I. Data Set Descriptors A. Title: Daniela Di Iorio. 2022. Continuous salinity, temperature and depth measurements from moored hydrographic data loggers deployed at GCE7_Hydro (Altamaha River near Carrs Island, Georgia) from 01-Jan-2020 through 31-Dec-2020. Georgia Coastal Ecosystems LTER Data Catalog (data set PHY-GCEM-2111e; http://gce-lter.marsci.uga.edu/data/PHY-GCEM-2111e) B. Accession Number: PHY-GCEM-2111e C. Description 1. Originator(s): Name: Daniela Di Iorio Address: Dept. of Marine Sciences University of Georgia Athens, Georgia 30602-3636 Country: USA Email: daniela@uga.edu 2. Abstract: Conductivity, temperature and pressure were measured continuously at Georgia Coastal Ecosystems LTER sampling location GCE7_Hydro (Altamaha River near Carrs Island, Georgia) from 01-Jan-2020 through 31-Dec-2020. Observations were logged at 30 minute intervals by moored Sea-Bird Electronics MicroCAT 37-SM data loggers and downloaded approximately semi-monthly. Salinity, depth and sigma-t (density anomaly) were calculated from the measured parameters using standard UNESCO algorithms. This data set was collected as part of the GCE-LTER Project continuous salinity, temperature and water level monitoring program. 3. Study Type: Monitoring 4. Study Themes: Physical Oceanography 5. LTER Core Areas: Other Site Research 6. Georeferences: geographic coordinates as data columns 7. Submission Date: May 18, 2022 D. Keywords: conductivity, density, depth, GCE, Georgia, Georgia Coastal Ecosystems, Hydrographic Moorings, hydrography, Inorganic Fluxes, inorganic nutrients, LTER, monitoring, mooring, pressure, salinity, Sapelo Island, sonde, temperature, USA, water column, water quality II. Research Origin Descriptors A. Overall Project Description 1. Project Title: Georgia Coastal Ecosystems LTER - IV 2. Principal Investigators: Name: Merryl Alber Address: Dept. of Marine Sciences University of Georgia Athens, Georgia 30602-3636 Country: USA Email: malber@uga.edu 3. Funding Period: Feb 01, 2019 to Jan 31, 2025 4. Objectives: The GCE-LTER project has four goals. 1) Track environmental and human drivers that can cause perturbations in our focal ecosystems. This will be accomplished this through continuing long-term measurements of climate, water chemistry, oceanic exchange, and human activities on the landscape. 2) Describe temporal and spatial variability in physical, chemical, geological and biological characteristics of the study system (coastal wetland complexes) and how they respond to external drivers. This will be accomplished through field monitoring in combination with remote sensing and modeling. 3) Characterize the ecological responses of intertidal marshes to disturbance. This will be accomplished by ongoing monitoring and experimental work to evaluate system responses to major perturbations in three key marsh habitats (changes in inundation and predator exclusion in Spartina-dominated salt marshes; increases in salinity in fresh marshes; changes in runoff in high marshes), by implementing standardized experimental disturbances along salinity and elevation gradients, and by tracking responses to natural disturbances. 4) Evaluate ecosystem properties at the landscape level (habitat distribution, net and gross primary production, C budgets) and assess the cumulative effects of disturbance on these properties. The project will also develop relationships between drivers and response variables, which can be used to predict the effects of future changes. This will be accomplished through a combination of data synthesis, remote sensing and modeling. 5. Abstract: The Georgia Coastal Ecosystems (GCE) Long Term Ecological Research (LTER) program, based at the University of Georgia Marine Institute on Sapelo Island, Georgia, was established in 2000 to study long-term change in coastal ecosystems. Estuaries (places where salt water from the ocean mixes with fresh water from the land) and their adjacent marshes provide food and refuge for fish, shellfish and birds; protect the shoreline from storms; help to keep the water clean; and store carbon. The GCE LTER researchers study marshes and estuaries to understand how these ecosystems function, to track how they change over time, and to predict how they might be affected by future changes in climate and human activities. They accomplish this by tracking the major factors that can cause long-term change in coastal areas (e.g. sea level, rainfall, upstream development), and measuring the effects of these factors on the study site. They also conduct focused studies to assess how key marsh habitats will respond to major changes expected in the future, including large-scale experiments to evaluate the effects of a) increases in the salinity of the water that floods freshwater marshes (mimicking drought and/or sea level rise), b) changes in water runoff from land into the upland marsh border (mimicking drought or upland development), and c) exclusion of larger organisms in the salt marsh (mimicking long-term declines in predators). During this award they will initiate additional studies to systematically evaluate how coastal wetlands respond to disturbances. Disturbances, or disruptions in the environment, are particularly important to understand in the context of long-term background changes such as increasing sea level, and GCE researchers are working to assess the cumulative effects of multiple disturbances on the landscape. The GCE education and outreach program works to share an understanding of coastal ecosystems with teachers and students, coastal managers, citizen scientist and the general public. 6. Funding Source: NSF OCE 1832178 B. Sub-project Description 1. Site Description a. Geographic Location: GCE-AL -- Altamaha River, Georgia, USA GCE7_Hydro -- Hammersmith Creek hydrographic datalogger deployment Coordinates: GCE-AL -- NW: 081 34 56.32 W, 31 24 05.05 N NE: 081 14 16.57 W, 31 24 05.05 N SE: 081 14 16.57 W, 31 17 45.72 N SW: 081 34 56.32 W, 31 17 45.72 N GCE7_Hydro -- 81 28 31.7 W, 31 20 17.5 N b. Physiographic Region: GCE-AL -- Estuary and tidal marsh GCE7_Hydro -- Estuary and tidal marsh c. Landform Components: GCE-AL -- Intertidal marsh bordering sounds, tidal channels and creeks GCE7_Hydro -- Intertidal marsh bordering sounds, tidal channels and creeks d. Hydrographic Characteristics: GCE-AL -- Site encompasses the Altamaha River estuary and nearby tidal creeks, and is subject to 2-3.4m semi-diurnal tides. High freshwater input from the Altamaha River, one of the largest rivers in the Southeastern United States. GCE7_Hydro -- Site encompasses the Altamaha River estuary and nearby tidal creeks, and is subject to 2-3.4m semi-diurnal tides. High freshwater input from the Altamaha River, one of the largest rivers in the Southeastern United States. e. Topographic Attributes: GCE-AL -- Flat, with elevations ranging from 0-3.4m above mean low tide GCE7_Hydro -- Flat, with elevations ranging from 0-3.4m above mean low tide f. Geology, Lithology and Soils: GCE-AL -- unspecified GCE7_Hydro -- unspecified g. Vegetation Communities: GCE-AL -- unspecified GCE7_Hydro -- unspecified h. History of Land Use and Disturbance: none recorded i. Climate: Climate summary for Sapelo Island, Georgia, based on NWS data from 1980-2010: Daily-aggregated Values: Mean (sample standard deviation) mean air temperature: 20.09°C (7.28°C) minimum air temperature: 15.02°C (7.96°C) maximum air temperature: 24.82°C (6.98°C) total precipitation: 3.26mm (10.3mm) Yearly-aggregated Daily Values: Mean (sample standard deviation) total precipitation (1980-2010): 1124mm (266mm) 2. Experimental or Sampling Design a. Design Characteristics: Conductivity, temperature and pressure were continuously monitored using an autonomous data-logging sensor package (sonde) that was moored to a piling and submerged 1-1.5m below mean low water. b. Permanent Plots: none c. Data Collection Duration and Frequency: The MicroCAT was programmed to autonomously measure and log conductivity, temperature and pressure at a sampling rate of 30 minutes (based on its internal chronometer). Upon retrieval the data was downloaded from the instrument via RS-232 serial communications and processed using custom Matlab(r) procedures to calculate depth (i.e. from pressure and latitude), salinity and sigma-t (i.e. from conductivity and temperature), and date and time components from sample time stamps. Beginning of Observations: Jan 01, 2020 End of Observations: Dec 31, 2020 3. Research Methods a. Field and Laboratory Methods: Method 1: Deployment -- The MicroCAT was mounted inside a protective PVC pipe enclosure and attached to a wooden piling (~12 inch diameter) that was driven firmly into the substrate. The enclosure was constructed from a 10-foot length of 6-inch (internal diameter) PVC pipe that was perforated all over by drilling 1.5-inch holes (at approximately 4-inch spacing); this permits proper water circulation within the enclosure. The bottom of the PVC pipe was submerged about 5 feet below the water surface at low tide and bolted (vertically) to the piling. The MicroCAT was deployed by lowering it into the enclosure on a 0.375-inch stainless steel cable, and bolting the cable to the piling, so that the bottom of the data logger was ~3 inches above the bottom of the PVC pipe. A weighted surveyor's tape was then used to measure the distance from the substrate to the pressure sensor on the MicroCAT for calculation of total water column depth from pressure readings. The mooring was inspected every 1-3 weeks, and any visible fouling of the enclosure or MicroCAT was removed with a brush or scaper. Method 2: Retrieval and Calibration -- At the end of each measurement period (approximately 2 months), the MicroCAT was unshackled from the cable and returned to the laboratory. The stored data was uploaded to a computer using a RS-232 serial cable and Sea-Bird Electronics SEATERM software. The MicroCAT was then cleaned to remove encrusting material and calibrated with a reference instrument at 4 to 5 salinity levels, generally ranging from 30 to 5 PSU. Method 3: Data Processing -- Data were processed after each retrieval using custom programs in the GCE Data Toolbox for MATLAB (parse_37sm and imp_gcesonde). Depth was calculated from recorded pressure and latitude values, and salinity and sigma-t were calculated from recorded conductivity and temperature values using standard UNESCO algorithms (reference: Unesco. 1983. Algorithms for computation of fundamental properties of seawater, 1983. Unesco Technical Papers in Marine Science No. 44, 53 pp.). Data were then plotted and visually inspected for evidence of biofouling of the conductivity sensor (i.e. prolonged periods of damped tidal oscillation in conductivity signal with no corresponding changes in temperature signal and no wind or rainfall events recorded at nearby monitoring stations, or periods of damped oscillation immediately followed by normal oscillation after instrument maintenance or replacement). Conductivity values recorded during periods of suspected biofouling were flagged as I (invalid) if visible fouling was noted in maintenance logs, and Q (questionable) if no visible fouling was noted. Method 4: Daily Aggregation -- The finalized 30-minute resolution data set was filtered to remove any remaining invalid values (i.e. assigned qualifier flags of 'I' = invalid value or 'X' = excise row), then padded with empty rows to produce a monotonic time series data set with even time steps. The data records were then aggregated (grouped) by Year, Month, Day, Site, Longitude and Latitude, and relevant summary statistics were calculated for each measured variable in each group and added as data columns. Quality control rules were defined for each calculated column to flag statistics based on days with more than 35% missing values as invalid, and more than 10% missing values or 35% flagged values as questionable. Columns listing the number and percentage of missing and flagged values in the original data set for each day were also added as data columns for reference by quality control rules. Following aggregation, summary statistics flagged as invalid were removed from the daily-aggregated data set and converted to missing (NaN). b. Protocols: Method 1: none Method 2: none Method 3: none Method 4: none c. Instrumentation: Method 1: Moored CTD datalogger (Sea-Bird Electronics Inc., model MicroCAT 37-SM S/N 1791, last factory calibration 11-Aug-2011); Moored CTD datalogger (Sea-Bird Electronics Inc., model MicroCAT 37-SM S/N 1790, last factory calibration 22-May-2012); Moored CTD datalogger (Sea-Bird Electronics Inc., model MicroCAT 37-SM S/N 13117, last factory calibration 23-Jan-2015); Moored CTD datalogger (Sea-Bird Electronics Inc., model MicroCAT 37-SM S/N 3746, last factory calibration 19-Jan-2020); Moored CTD datalogger (Sea-Bird Electronics Inc., model MicroCAT 37-SM S/N 3342, last factory calibration 11-Aug-2020) SBE MicroCAT 37-SM (S/N 3342) Manufacturer: Sea-Bird Electronics (Model: 37-SM MicroCAT) Last Calibration: Aug 11, 2020 Parameter: Conductivity (Accuracy: 0.0003 S/m, Readability: 0.00001 S/m, Range: 0 to 7 S/m) Protocol: Prior to each timed measurement the conductivity cell is opened and water is pumped for 0.5 sec, then conductivity is measured using an ultra-precision Wien-Bridge oscillator with frequency counted by a high-stability reference crystal (<2 ppm/year drift rate). The cell is closed between measurements and tributyl tin antifoulant is released into the tubing. Parameter: Pressure (water) (Accuracy: 0.2m, Readability: 0.0004m, Range: 0 to 20m) Protocol: Pressure is measured using a micro-machined silicon diaphragm with embedded strain elements, and temperature compensation is performed by the SBE MicroCAT onboard cpu. Parameter: Temperature (water) (Accuracy: 0.002°C, Readability: 0.0001°C, Range: -5 to 35°C) Protocol: Temperature is measured by applying an AC excitation to a hermetically-sealed VISHAY reference resistor and an ultra-stable aged thermistor (drift rate typically less than 0.002°C/year). SBE MicroCAT 37-SM (S/N 13117) Manufacturer: Sea-Bird Electronics (Model: 37-SM MicroCAT) Last Calibration: Jan 23, 2015 Parameter: Conductivity (Accuracy: 0.0003 S/m, Readability: 0.00001 S/m, Range: 0 to 7 S/m) Protocol: Water passively circulates through an open internal-field conductivity cell equipped with an external tributyl tin antifoulant dispenser, and conductivity is measured using an ultra-precision Wien-Bridge oscillator with frequency counted by a high-stability reference crystal (<2 ppm/year drift rate). Parameter: Pressure (water) (Accuracy: 0.2m, Readability: 0.0004m, Range: 0 to 20m) Protocol: Pressure is measured using a micro-machined silicon diaphragm with embedded strain elements, and temperature compensation is performed by the SBE MicroCAT onboard cpu. Parameter: Temperature (water) (Accuracy: 0.002°C, Readability: 0.0001°C, Range: -5 to 35°C) Protocol: Temperature is measured by applying an AC excitation to a hermetically-sealed VISHAY reference resistor and an ultra-stable aged thermistor (drift rate typically less than 0.002°C/year). SBE MicroCAT 37-SM (S/N 1790) Manufacturer: Sea-Bird Electronics (Model: 37-SM MicroCAT) Last Calibration: May 22, 2012 Parameter: Conductivity (Accuracy: 0.0003 S/m, Readability: 0.00001 S/m, Range: 0 to 7 S/m) Protocol: Water passively circulates through an open internal-field conductivity cell equipped with an external tributyl tin antifoulant dispenser, and conductivity is measured using an ultra-precision Wien-Bridge oscillator with frequency counted by a high-stability reference crystal (<2 ppm/year drift rate). Parameter: Pressure (water) (Accuracy: 0.2m, Readability: 0.0004m, Range: 0 to 20m) Protocol: Pressure is measured using a micro-machined silicon diaphragm with embedded strain elements, and temperature compensation is performed by the SBE MicroCAT onboard cpu. Parameter: Temperature (water) (Accuracy: 0.002°C, Readability: 0.0001°C, Range: -5 to 35°C) Protocol: Temperature is measured by applying an AC excitation to a hermetically-sealed VISHAY reference resistor and an ultra-stable aged thermistor (drift rate typically less than 0.002°C/year). SBE MicroCAT 37-SM (S/N 1791) Manufacturer: Sea-Bird Electronics (Model: 37-SM MicroCAT) Last Calibration: Aug 01, 2020 Parameter: Conductivity (Accuracy: 0.0003 S/m, Readability: 0.00001 S/m, Range: 0 to 7 S/m) Protocol: Water passively circulates through an open internal-field conductivity cell equipped with an external tributyl tin antifoulant dispenser, and conductivity is measured using an ultra-precision Wien-Bridge oscillator with frequency counted by a high-stability reference crystal (<2 ppm/year drift rate). Parameter: Pressure (water) (Accuracy: 0.2m, Readability: 0.0004m, Range: 0 to 20m) Protocol: Pressure is measured using a micro-machined silicon diaphragm with embedded strain elements, and temperature compensation is performed by the SBE MicroCAT onboard cpu. Parameter: Temperature (water) (Accuracy: 0.002°C, Readability: 0.0001°C, Range: -5 to 35°C) Protocol: Temperature is measured by applying an AC excitation to a hermetically-sealed VISHAY reference resistor and an ultra-stable aged thermistor (drift rate typically less than 0.002°C/year). SBE MicroCAT 37-SM (S/N 3746) Manufacturer: Sea-Bird Electronics (Model: 37-SM MicroCAT) Last Calibration: Jan 19, 2020 Parameter: Conductivity (Accuracy: 0.0003 S/m, Readability: 0.00001 S/m, Range: 0 to 7 S/m) Protocol: Prior to each timed measurement the conductivity cell is opened and water is pumped for 0.5 sec, then conductivity is measured using an ultra-precision Wien-Bridge oscillator with frequency counted by a high-stability reference crystal (<2 ppm/year drift rate). The cell is closed between measurements and tributyl tin antifoulant is released into the tubing. Parameter: Pressure (water) (Accuracy: 0.2m, Readability: 0.0004m, Range: 0 to 20m) Protocol: Pressure is measured using a micro-machined silicon diaphragm with embedded strain elements, and temperature compensation is performed by the SBE MicroCAT onboard cpu. Parameter: Temperature (water) (Accuracy: 0.002°C, Readability: 0.0001°C, Range: -5 to 35°C) Protocol: Temperature is measured by applying an AC excitation to a hermetically-sealed VISHAY reference resistor and an ultra-stable aged thermistor (drift rate typically less than 0.002°C/year). Method 2: none Method 3: none Method 4: none d. Taxonomy and Systematics: Method 1: Method 2: Method 3: Method 4: e. Speclies List: f. Permit History: Method 1: none Method 2: none Method 3: none Method 4: none 4. Project Personnel a. Personnel: 1: Daniela Di Iorio 2: Wade M. Sheldon, Jr. 3: Adam Sapp 4: Jacob Shalack 5: Dontrece Smith 6: Elise Kathryn Diehl 7: John Thomas Williams b. Affiliations: 1: University of Georgia, Athens, Georgia 2: University of Georgia, Athens, Georgia 3: University of Georgia, Athens, Georgia 4: University of Georgia Marine Institute, Sapelo Island, Georgia 5: University of Georgia Marine Institute, Sapelo Island, Georgia 6: University of Georgia Marine Institute, Sapelo Island, GA 7: University of Georgia Marine Institute, Sapelo Island, GA III. Data Set Status and Accessibility A. Status 1. Latest Update: 06-Jun-2022 2. Latest Archive Date: 06-Jun-2022 3. Latest Metadata Update: 06-Jun-2022 4. Data Verification Status: new submission B. Accessibility 1. Storage Location and Medium: Stored at GCE-LTER Data Management Office Dept. of Marine Sciences Univ. of Georgia Athens, GA 30602-3636 USA on media: electronic data download (WWW) or compact disk 2. Contact Person: Name: Adam Sapp Address: Department of Marine Sciences University of Georgia Athens, Georgia 30602 Country: USA Email: asapp@uga.edu 3. Copyright Restrictions: not copyrighted 4. Restrictions: This information is licensed under a Creative Commons Attribution 4.0 International License (see: https://creativecommons.org/licenses/by/4.0/). The consumer of these data ("Data User" herein) has an ethical obligation to cite it appropriately in any publication that results from its use. The Data User should realize that these data may be actively used by others for ongoing research and that coordination may be necessary to prevent duplicate publication. The Data User is urged to contact the authors of these data if any questions about methodology or results occur. Where appropriate, the Data User is encouraged to consider collaboration or co-authorship with the authors. The Data User should realize that misinterpretation of data may occur if used out of context of the original study. While substantial efforts are made to ensure the accuracy of data and associated documentation, complete accuracy of data sets cannot be guaranteed. All data are made available "as is." The Data User should be aware, however, that data are updated periodically and it is the responsibility of the Data User to check for new versions of the data. The data authors and the repository where these data were obtained shall not be liable for damages resulting from any use or misinterpretation of the data. a. Release Date: Affiliates: May 18, 2022, Public: May 18, 2022 b. Citation: Data provided by the Georgia Coastal Ecosystems Long Term Ecological Research Project, supported by funds from NSF OCE 1832178 (data set PHY-GCEM-2111e) c. Disclaimer: The user assumes all responsibility for errors in judgement based on interpretation of data and analyses presented in this data set. 5. Costs: free electronic data download via WWW, distribution on CD may be subject to nominal processing and handling fee IV. Data Structural Descriptors A. Data Set File 1. File Name: PHY-GCEM-2111e_Daily_1_0.CSV 2. Size: 366 records 3. File Format: ASCII text (comma-separated value format) 3a. Delimiters: single comma 4. Header Information: 5 lines of ASCII text 5. Alphanumeric Attributes: none 6. Quality Control Flag Codes: Q = questionable value, I = invalid value (out of range), S = spike/noise, X = excise row flag 7. Authentication Procedures: not specified 8. Calculations: Depth(m) = sw_dpth(Pressure(dbar),Latitude(deg)) -- sw_dpth (salt water depth from pressure) Matlab function, Revision: 1.3, Date: 10-Oct-1994 (C)1992 CSIRO, Phil Morgan (morgan@ml.csiro.au) [Salinity(psu),Sigma_t] = salsig2(Depth(m),Temperature(C),Conductivity(mmho/cm)) -- salsig2 (salinity and sigma-t from conductivity, temperature and depth) Matlab function Revision 06-May-1992 by V. Holliday, as modified by Tom Gross and Julie Amft (julie@skio.peachnet.edu) 9. Processing History: Software version: GCE Data Toolbox Version 3.9.9b (06-Mar-2019) Data structure version: GCE Data Structure 1.1 (29-Mar-2001) Original data files processed: 07200291.asc (6395 records) 07200590.asc (3982 records) 07200817.cnv (4705 records) 07201146.asc (3999 records) 07210242.asc (4657 records) Data processing history: 28-Feb-2020: data uploaded from SBE 37-SM MicroCAT using SEATERM software version 1.59 10-Apr-2020: new GCE Data Structure 1.1 created ('newstruct') 10-Apr-2020: data imported from processed SBE SM-37 sonde data file '07200291.asc' (6395 records) ('imp_gcesonde') 10-Apr-2020: deleted column Second from the structure ('deletecols') 10-Apr-2020: calculated calendar date in MATLAB serial day (base 1/1/0000) format from individual date component columns Year, Month, Day, Hour and Minute, added 'Date' column at position 1 ('add_datecol') 10-Apr-2020: added column 'Instrument' at position 1 ('addcol') 10-Apr-2020: added column 'Pump' at position 2 ('addcol') 10-Apr-2020: Q/C flagging criteria applied for column(s) Pump, 'flags' field updated ('dataflag') 10-Apr-2020: added column 'Latitude' at position 1 ('addcol') 10-Apr-2020: Q/C flagging criteria applied for column(s) Latitude, 'flags' field updated ('dataflag') 10-Apr-2020: added column 'Longitude' at position 1 ('addcol') 10-Apr-2020: Q/C flagging criteria applied for column(s) Longitude, 'flags' field updated ('dataflag') 10-Apr-2020: added column 'Site' at position 1 ('addcol') 10-Apr-2020: matched 6395 out of 6395 geographic coordinates in columns Latitude and Longitude to coordinates for registered locations in the file 'geo_locations.mat' within a distance tolerance of 0.5km (add_locations) 10-Apr-2020: added column 'Station' at position 2 ('addcol') 10-Apr-2020: Q/C flagging criteria applied for column(s) Station, 'flags' field updated ('dataflag') 10-Apr-2020: added geographic metadata based on matching values in column Station to location and station names registered in 'geo_locations.mat' ('add_sitemetadata') 10-Apr-2020: updated 8 metadata fields in the Site sections ('addmeta') 10-Apr-2020: added column 'Calibration' at position 19 ('addcol') 10-Apr-2020: Q/C flagging criteria applied for column(s) Calibration, 'flags' field updated ('dataflag') 10-Apr-2020: updated 13 metadata fields in the Data, Dataset, Status, Study, Supplement sections ('addmeta') 10-Apr-2020: Q/C flagging criteria applied, 'flags' field updated ('dataflag') 10-Apr-2020: edited structure data ('ui_datagrid'): deleted record(s) 1, 2, 3, 4, 6391, 6392, 6393, 6394 and 6395 10-Apr-2020: Q/C flagging criteria applied, 'flags' field updated ('dataflag') 13-Apr-2020: query 'Year==2020' run, returned 2812 of 6386 data rows ('querydata') 13-Apr-2020: automatically assigned study date metadata descriptors based on the range of date values in date/time columns (add_studydates) 13-Apr-2020: manually edited data set metadata ('ui_editmetadata') 13-Apr-2020: edited data set title in structure and metadata ('ui_editor') 20-Sep-2020: 3950 rows added at the bottom of the data set from 'Data from Sea-Bird Electronics 37-SM MicroCAT sonde S/N 1790 deployed at GCE7_Hydro (Hammersmith Creek hydrographic datalogger deployment) from 28-Feb-2020 to 21-May-2020' ('datamerge') 20-Sep-2020: updated 18 metadata fields in the Data, Dataset, Project, Status, Study, Supplement sections ('addmeta') 20-Sep-2020: Q/C flagging criteria applied, 'flags' field updated ('dataflag') 20-Sep-2020: automatically assigned study date metadata descriptors based on the range of date values in date/time columns (add_studydates) 20-Sep-2020: 4691 rows added at the bottom of the data set from 'Data from Sea-Bird Electronics 37-SM MicroCAT sonde S/N 13117 deployed at GCE7_Hydro (Hammersmith Creek hydrographic datalogger deployment) from 20-May-2020 to 26-Aug-2020' ('datamerge') 20-Sep-2020: updated 18 metadata fields in the Data, Dataset, Project, Status, Study, Supplement sections ('addmeta') 20-Sep-2020: Q/C flagging criteria applied, 'flags' field updated ('dataflag') 20-Sep-2020: manually edited data set metadata ('ui_editmetadata') 20-Sep-2020: edited data set title in structure and metadata ('ui_editor') 04-Dec-2020: 3997 rows added at the bottom of the data set from 'Data from Sea-Bird Electronics 37-SM MicroCAT sonde S/N 3746 deployed at GCE7_Hydro (Hammersmith Creek hydrographic datalogger deployment) from 26-Aug-2020 to 17-Nov-2020' ('datamerge') 04-Dec-2020: updated 18 metadata fields in the Data, Dataset, Project, Status, Study, Supplement sections ('addmeta') 04-Dec-2020: Q/C flagging criteria applied, 'flags' field updated ('dataflag') 04-Dec-2020: manually edited data set metadata ('ui_editmetadata') 04-Dec-2020: edited data set title in structure and metadata ('ui_editor') 01-Mar-2021: 4647 rows added at the bottom of the data set from 'Data from Sea-Bird Electronics 37-SM MicroCAT sonde S/N 3342 deployed at GCE7_Hydro (Hammersmith Creek hydrographic datalogger deployment) from 17-Nov-2020 to 22-Feb-2021' ('datamerge') 01-Mar-2021: updated 18 metadata fields in the Data, Dataset, Project, Status, Study, Supplement sections ('addmeta') 01-Mar-2021: Q/C flagging criteria applied, 'flags' field updated ('dataflag') 01-Mar-2021: query 'Year==2020' run, returned 17568 of 20097 data rows ('querydata') 01-Mar-2021: automatically assigned study date metadata descriptors based on the range of date values in date/time columns (add_studydates) 01-Mar-2021: manually edited data set metadata ('ui_editmetadata') 01-Mar-2021: edited data set title in structure and metadata ('ui_editor') 01-Mar-2021: manually edited data set metadata ('ui_editmetadata') 01-Mar-2021: edited data set title in structure and metadata ('ui_editor') 17-May-2022: query 'Year=2020' run, returned 17568 of 17568 data rows ('querydata') 17-May-2022: imported all documentation metadata from the template 'GCE_Sonde', retaining existing attribute descriptors for all columns ('meta_template') 17-May-2022: updated 41 metadata fields in the Data, Dataset, Project, Site, Status, Study, Supplement sections ('addmeta') 17-May-2022: updated title ('newtitle') 17-May-2022: added geographic metadata based on matching values in column Station to location and station names registered in 'geo_locations.mat' ('add_sitemetadata') 17-May-2022: updated 8 metadata fields in the Site sections ('addmeta') 17-May-2022: updated title ('newtitle') 17-May-2022: updated 1 metadata fields in the Dataset sections ('addmeta') 04-Jun-2022: query 'Year=2020' run, returned 17568 of 17568 data rows ('querydata') 04-Jun-2022: imported all documentation metadata from the template 'GCE_Sonde', retaining existing attribute descriptors for all columns ('meta_template') 04-Jun-2022: updated 41 metadata fields in the Data, Dataset, Project, Site, Status, Study, Supplement sections ('addmeta') 04-Jun-2022: updated title ('newtitle') 04-Jun-2022: added geographic metadata based on matching values in column Station to location and station names registered in 'geo_locations.mat' ('add_sitemetadata') 04-Jun-2022: updated 8 metadata fields in the Site sections ('addmeta') 04-Jun-2022: updated title ('newtitle') 04-Jun-2022: updated 1 metadata fields in the Dataset sections ('addmeta') 04-Jun-2022: performed daily statistical aggregation on data columns Temperature, Conductivity, Pressure, Depth, Salinity and Sigma_t by grouping on columns Site, Station, Longitude, Latitude, Year, Month and Day (aggr_datetime) 04-Jun-2022: updated title ('newtitle') 04-Jun-2022: updated 1 metadata fields in the Dataset sections ('addmeta') 04-Jun-2022: calculated calendar date in MATLAB serial day (base 1/1/0000) format from individual date component columns Year, Month and Day, added 'Date' column at position 5 ('add_datecol') 04-Jun-2022: sorted by column Date(ascending) ('sortdata') 04-Jun-2022: updated 1 metadata fields in the Study sections ('addmeta') 06-Jun-2022: updated 1 metadata fields in the Dataset sections ('addmeta') 06-Jun-2022: imported Dataset, Project, Site, Study, Status, Supplement metadata descriptors from the GCE Metabase ('imp_gcemetadata') 06-Jun-2022: updated 57 metadata fields in the Dataset, Project, Site, Status, Study, Supplement sections ('addmeta') 06-Jun-2022: converted dates in column(s) Date to format yyyy-mm-dd HH:MM:SS 06-Jun-2022: updated 6 metadata fields in the Data sections ('addmeta') 06-Jun-2022: updated 15 metadata fields in the Status, Data sections to reflect attribute metadata ('updatecols') 06-Jun-2022: parsed and formatted metadata ('listmeta') B. Variable Information 1. Variable Name: column 1. Site column 2. Station column 3. Longitude column 4. Latitude column 5. Date column 6. Year column 7. Month column 8. Day column 9. Missing_Temperature column 10. Percent_Missing_Temperature column 11. Flagged_Temperature column 12. Percent_Flagged_Temperature column 13. Daily_Num_Temperature column 14. Daily_Min_Temperature column 15. Daily_Max_Temperature column 16. Daily_Mean_Temperature column 17. Daily_StdDev_Temperature column 18. Daily_SE_Temperature column 19. Missing_Conductivity column 20. Percent_Missing_Conductivity column 21. Flagged_Conductivity column 22. Percent_Flagged_Conductivity column 23. Daily_Num_Conductivity column 24. Daily_Min_Conductivity column 25. Daily_Max_Conductivity column 26. Daily_Mean_Conductivity column 27. Daily_StdDev_Conductivity column 28. Daily_SE_Conductivity column 29. Missing_Pressure column 30. Percent_Missing_Pressure column 31. Flagged_Pressure column 32. Percent_Flagged_Pressure column 33. Daily_Num_Pressure column 34. Daily_Min_Pressure column 35. Daily_Max_Pressure column 36. Daily_Mean_Pressure column 37. Daily_StdDev_Pressure column 38. Daily_SE_Pressure column 39. Missing_Depth column 40. Percent_Missing_Depth column 41. Flagged_Depth column 42. Percent_Flagged_Depth column 43. Daily_Num_Depth column 44. Daily_Min_Depth column 45. Daily_Max_Depth column 46. Daily_Mean_Depth column 47. Daily_StdDev_Depth column 48. Daily_SE_Depth column 49. Missing_Salinity column 50. Percent_Missing_Salinity column 51. Flagged_Salinity column 52. Percent_Flagged_Salinity column 53. Daily_Num_Salinity column 54. Daily_Min_Salinity column 55. Daily_Max_Salinity column 56. Daily_Mean_Salinity column 57. Daily_StdDev_Salinity column 58. Daily_SE_Salinity column 59. Missing_Sigma_t column 60. Percent_Missing_Sigma_t column 61. Flagged_Sigma_t column 62. Percent_Flagged_Sigma_t column 63. Daily_Num_Sigma_t column 64. Daily_Min_Sigma_t column 65. Daily_Max_Sigma_t column 66. Daily_Mean_Sigma_t column 67. Daily_StdDev_Sigma_t column 68. Daily_SE_Sigma_t 2. Variable Definition: column 1. Nearest nominal GCE-LTER sampling site column 2. Station determined by geographic database lookup of coordinates in columns Latitude and Longitude using a distance tolerance of 0.5km from registered station location column 3. Geographic longitude in decimal degrees column 4. Geographic latitude in decimal degrees column 5. Fractional MATLAB serial day (based on 1 = January 1, 0000) column 6. Calendar year column 7. Calendar month column 8. Calendar day column 9. Number of missing observations of Water temperature column 10. Percent missing observations of Water temperature column 11. Number of QC/QA-flagged observations of Water temperature column 12. Percent QC/QA-flagged observations of Water temperature column 13. Daily Observations of Water temperature column 14. Daily Minimum Water temperature column 15. Daily Maximum Water temperature column 16. Daily Mean Water temperature column 17. Daily Sample Standard Deviation of Water temperature column 18. Daily Standard Error of Water temperature column 19. Number of missing observations of Conductivity column 20. Percent missing observations of Conductivity column 21. Number of QC/QA-flagged observations of Conductivity column 22. Percent QC/QA-flagged observations of Conductivity column 23. Daily Observations of Conductivity column 24. Daily Minimum Conductivity column 25. Daily Maximum Conductivity column 26. Daily Mean Conductivity column 27. Daily Sample Standard Deviation of Conductivity column 28. Daily Standard Error of Conductivity column 29. Number of missing observations of Water pressure at sensor (approximately equivalent to water depth within 3% error) column 30. Percent missing observations of Water pressure at sensor (approximately equivalent to water depth within 3% error) column 31. Number of QC/QA-flagged observations of Water pressure at sensor (approximately equivalent to water depth within 3% error) column 32. Percent QC/QA-flagged observations of Water pressure at sensor (approximately equivalent to water depth within 3% error) column 33. Daily Observations of Water pressure at sensor (approximately equivalent to water depth within 3% error) column 34. Daily Minimum Water pressure at sensor (approximately equivalent to water depth within 3% error) column 35. Daily Maximum Water pressure at sensor (approximately equivalent to water depth within 3% error) column 36. Daily Mean Water pressure at sensor (approximately equivalent to water depth within 3% error) column 37. Daily Sample Standard Deviation of Water pressure at sensor (approximately equivalent to water depth within 3% error) column 38. Daily Standard Error of Water pressure at sensor (approximately equivalent to water depth within 3% error) column 39. Number of missing observations of Water depth to the pressure sensor of the moored sonde column 40. Percent missing observations of Water depth to the pressure sensor of the moored sonde column 41. Number of QC/QA-flagged observations of Water depth to the pressure sensor of the moored sonde column 42. Percent QC/QA-flagged observations of Water depth to the pressure sensor of the moored sonde column 43. Daily Observations of Water depth to the pressure sensor of the moored sonde column 44. Daily Minimum Water depth to the pressure sensor of the moored sonde column 45. Daily Maximum Water depth to the pressure sensor of the moored sonde column 46. Daily Mean Water depth to the pressure sensor of the moored sonde column 47. Daily Sample Standard Deviation of Water depth to the pressure sensor of the moored sonde column 48. Daily Standard Error of Water depth to the pressure sensor of the moored sonde column 49. Number of missing observations of Salinity column 50. Percent missing observations of Salinity column 51. Number of QC/QA-flagged observations of Salinity column 52. Percent QC/QA-flagged observations of Salinity column 53. Daily Observations of Salinity column 54. Daily Minimum Salinity column 55. Daily Maximum Salinity column 56. Daily Mean Salinity column 57. Daily Sample Standard Deviation of Salinity column 58. Daily Standard Error of Salinity column 59. Number of missing observations of Sigma-t (i.e. Density-1) column 60. Percent missing observations of Sigma-t (i.e. Density-1) column 61. Number of QC/QA-flagged observations of Sigma-t (i.e. Density-1) column 62. Percent QC/QA-flagged observations of Sigma-t (i.e. Density-1) column 63. Daily Observations of Sigma-t (i.e. Density-1) column 64. Daily Minimum Sigma-t (i.e. Density-1) column 65. Daily Maximum Sigma-t (i.e. Density-1) column 66. Daily Mean Sigma-t (i.e. Density-1) column 67. Daily Sample Standard Deviation of Sigma-t (i.e. Density-1) column 68. Daily Standard Error of Sigma-t (i.e. Density-1) 3. Units of Measurement: column 1. none column 2. none column 3. degrees column 4. degrees column 5. yyyy-mm-dd HH:MM:SS column 6. YYYY column 7. MM column 8. DD column 9. count column 10. % column 11. count column 12. % column 13. count column 14. °C column 15. °C column 16. °C column 17. °C column 18. °C column 19. count column 20. % column 21. count column 22. % column 23. count column 24. S/m column 25. S/m column 26. S/m column 27. S/m column 28. S/m column 29. count column 30. % column 31. count column 32. % column 33. count column 34. dbar column 35. dbar column 36. dbar column 37. dbar column 38. dbar column 39. count column 40. % column 41. count column 42. % column 43. count column 44. m column 45. m column 46. m column 47. m column 48. m column 49. count column 50. % column 51. count column 52. % column 53. count column 54. PSU column 55. PSU column 56. PSU column 57. PSU column 58. PSU column 59. count column 60. % column 61. count column 62. % column 63. count column 64. kg/m^3 column 65. kg/m^3 column 66. kg/m^3 column 67. kg/m^3 column 68. kg/m^3 4. Data Type a. Storage Type: column 1. integer column 2. string column 3. floating-point column 4. floating-point column 5. string column 6. integer column 7. integer column 8. integer column 9. integer column 10. floating-point column 11. integer column 12. floating-point column 13. integer column 14. floating-point column 15. floating-point column 16. floating-point column 17. floating-point column 18. floating-point column 19. integer column 20. floating-point column 21. integer column 22. floating-point column 23. integer column 24. floating-point column 25. floating-point column 26. floating-point column 27. floating-point column 28. floating-point column 29. integer column 30. floating-point column 31. integer column 32. floating-point column 33. integer column 34. floating-point column 35. floating-point column 36. floating-point column 37. floating-point column 38. floating-point column 39. integer column 40. floating-point column 41. integer column 42. floating-point column 43. integer column 44. floating-point column 45. floating-point column 46. floating-point column 47. floating-point column 48. floating-point column 49. integer column 50. floating-point column 51. integer column 52. floating-point column 53. integer column 54. floating-point column 55. floating-point column 56. floating-point column 57. floating-point column 58. floating-point column 59. integer column 60. floating-point column 61. integer column 62. floating-point column 63. integer column 64. floating-point column 65. floating-point column 66. floating-point column 67. floating-point column 68. floating-point b. Variable Codes: c. Numeric Range: column 1. 7 to 7 column 2. (none) column 3. -81.4755 to -81.4755 column 4. 31.3382 to 31.3382 column 5. (none) column 6. 2020 to 2020 column 7. 1 to 12 column 8. 1 to 31 column 9. 0 to 0 column 10. 0 to 0 column 11. 0 to 0 column 12. 0 to 0 column 13. 48 to 48 column 14. 9.0811 to 30.8912 column 15. 9.5289 to 32.0629 column 16. 9.3132 to 31.255 column 17. 0.074418 to 0.81097 column 18. 0.010741 to 0.11705 column 19. 0 to 0 column 20. 0 to 0 column 21. 0 to 0 column 22. 0 to 0 column 23. 48 to 48 column 24. 0.00356 to 0.028835 column 25. 0.00384 to 0.45097 column 26. 0.0036756 to 0.1018 column 27. 2.3335e-05 to 0.12339 column 28. 3.3681e-06 to 0.01781 column 29. 0 to 0 column 30. 0 to 0 column 31. 0 to 0 column 32. 0 to 0 column 33. 48 to 48 column 34. 0.763 to 2.889 column 35. 2.505 to 3.809 column 36. 1.6478 to 3.3454 column 37. 0.18145 to 0.69462 column 38. 0.02619 to 0.10026 column 39. 0 to 0 column 40. 0 to 0 column 41. 0 to 0 column 42. 0 to 0 column 43. 48 to 48 column 44. 0.75772 to 2.869 column 45. 2.4877 to 3.7826 column 46. 1.6364 to 3.3223 column 47. 0.18019 to 0.68981 column 48. 0.026008 to 0.099566 column 49. 0 to 0 column 50. 0 to 0 column 51. 0 to 0 column 52. 0 to 0 column 53. 48 to 48 column 54. 0.02486 to 0.12508 column 55. 0.026314 to 2.4882 column 56. 0.025494 to 0.5382 column 57. 0.00013277 to 0.67308 column 58. 1.9164e-05 to 0.09715 column 59. 0 to 0 column 60. 0 to 0 column 61. 0 to 0 column 62. 0 to 0 column 63. 48 to 48 column 64. -4.9114 to -0.20668 column 65. -4.5677 to -0.17171 column 66. -4.6804 to -0.18964 column 67. 0.0093766 to 0.488 column 68. 0.0013534 to 0.070437 d. Missing Value Code: 5. Data Format a. Column Type: column 1. numerical column 2. text column 3. numerical column 4. numerical column 5. text column 6. numerical column 7. numerical column 8. numerical column 9. numerical column 10. numerical column 11. numerical column 12. numerical column 13. numerical column 14. numerical column 15. numerical column 16. numerical column 17. numerical column 18. numerical column 19. numerical column 20. numerical column 21. numerical column 22. numerical column 23. numerical column 24. numerical column 25. numerical column 26. numerical column 27. numerical column 28. numerical column 29. numerical column 30. numerical column 31. numerical column 32. numerical column 33. numerical column 34. numerical column 35. numerical column 36. numerical column 37. numerical column 38. numerical column 39. numerical column 40. numerical column 41. numerical column 42. numerical column 43. numerical column 44. numerical column 45. numerical column 46. numerical column 47. numerical column 48. numerical column 49. numerical column 50. numerical column 51. numerical column 52. numerical column 53. numerical column 54. numerical column 55. numerical column 56. numerical column 57. numerical column 58. numerical column 59. numerical column 60. numerical column 61. numerical column 62. numerical column 63. numerical column 64. numerical column 65. numerical column 66. numerical column 67. numerical column 68. numerical b. Number of Columns: 68 c. Decimal Places: column 1. 0 column 2. 0 column 3. 6 column 4. 6 column 5. 0 column 6. 0 column 7. 0 column 8. 0 column 9. 0 column 10. 2 column 11. 0 column 12. 2 column 13. 0 column 14. 3 column 15. 3 column 16. 4 column 17. 4 column 18. 5 column 19. 0 column 20. 2 column 21. 0 column 22. 2 column 23. 0 column 24. 3 column 25. 3 column 26. 4 column 27. 4 column 28. 5 column 29. 0 column 30. 2 column 31. 0 column 32. 2 column 33. 0 column 34. 3 column 35. 3 column 36. 4 column 37. 4 column 38. 5 column 39. 0 column 40. 2 column 41. 0 column 42. 2 column 43. 0 column 44. 3 column 45. 3 column 46. 4 column 47. 4 column 48. 5 column 49. 0 column 50. 2 column 51. 0 column 52. 2 column 53. 0 column 54. 3 column 55. 3 column 56. 4 column 57. 4 column 58. 5 column 59. 0 column 60. 2 column 61. 0 column 62. 2 column 63. 0 column 64. 3 column 65. 3 column 66. 4 column 67. 4 column 68. 5 6. Logical Variable Type: column 1. nominal (discrete) column 2. nominal (none) column 3. geographic coordinate (continuous) column 4. geographic coordinate (continuous) column 5. datetime (none) column 6. datetime (discrete) column 7. datetime (discrete) column 8. datetime (discrete) column 9. calculation (discrete) column 10. calculation (continuous) column 11. calculation (discrete) column 12. calculation (continuous) column 13. calculation (discrete) column 14. calculation (continuous) column 15. calculation (continuous) column 16. calculation (continuous) column 17. calculation (continuous) column 18. calculation (continuous) column 19. calculation (discrete) column 20. calculation (continuous) column 21. calculation (discrete) column 22. calculation (continuous) column 23. calculation (discrete) column 24. calculation (continuous) column 25. calculation (continuous) column 26. calculation (continuous) column 27. calculation (continuous) column 28. calculation (continuous) column 29. calculation (discrete) column 30. calculation (continuous) column 31. calculation (discrete) column 32. calculation (continuous) column 33. calculation (discrete) column 34. calculation (continuous) column 35. calculation (continuous) column 36. calculation (continuous) column 37. calculation (continuous) column 38. calculation (continuous) column 39. calculation (discrete) column 40. calculation (continuous) column 41. calculation (discrete) column 42. calculation (continuous) column 43. calculation (discrete) column 44. calculation (continuous) column 45. calculation (continuous) column 46. calculation (continuous) column 47. calculation (continuous) column 48. calculation (continuous) column 49. calculation (discrete) column 50. calculation (continuous) column 51. calculation (discrete) column 52. calculation (continuous) column 53. calculation (discrete) column 54. calculation (continuous) column 55. calculation (continuous) column 56. calculation (continuous) column 57. calculation (continuous) column 58. calculation (continuous) column 59. calculation (discrete) column 60. calculation (continuous) column 61. calculation (discrete) column 62. calculation (continuous) column 63. calculation (discrete) column 64. calculation (continuous) column 65. calculation (continuous) column 66. calculation (continuous) column 67. calculation (continuous) column 68. calculation (continuous) 7. Flagging Criteria: column 1. none column 2. none column 3. none column 4. none column 5. none column 6. none column 7. none column 8. none column 9. none column 10. none column 11. none column 12. none column 13. none column 14. col_Percent_Missing_Temperature>35="I";col_Percent_Missing_Temperature>15="Q";col_Percen t_Flagged_Temperature>35="Q" column 15. col_Percent_Missing_Temperature>35="I";col_Percent_Missing_Temperature>15="Q";col_Percen t_Flagged_Temperature>35="Q" column 16. col_Percent_Missing_Temperature>35="I";col_Percent_Missing_Temperature>15="Q";col_Percen t_Flagged_Temperature>35="Q" column 17. col_Percent_Missing_Temperature>35="I";col_Percent_Missing_Temperature>15="Q";col_Percen t_Flagged_Temperature>35="Q" column 18. col_Percent_Missing_Temperature>35="I";col_Percent_Missing_Temperature>15="Q";col_Percen t_Flagged_Temperature>35="Q" column 19. none column 20. none column 21. none column 22. none column 23. none column 24. col_Percent_Missing_Conductivity>35="I";col_Percent_Missing_Conductivity>15="Q";col_Perc ent_Flagged_Conductivity>35="Q" column 25. col_Percent_Missing_Conductivity>35="I";col_Percent_Missing_Conductivity>15="Q";col_Perc ent_Flagged_Conductivity>35="Q" column 26. col_Percent_Missing_Conductivity>35="I";col_Percent_Missing_Conductivity>15="Q";col_Perc ent_Flagged_Conductivity>35="Q" column 27. col_Percent_Missing_Conductivity>35="I";col_Percent_Missing_Conductivity>15="Q";col_Perc ent_Flagged_Conductivity>35="Q" column 28. col_Percent_Missing_Conductivity>35="I";col_Percent_Missing_Conductivity>15="Q";col_Perc ent_Flagged_Conductivity>35="Q" column 29. none column 30. none column 31. none column 32. none column 33. none column 34. col_Percent_Missing_Pressure>35="I";col_Percent_Missing_Pressure>15="Q";col_Percent_Flag ged_Pressure>35="Q" column 35. col_Percent_Missing_Pressure>35="I";col_Percent_Missing_Pressure>15="Q";col_Percent_Flag ged_Pressure>35="Q" column 36. col_Percent_Missing_Pressure>35="I";col_Percent_Missing_Pressure>15="Q";col_Percent_Flag ged_Pressure>35="Q" column 37. col_Percent_Missing_Pressure>35="I";col_Percent_Missing_Pressure>15="Q";col_Percent_Flag ged_Pressure>35="Q" column 38. col_Percent_Missing_Pressure>35="I";col_Percent_Missing_Pressure>15="Q";col_Percent_Flag ged_Pressure>35="Q" column 39. none column 40. none column 41. none column 42. none column 43. none column 44. col_Percent_Missing_Depth>35="I";col_Percent_Missing_Depth>15="Q";col_Percent_Flagged_De pth>35="Q" column 45. col_Percent_Missing_Depth>35="I";col_Percent_Missing_Depth>15="Q";col_Percent_Flagged_De pth>35="Q" column 46. col_Percent_Missing_Depth>35="I";col_Percent_Missing_Depth>15="Q";col_Percent_Flagged_De pth>35="Q" column 47. col_Percent_Missing_Depth>35="I";col_Percent_Missing_Depth>15="Q";col_Percent_Flagged_De pth>35="Q" column 48. col_Percent_Missing_Depth>35="I";col_Percent_Missing_Depth>15="Q";col_Percent_Flagged_De pth>35="Q" column 49. none column 50. none column 51. none column 52. none column 53. none column 54. col_Percent_Missing_Salinity>35="I";col_Percent_Missing_Salinity>15="Q";col_Percent_Flag ged_Salinity>35="Q" column 55. col_Percent_Missing_Salinity>35="I";col_Percent_Missing_Salinity>15="Q";col_Percent_Flag ged_Salinity>35="Q" column 56. col_Percent_Missing_Salinity>35="I";col_Percent_Missing_Salinity>15="Q";col_Percent_Flag ged_Salinity>35="Q" column 57. col_Percent_Missing_Salinity>35="I";col_Percent_Missing_Salinity>15="Q";col_Percent_Flag ged_Salinity>35="Q" column 58. col_Percent_Missing_Salinity>35="I";col_Percent_Missing_Salinity>15="Q";col_Percent_Flag ged_Salinity>35="Q" column 59. none column 60. none column 61. none column 62. none column 63. none column 64. col_Percent_Missing_Sigma_t>35="I";col_Percent_Missing_Sigma_t>15="Q";col_Percent_Flagge d_Sigma_t>35="Q" column 65. col_Percent_Missing_Sigma_t>35="I";col_Percent_Missing_Sigma_t>15="Q";col_Percent_Flagge d_Sigma_t>35="Q" column 66. col_Percent_Missing_Sigma_t>35="I";col_Percent_Missing_Sigma_t>15="Q";col_Percent_Flagge d_Sigma_t>35="Q" column 67. col_Percent_Missing_Sigma_t>35="I";col_Percent_Missing_Sigma_t>15="Q";col_Percent_Flagge d_Sigma_t>35="Q" column 68. col_Percent_Missing_Sigma_t>35="I";col_Percent_Missing_Sigma_t>15="Q";col_Percent_Flagge d_Sigma_t>35="Q" C. Data Anomalies: V. Supplemental Descriptors A. Data Acquisition 1. Data Forms: Copies of CTD cast logs and raw data are maintained at the Georgia Coastal Ecosystems Information Management Office 2. Form Location: GCE-LTER Information Management Office, Dept. of Marine Sciences, University of Georgia, Athens, GA 30602 3. Data Entry Validation: B. Quality Assurance/Quality Control Procedures: QA/QC flags are generated automatically according to domain criteria specified for each data column, then subsequently reviewed and revised as appropriate. Coded flag columns are generated for each data column, listing qualifier flags assigned to the data value on the corresponding row. C. Supplemental Materials: not applicable D. Computer Programs: Sea-Bird Electronics Sea-Soft version 4.246, MATLAB version 2013B E. Archival Practices: Data sets and documentation are stored in structured binary (Matlab 5.x files) and delimited ASCII text formats, and archived on magnetic tape and CD at the GCE LTER Information Management Office at the University of Georgia, Athens, Georgia, USA F. Publications: not specified G. History of Data Set Usage 1. Data Request History: not specified 2. Data Set Update History: none 3. Review History: none 4. Questions and Comments from Users: none