA U.S. Geological Survey https://pubs.usgs.gov/of/2012/1157/ These data were drawn and vetted for accuracy using the source input raster files and point sample data described in the processing steps and source contributions. Overlapping features and unintentional gaps within the survey area were identified using the topology checker in ArcMap (version 10.5) and corrected or removed. Not all digitized sea-floor features contained sample information, so often the sea-floor texture is characterized by the nearest similar feature that contains a sample. Conversely, sometimes a digitized feature contained multiple samples and not all of the samples within the feature were in agreement (of the same texture). In these cases all data (raster and sample) were considered, and the dominant sediment texture from sample analyses did not necessarily determine the primary texture assigned to a polygon. Samples from rocky areas often only consist of bottom photographs, because large particle size often prevents the recovery of a sediment sample. Bottom photo classification can be subjective, such that determining the sediment type that is greater than 50% of the view frame is estimated by the interpreter and may differ among interpreters. Bottom photo transects often reveal changes in the sea floor over distances of less than 100 m and these changes are often not resolved in acoustic data. Heterogeneous sea floor texture can change very quickly, and many small-scale changes will not be detectable or mappable at a scale of 1:25,000. The boundaries of polygons are often inferred on the basis of sediment samples, and even boundaries that are traced on the basis of amplitude changes in geophysical data are subject to migration. Polygon boundaries should be considered an approximation of the location of a change in texture. These sediment cover data are defined for areas where source data exists. In general, gaps in the coverage coincide with gaps in the source data. However, some small data gaps were interpreted through extrapolation. Areas of lower data quality and incomplete coverage are noted in a data confidence attribute field. All of the interpretive layer bounds in this report are a little short of the data bounds in western Vineyard Sound, this is because this dataset abuts the interpretive layers of Baldwin and others (2016), and are not redundant with that interpretation. These data were produced qualitatively from acoustic and sample data with varying resolutions. Horizontal uncertainty associated with sample collection especially, can be quite high (100's of meters), much higher than positional uncertainty associated with acoustic data (usually less than 10's of meters). The date of sample collection and ship station positioning all contribute to sample position uncertainty. These qualitatively derived polygons outlining sea floor features are estimated to be within 50 meters, horizontally, but locally may be higher when delineation is based on sample information alone. Denny, J.F. Danforth, W.W. Foster, D.S. Sherwood, C.R. 2009 Open-File Report 2008-1288 Reston, VA U.S. Geological Survey http://pubs.usgs.gov/of/2008/1288/ online 20070809 20070813 ground condition Denny and others, 2009 This report provided source geophysical data (sidescan-sonar, bathymetry, and seismic-reflection profiles) for the area south of Martha's Vineyard surrounding the Martha's Vineyard Coastal Observatory. The 2007 mapping was conducted aboard the M/V Megan T. Miller. High-resolution chirp seismic-reflection profiles were collected during U.S. Geological Survey field activity 2007-011-FA using an EdgeTech Geo-Star full spectrum sub-bottom (FSSB) system and SB-0512i towfish. Thorough descriptions of acquisition and processing parameters for the survey are provided by Denny and others (2009) in the report and seismic-reflection metadata. Shallow geologic framework and surficial geology were interpreted from post-processed chirp seismic-reflection profiles. Andrews, B.D. Ackerman, S.D. Baldwin, W.E. Foster, D.S. Schwab, W.C. 2014 2.0 Open-File Report 2012-1006 Reston, VA U.S. Geological Survey https://pubs.usgs.gov/of/2012/1006/ online 20110507 20110517 ground condition Andrews and others, 2014 This report provided source geophysical data (sidescan-sonar, bathymetry, and seismic-reflection profiles) for the study area on the western side of Martha's Vineyard. The 2011 mapping was conducted on the R/V Scarlett Isabella during U.S. Geological Survey field activity 2011-004-FA. Chirp seismic-reflection data were collected using an EdgeTech Geo-Star FSSB subbottom profiling system and an SB-0512i towfish. Thorough descriptions of acquisition and processing parameters for each survey are provided by Andrews and others (2014) in the methods section and seismic-reflection metadata. Shallow geologic framework was interpreted from post-processed chirp seismic-reflection profiles. Only the data collected along the western shore of Martha’s Vineyard was used for this dataset. Ackerman, S.D. Brothers L.L. Foster, D.S. Andrews B.D. Baldwin W.E. Schwab W.C. 2016 Open-File Report 2016-1168 Reston, VA U.S. Geological Survey https://pubs.usgs.gov/of/2016/1168/ https://doi.org/10.3133/ofr20161168 online 20130522 20130611 ground condition Ackerman and others, 2016 This report provided source geophysical data (sidescan-sonar, bathymetry, and seismic-reflection profiles) for the majority of this study including offshore of southern Martha's Vineyard and north of Nantucket. These areas were surveyed with the R/V Scarlett Isabella 2013 during U.S. Geological Survey field activity 2013-003-FA. Seismic-reflection data were collected using an EdgeTech Geo-Star FSSB subbottom profiling system and an SB-0512i towfish. Thorough descriptions of acquisition and processing parameters for each survey are provided by Ackerman and others (2016) in the methods section and seismic-reflection metadata. Shallow geologic framework and surficial geology were interpreted from post-processed chirp seismic-reflection profiles. Brian Andrews Wayne Baldwin Daniel Sampson William Schwab 2018 1.0 data release DOI:10.5066/F72806T7 Reston, VA U.S. Geological Survey https://doi.org/10.5066/f72806t7 online 20110507 20130611 ground condition Andrews and others, 2018 This report provided source bathymetry for the study area including offshore of southern Martha's Vineyard and north of Nantucket. Thorough descriptions of the merging and processing parameters are provided by Andrews and others (2018) in the metadata. Ford, K.H. Huntley, E.C. Sampson, D.W. Voss, S. Unpublished Material This sample database has been compiled and vetted from existing samples and datasets by the Massachusetts Office of Coastal Zone Management. The data are currently unpublished, but may be acquired by contacting the CZM office: 251 Causeway St Boston, MA 02114 (617) 626-1000 czm@state.ma.us digital vector 19950101 20110101 ground condition CZM sample database Sediment sample databases of Ford and Voss (2010) and McMullen and others (2011) were combined then edited and supplemented with NOAA chart sampling data and bottom photos and descriptions by a group of GIS specialists at the Massachusetts Office of Coastal Zone Management (Emily Huntley, personal communication). These data contained sediment laboratory statistics when available, visual descriptions if sediment analysis was not performed or if the site was a bottom photograph, and classification fields of Barnhardt and others (1998), Shepard (1954), and Wentworth (1922) as well as average sediment statistics and phi size, when laboratory analysis was conducted. U.S. Army Corps of Engineers - Joint Airborne Lidar Bathymetry Center of Expertise 2009 Charleston, SC NOAA National Ocean Service (NOS), Coastal Services Center (CSC) http://coast.noaa.gov/dataviewer/index.html?action=advsearch&qType=in&qFld=ID&qVal=116 ftp://coast.noaa.gov/pub/DigitalCoast/lidar1_z/geoid12a/data/116 online 20070527 20070527 ground condition USACE-JALBTCX, 2009 The source lidar data for the very nearshore (less than -5 m) region along the western and southern shoreline of Martha's Vineyard. Lidar (Light Detection and Ranging) data were acquired with a SHOALS-1000T (for hydrographic and topographic data) using the Joint Airborne Joint Airborne LiDAR Bathymetry Center of Expertise (JALBTCX) lidar plane. These data are now publically available in LAS lidar format via NOAA's Digital Coast website. The texture and spatial distribution of sea-floor sediment were qualitatively analyzed in ArcGIS using several input data sources (listed in the source contribution), including acoustic backscatter, bathymetry, seismic-reflection profile interpretations, bottom photographs, and sediment samples. The interpretation was initiated by creating a new polygon feature class in an ArcMap 10.5 file geodatabase based on the extent of the regional bathymetric DEM (Andrews and others, 2018, and clipped to the extent of this study area). The polygon was then partitioned into multiple sediment texture polygons using 'cut polygon' and 'auto-complete polygon' in an edit session. In general, polygon editing was done at scales between 1:8,000 and 1:25,000, depending on the size of the traced feature and the resolution of the source data. Some areas interpreted as a single sediment textural unit may contain multiple polygons that indicate different interpretation confidence levels. The following numbered steps outline the workflow of the data interpretation. 1. Backscatter intensity data was the first input. Changes in backscatter were digitized to outline possible changes in sea-floor texture on the basis of acoustic return. Areas of high backscatter (light colors) have strong acoustic reflections and suggest boulders, gravels, and generally coarse sea-floor sediments. Low-backscatter areas (dark colors) have weak acoustic reflections and are generally characterized by finer grained material such as muds and fine sands. 2. The polygons were then refined and edited using gradient, rugosity, and hillshaded relief images derived from interferometric and multibeam swath bathymetry. Areas of rough topography and high rugosity are typically associated with rocky areas, while smooth, lower-relief regions tend to be blanketed by fine-grained sediment. These bathymetric derivatives helped to refine polygon boundaries where changes from primarily rock to primarily gravel may not have been apparent in backscatter data, but could easily be identified in hillshaded relief and slope changes. 3. The third data input (where available) was the stratigraphic interpretation of seismic-reflection profiles, which further constrained the extent and general shape of sea-floor sediment distributions and rocky outcrops, and also provided insight concerning the likely sediment texture of the feature on the basis of glacial or post-glacial origin. Seismic lines and the surficial geologic maps derived from them are used here as input data and were collected at typically 100-meter spacing, with tie-lines generally spaced 1-km apart. 4. After all the sea-floor features were traced from the geophysical data, a spatial join was conducted to provide grain size statistics based on sediment samples. The fields that contain sediment texture statistics or mean water depth information were created and populated using data joins or zonal statistics functions within ArcMap (version 10.5). The fields beginning with "Avg_" and the 'Count_' field were automatically generated by computing a data join where the CZM sample database (vector points) was edited to include only the samples with laboratory sediment analysis and joined to the qualitatively derived polygon file. The fields beginning with "Avg_" and ending in "_1" were automatically generated by computing a data join where the CZM sample database (vector points) included samples with laboratory and visual sediment analysis. Each polygon was given an average of the numeric attributes of the points (with laboratory grain size analysis or with and without laboratory analysis) that fall inside it, and the count field shows how many laboratory analyzed points fall inside each polygon. 153 samples were analyzed in the laboratory. Several fields that were not needed were deleted after the join. A mean water depth (NAVD 88) field was created using ArcMap (version 10.5): ArcToolbox - Spatial Analyst Tools > Zonal > Zonal Statistics as Table, where the mean water depth for each polygon (input zone data using the zone field sed_type) was derived from the regional bathymetric DEM (see Andrews and others, 2018). No data raster values were ignored in determining the output value for each polygon zone. The output was saved to a table, which was joined with the sediment type polygon shapefile. All of the joined fields except MEAN were turned off. 5. A new field was created in the shapefile called 'Barnhardt'. Seafloor composition observations from sediment samples and bottom photographs/video were used to define sediment texture for the polygons using Barnhardt and others (1998) classification. Samples with laboratory grain size analysis were preferred over visual descriptions when defining sediment texture throughout the study area; however within large polygons with a small number of samples (1 or 2), visual samples were considered and used to provide additional insight on the mean sediment texture. Bottom photo stations are typically around 2-km apart, but do not always provide a clear view of the sea floor, and the density of sediment samples varies throughout the study area. Some polygons contained more than one sample with grain-size statistics, while others contained none. For multiple samples within a polygon, the dominant sediment texture was used to classify sediment type (often aided by the 'data join' sediment statistics described in an earlier processing step). In rocky areas, bottom photos were used in the absence of sediment samples to qualitatively define sediment texture. Polygons that lacked sample information were texturally defined through extrapolation from adjacent or proximal polygons of similar acoustic character that did contain sediment samples. 2017 Elizabeth Pendleton U.S. Geological Survey Geologist mailing and physical address

384 Woods Hole Rd.

Woods Hole MA 02543 USA 508-548-8700 x2259 508-457-2310 ependleton@usgs.gov After some additional qualitative polygon editing and reshaping was done in order to create a sediment map that was in the best agreement with all input data: lidar, bathymetry, backscatter, seismic interpretations, bottom photographs, and sediment samples, 4 more fields were added (ArcMap version 9.3.1). The first field, 'simple' is just 3 classes: sand, mud, or hardbottom. A field 'Confidence' was added as a data interpretation confidence, which describes how confident we are in the interpretation on the basis of the number and quality of the input data sources (see the entity and attribute sections for more information on these fields). The last 2 ('Carbonate' and 'Biogenic_C') fields were added and populated manually to incorporate percent carbonate information that accompanied sample analyses in Nantucket Sound. Finally, a second join was conducted similar to the previous processing steps, but allowing all samples with analysis (visual and laboratory) to be incorporated into the statistics. The polygon feature class containing the sediment texture units was assigned topology rules, (i.e. no gaps and no overlaps). Topology errors were identified and remedied using the topology toolbar in ArcMap (10.5). Finally, the sediment texture was exported from the geodatabase as a shapefile. polygons containing sediment texture units 2017 Elizabeth Pendleton U.S. Geological Survey Geologist mailing and physical address

384 Woods Hole Rd.

Woods Hole MA 02543 USA 508-548-8700 x2259 508-457-2310 ependleton@usgs.gov Added keywords section with USGS persistent identifier as theme keyword. 20200807 U.S. Geological Survey VeeAnn A. Cross Marine Geologist Mailing and Physical

384 Woods Hole Road

Woods Hole MA 02543-1598 508-548-8700 x2251 508-457-2310 vatnipp@usgs.gov Vector G-polygon 438 0.0197427722 0.0261514554 Decimal seconds WGS_1984 WGS_84 6378137.0 298.257223563 MV_ACK_sedtexture.shp Sediment texture shapefile U.S. Geological Survey FID Internal feature number. Esri Sequential unique whole numbers that are automatically generated. Shape Feature geometry. Esri Coordinates defining the features. Barnhardt Bottom-type classification on the basis of twelve composite units that represent combinations of four end-member units (R= rock; G= gravel; S= sand; M= mud). Barnhardt and others (1998) G The end-member texture (= or greater than 90%) Gravel (G) is the primary texture. Barnhardt and others (1998) Gs The dominant texture (greater than 50%) Gravel (G) is given the upper case letter and the subordinate texture (less than 50%) sand (s) is given a lower case letter. Barnhardt and others (1998) S The end-member texture (= or greater than 90%) Sand (S) is the primary texture. Barnhardt and others (1998) Sg The dominant texture (greater than 50%) Sand (S) is given the upper case letter and the subordinate texture (less than 50%) gravel (g) is given a lower case letter. Barnhardt and others (1998) Sm The dominant texture (greater than 50%) Sand (S) is given the upper case letter and the subordinate texture (less than 50%) mud (m) is given a lower case letter. Barnhardt and others (1998) Ms The dominant texture (greater than 50%) Mud (M) is given the upper case letter and the subordinate texture (less than 50%) sand (s) is given a lower case letter. Barnhardt and others (1998) Rs The dominant texture (greater than 50%) Rock (R) is given the upper case letter and the subordinate texture (less than 50%) sand (s) is given a lower case letter. Barnhardt and others (1998) Sr The dominant texture (greater than 50%) Sand (S) is given the upper case letter and the subordinate texture (less than 50%) rock (r) is given a lower case letter. Barnhardt and others (1998) Confidence Each interpreted polygon was assigned a data interpretation confidence value from 1-4 (more to less confident) on the basis of the quality and number of input data sources. U.S. Geological Survey 1 Sediment texture regions that were defined on the basis of the highest resolution bathymetry (10m) and backscatter (1m), bottom photos, sediment samples with laboratory analysis, and seismic interpretations were given the highest data interpretation confidence value of 1. U.S. Geological Survey 2 Sediment texture regions that were defined on the basis of the highest resolution bathymetry (10m), backscatter (1m), and seismic interpretations, and possibly bottom photos and/or qualitative descriptions of sediment samples, but no sediment samples with laboratory analysis were given the data interpretation confidence value of 2 U.S. Geological Survey 3 Sediment texture regions that were defined on the basis of the highest resolution bathymetry (10m) and/or lidar bathymetry, and sediment samples with laboratory analysis and/or qualitative descriptions, but no acoustic backscatter or seismic interpretations were given the data interpretation confidence value of 3. U.S. Geological Survey 4 Sediment texture regions that were defined on the basis of the highest resolution bathymetry (10m) and/or lidar bathymetry, but no sediment samples with laboratory analysis and/or qualitative descriptions, and no acoustic backscatter or seismic interpretations were given the data interpretation confidence value of 3. U.S. Geological Survey Count_ The number of sediment samples (with laboratory analyzed grain size statistics) that occur within each qualitatively derived polygon. This field was automatically generated by Esri when point data (sample database) is joined to a polygon (sediment texture interpretation). A value of -999 indicates there are no samples within that polygon. Esri 1 33 count 1 Avg_GRAVEL Average percent weight (%) gravel (as determined from samples with laboratory analyzed grain size statistics) within each qualitatively derived polygon. This field was automatically generated by Esri as a summary of the numeric attributes of the points that fall inside a polygon when point data (sample database) is joined to a polygon (sediment texture interpretation). A value of -999 indicates that no sample was available within a particular feature. U.S. Geological Survey 0 30.73 percent Avg_SAND Average percent weight (%) sand within each qualitatively derived polygon. This field was automatically generated by Esri as a summary of the numeric attributes of the points that fall inside a polygon when point data (sample database) is joined to a polygon (sediment texture interpretation). A value of -999 indicates that no sample was available within a particular feature. U.S. Geological Survey 25.27 100 percent Avg_MUD Average percent weight (%) silt and clay within each qualitatively derived polygon. This field was automatically generated by Esri as a summary of the numeric attributes of the points that fall inside a polygon when point data (sample database) is joined to a polygon (sediment texture interpretation). A value of -999 indicates that no sample was available within a particular feature. U.S. Geological Survey 0 73.2 percent Carbonate Average percent weight (%) of carbonate within each qualitatively derived polygon. A few samples from Nantucket sound had received carbonate analysis and these data were incorporated into the CZM sample database. A value of -999 indicates that no sample was available within a particular feature. U.S. Geological Survey 0.02 23.25 percent Biogenic_c Description of carbonate sediment based on percent weight of carbonate. U.S. Geological Survey trace The weight percent of the coarse fraction (sand + gravel) that is carbonate is less than 2 percent U.S. Geological Survey present The weight percent of the coarse fraction (sand + gravel) that is carbonate is more than 2 percent but less than 10 percent U.S. Geological Survey abundant The weight percent of the coarse fraction (sand + gravel) that is carbonate is more than 10 percent but less than 50 percent U.S. Geological Survey unknown The weight percent of the coarse fraction (sand + gravel) that is carbonate is unknown because no carbonate analysis was performed. U.S. Geological Survey Avg_GRAVEL_1 Average percent weight (%) gravel (as determined from samples WITH and WITHOUT laboratory analyzed grain size statistics) within each qualitatively derived polygon. This field was automatically generated by Esri as a summary of the numeric attributes of the points that fall inside a polygon when point data (sample database) is joined to a polygon (sediment texture interpretation). A value of -999 indicates that no sample was available within a particular feature. U.S. Geological Survey 0 100 percent Avg_SAND_1 Average percent weight (%) sand (as determined from samples WITH and WITHOUT laboratory analyzed grain size statistics) within each qualitatively derived polygon. This field was automatically generated by Esri as a summary of the numeric attributes of the points that fall inside a polygon when point data (sample database) is joined to a polygon (sediment texture interpretation). A value of -999 indicates that no sample was available within a particular feature. U.S. Geological Survey 0 100 percent Avg_MUD_1 Average percent weight (%) mud (as determined from samples WITH and WITHOUT laboratory analyzed grain size statistics) within each qualitatively derived polygon. This field was automatically generated by Esri as a summary of the numeric attributes of the points that fall inside a polygon when point data (sample database) is joined to a polygon (sediment texture interpretation). A value of -999 indicates that no sample was available within a particular feature. U.S. Geological Survey 0 100 percent simple sediment nomenclature on the basis of 3 simple classes: sand, mud, hardbottom as defined in the CZM sample database U.S. Geological Survey sand Sediment whose primary component (greater than 50%) is sand U.S. Geological Survey hardbottom Sediment whose primary component is rock, boulder, cobble, or coarse gravel U.S. Geological Survey mud Sediment whose primary component (greater than 50%) is silt and clay U.S. Geological Survey water_dept Average seafloor elevation in meters below NAVD 88 within each qualitatively derived polygon. U.S. Geological Survey -31.45 -3.49 meters 0.01 U.S. Geological Survey GS ScienceBase mailing address

Denver Federal Center, Building 810, Mail Stop 302

Denver CO 80225 United States 1-888-275-8747 sciencebase@usgs.gov MV_ACK_sedtexture (and the related shapefile componensts) contains qualitatively derived polygons that define sea floor sediment texture offshore of western and southern Martha's Vineyard and north of Nantucket, MA. The dataset also contains a browse graphic (MV_ACK_sedtexture_browse.png), and the associated CSDGM metadata in XML format. Neither the U.S. Government, the Department of the Interior, nor the USGS, nor any of their employees, contractors, or subcontractors, make any warranty, express or implied, nor assume any legal liability or responsibility for the accuracy, completeness, or usefulness of any information, apparatus, product, or process disclosed, nor represent that its use would not infringe on privately owned rights. The act of distribution shall not constitute any such warranty, and no responsibility is assumed by the U.S. Geological Survey in the use of these data or related materials. Any use of trade, product, or firm names is for descriptive purposes only and does not imply endorsement by the U.S. Government shapefile ArcGIS v. 10.5.1 shapefile 0.39 https://www.sciencebase.gov/catalog/item/5bfd6064e4b0815414ca39e1 https://www.sciencebase.gov/catalog/file/get/5bfd6064e4b0815414ca39e1 https://doi.org/10.5066/P9E9EFNE To download the data, it is recommended that you go to the page containing the data and take advantage of the large file handler. The first link is to the page containing the data. The second is a direct link to download all data available from the page as a zip file. And the final link is to the publication landing page. WMS ArcGIS v. 10.5.1 shapefile provided through a WMS (web mapping service). https://www.sciencebase.gov/catalogMaps/mapping/ows/5aff06afe4b0da30c1bfcdf1?service=wms&request=getcapabilities&version=1.3.0 https://www.sciencebase.gov/catalog/item/5aff06afe4b0da30c1bfcdf1 https://doi.org/10.5066/P9E9EFNE The first link in the network resources accesses the data through a coverage service, the second is to the page containing the data, and the third link is to the publication landing page. WFS ArcGIS v. 10.5.1 shapefile provided through a WFS (web feature service). https://www.sciencebase.gov/catalogMaps/mapping/ows/5aff06afe4b0da30c1bfcdf1?service=wfs&request=getcapabilities&version=1.0.0 https://www.sciencebase.gov/catalog/item/5aff06afe4b0da30c1bfcdf1 https://doi.org/10.5066/P9E9EFNE The first link in the network resources accesses the data through a mapping service, the second is to the page containing the data, and the third link is to the publication landing page. None These data are available in Environmental Systems Research Institute (Esri) shapefile format. The user must have software capable of importing and processing this data type. 20240319 2017 Elizabeth A Pendleton U.S. Geological Survey Geologist mailing and physical address

384 Woods Hole Rd.

Woods Hole MA 02543 USA 508-548-8700 x2259 508-457-2310 whsc_data_contact@usgs.gov The metadata contact email address is a generic address in the event the person is no longer with USGS. (updated on 20240319) FGDC Content Standards for Digital Geospatial Metadata FGDC-STD-001-1998 local time None None