BCO-DMO ERDDAP
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Row Type | Variable Name | Attribute Name | Data Type | Value |
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attribute | NC_GLOBAL | access_formats | String | .htmlTable,.csv,.json,.mat,.nc,.tsv |
attribute | NC_GLOBAL | acquisition_description | String | Samples were collected from the Sage Lot Pond salt marsh tidal creek in\nWaquoit Bay, MA at approx. 41.5546N, 70.5071W.\n \nIn situ, high-frequency sensors for DIC and salinity were deployed at the\nmouth of the tidal creek in Sage Lot Pond at the latitude and longitude listed\nin the location above. DIC was measured with an autonomous sensor called\nCHANnelized Optical Sensor (CHANOS). An EXO2 Multiparameter Sonde (YSI Inc.,\nYellow Springs, OH) was submerged in the tidal creek to measure temperature\nand salinity. The YSI EXO2 recorded at intervals ranging from 2 min to 8 min.\nReported YSI EXO2 sensor accuracy specifications are: 1% of the reading for\nsalinity and 0.05 \\u00b0C for temperature. CHANOS was placed on a platform\natop the marsh adjacent to the creek with the inlet pumping from the creek at\nthe same depth and within 30 cm of the EXO2 Sonde. This setup avoided any\ninterference by CHANOS on water flow in the creek. There is no significant\nconcentration difference with depth in the creek (data not shown). In order to\nprevent fouling, sample water was filtered by a 100\\u03bcm plastic disc filter\n(Keller Products, Acton, MA) followed by a copper mesh filter. CHANOS was\npowered by two 12 V batteries that were charged with two 250W solar panels\n(Renogy, Ontario, CA).\n \nCHANOS uses spectrophotometric principles to measure DIC and pH using two\nindependent channels (Wang et al., 2015). Briefly, CHANOS consisted of syringe\npumps for delivery of reagents, junction boxes containing valves, thermistors,\nand optical and fluidic components for DIC and pH analysis, and an electronics\nhousing, as well as reagent bags for storage of CRM, hydrochloric acid,\nreference solution, and pH- sensitive indicator solution. For this study, only\n[DIC] measurements were used. The DIC channel uses an improved\nspectrophotometric method described in detail in Wang et al. (2013) whereby a\ncountercurrent flow configuration between acidified seawater and a pH-\nsensitive indicator solution in a tube-in-tube design achieves fast,\ncontinuous CO2 equilibration across highly CO2-permeable Teflon AF 2400\ntubing. After CO2 exchange in the countercurrent flow cell, the indicator\nsolution is directed into an optical cell for detection. Each measurement\ncycle is ~15min. The system achieved a precision of ~ \\u00b1 2.5 \\u03bcmol\nkg-1 and an accuracy of ~ \\u00b1 5.0 \\u03bcmol kg-1 during coastal deployments\n(Wang et al., 2015). |
attribute | NC_GLOBAL | awards_0_award_nid | String | 765031 |
attribute | NC_GLOBAL | awards_0_award_number | String | OCE-1459521 |
attribute | NC_GLOBAL | awards_0_data_url | String | http://www.nsf.gov/awardsearch/showAward.do?AwardNumber=1459521 |
attribute | NC_GLOBAL | awards_0_funder_name | String | NSF Division of Ocean Sciences |
attribute | NC_GLOBAL | awards_0_funding_acronym | String | NSF OCE |
attribute | NC_GLOBAL | awards_0_funding_source_nid | String | 355 |
attribute | NC_GLOBAL | awards_0_program_manager | String | Henrietta N Edmonds |
attribute | NC_GLOBAL | awards_0_program_manager_nid | String | 51517 |
attribute | NC_GLOBAL | cdm_data_type | String | Other |
attribute | NC_GLOBAL | comment | String | Salt marsh continuous DIC \n measured by CHANnelized Optical Sensor (CHANOS) \n PI: Zhaohui Aleck Wang (WHOI) \n Co-PIs: Kevin Kroeger & Meagan Gonneea (USGS) \n Version date: 23-May-2019 |
attribute | NC_GLOBAL | Conventions | String | COARDS, CF-1.6, ACDD-1.3 |
attribute | NC_GLOBAL | creator_email | String | info at bco-dmo.org |
attribute | NC_GLOBAL | creator_name | String | BCO-DMO |
attribute | NC_GLOBAL | creator_type | String | institution |
attribute | NC_GLOBAL | creator_url | String | https://www.bco-dmo.org/ |
attribute | NC_GLOBAL | data_source | String | extract_data_as_tsv version 2.3 19 Dec 2019 |
attribute | NC_GLOBAL | date_created | String | 2019-05-24T19:54:34Z |
attribute | NC_GLOBAL | date_modified | String | 2019-05-29T15:35:39Z |
attribute | NC_GLOBAL | defaultDataQuery | String | &time<now |
attribute | NC_GLOBAL | doi | String | 10.1575/1912/bco-dmo.768607.1 |
attribute | NC_GLOBAL | infoUrl | String | https://www.bco-dmo.org/dataset/768607 |
attribute | NC_GLOBAL | institution | String | BCO-DMO |
attribute | NC_GLOBAL | instruments_0_acronym | String | YSI EXO |
attribute | NC_GLOBAL | instruments_0_dataset_instrument_nid | String | 768617 |
attribute | NC_GLOBAL | instruments_0_description | String | Comprehensive multi-parameter, water-quality monitoring sondes designed for long-term monitoring, profiling and spot sampling. The EXO sondes are split into several categories: EXO1 Sonde, EXO2 Sonde, EXO3 Sonde. Each category has a slightly different design purpose with the the EXO2 and EXO3 containing more sensor ports than the EXO1. Data are collected using up to four user-replaceable sensors and an integral pressure transducer. Users communicate with the sonde via a field cable to an EXO Handheld, via Bluetooth wireless connection to a PC, or a USB connection to a PC. Typical parameter specifications for relevant sensors include dissolved oxygen with ranges of 0-50 mg/l, with a resolution of +/- 0.1 mg/l, an accuracy of 1 percent of reading for values between 0-20 mg/l and an accuracy of +/- 5 percent of reading for values 20-50 mg/l. Temp ranges are from-5 to +50 degC, with an accuracy of +/- 0.001 degC. Conductivity has a range of 0-200 mS/cm, with an accuracy of +/-0.5 percent of reading + 0.001 mS/cm and a resolution of 0.0001 - 0.01 mS/cm. |
attribute | NC_GLOBAL | instruments_0_instrument_name | String | YSI EXO multiparameter water quality sondes |
attribute | NC_GLOBAL | instruments_0_instrument_nid | String | 768595 |
attribute | NC_GLOBAL | instruments_0_supplied_name | String | EXO2 Multiparameter Sonde (YSI Inc., Yellow Springs, OH) |
attribute | NC_GLOBAL | instruments_1_acronym | String | CHANOS |
attribute | NC_GLOBAL | instruments_1_dataset_instrument_nid | String | 768619 |
attribute | NC_GLOBAL | instruments_1_description | String | CHANOS uses spectrophotometric principles to measure DIC and pH using two independent channels (Wang et al., 2015). Briefly, CHANOS consisted of syringe pumps for delivery of reagents, junction boxes containing valves, thermistors, and optical and fluidic components for DIC and pH analysis, and an electronics housing, as well as reagent bags for storage of CRM, hydrochloric acid, reference solution, and pH- sensitive indicator solution. \n\nRefer to Wang et al. (2015) doi: 10.1021/es504893n |
attribute | NC_GLOBAL | instruments_1_instrument_name | String | CHANnelized Optical Sensor |
attribute | NC_GLOBAL | instruments_1_instrument_nid | String | 768618 |
attribute | NC_GLOBAL | instruments_1_supplied_name | String | CHANnelized Optical Sensor |
attribute | NC_GLOBAL | keywords | String | bco, bco-dmo, biological, chanosdic, chemical, data, dataset, date, density, dmo, earth, Earth Science > Oceans > Salinity/Density > Salinity, erddap, iso, management, ocean, oceanography, oceans, office, practical, preliminary, salinity, science, sea, sea_water_practical_salinity, seawater, temperature, time, water |
attribute | NC_GLOBAL | keywords_vocabulary | String | GCMD Science Keywords |
attribute | NC_GLOBAL | license | String | https://www.bco-dmo.org/dataset/768607/license |
attribute | NC_GLOBAL | metadata_source | String | https://www.bco-dmo.org/api/dataset/768607 |
attribute | NC_GLOBAL | param_mapping | String | {'768607': {'ISO_DateTime_UTC': 'flag - time'}} |
attribute | NC_GLOBAL | parameter_source | String | https://www.bco-dmo.org/mapserver/dataset/768607/parameters |
attribute | NC_GLOBAL | people_0_affiliation | String | Woods Hole Oceanographic Institution |
attribute | NC_GLOBAL | people_0_affiliation_acronym | String | WHOI |
attribute | NC_GLOBAL | people_0_person_name | String | Zhaohui Aleck Wang |
attribute | NC_GLOBAL | people_0_person_nid | String | 51347 |
attribute | NC_GLOBAL | people_0_role | String | Principal Investigator |
attribute | NC_GLOBAL | people_0_role_type | String | originator |
attribute | NC_GLOBAL | people_1_affiliation | String | United States Geological Survey |
attribute | NC_GLOBAL | people_1_affiliation_acronym | String | USGS |
attribute | NC_GLOBAL | people_1_person_name | String | Meagan Gonneea |
attribute | NC_GLOBAL | people_1_person_nid | String | 768545 |
attribute | NC_GLOBAL | people_1_role | String | Co-Principal Investigator |
attribute | NC_GLOBAL | people_1_role_type | String | originator |
attribute | NC_GLOBAL | people_2_affiliation | String | United States Geological Survey |
attribute | NC_GLOBAL | people_2_affiliation_acronym | String | USGS |
attribute | NC_GLOBAL | people_2_person_name | String | Kevin Kroeger |
attribute | NC_GLOBAL | people_2_person_nid | String | 768544 |
attribute | NC_GLOBAL | people_2_role | String | Co-Principal Investigator |
attribute | NC_GLOBAL | people_2_role_type | String | originator |
attribute | NC_GLOBAL | people_3_affiliation | String | Woods Hole Oceanographic Institution |
attribute | NC_GLOBAL | people_3_affiliation_acronym | String | WHOI BCO-DMO |
attribute | NC_GLOBAL | people_3_person_name | String | Shannon Rauch |
attribute | NC_GLOBAL | people_3_person_nid | String | 51498 |
attribute | NC_GLOBAL | people_3_role | String | BCO-DMO Data Manager |
attribute | NC_GLOBAL | people_3_role_type | String | related |
attribute | NC_GLOBAL | project | String | Salt Marsh Paradox |
attribute | NC_GLOBAL | projects_0_acronym | String | Salt Marsh Paradox |
attribute | NC_GLOBAL | projects_0_description | String | NSF Award Abstract:\nCarbon production in vegetated coastal systems such as marshes is among the highest in the biosphere. Resolving carbon production from marshes and assessing their impacts on coastal carbon cycling are critical to determining the long-term impacts of global change such as ocean acidification and eutrophication. In this project, researchers will use new methods to improve the assessment of carbon production from salt marshes. The overarching goals are to understand the role of coastal wetlands in altering carbonate chemistry, alkalinity, and carbon budgets of the coastal ocean, as well as their capacity to buffer against anthropogenically driven chemical changes, such as ocean acidification. This project will involve training for undergraduate, graduate, and postdoctoral researchers, and will provide educational opportunities for students from a local Native American tribe.\n\nTidal water, after exchange with intertidal salt marshes, contains higher total alkalinity (TA), higher carbon dioxide, but lower pH. These highly productive, vegetated wetlands are deemed to export both alkalinity and dissolved inorganic carbon (DIC) to the ocean. This creates an apppartent paradox in that salt marshes are both an acidifying and alkalizing source to the ocean. Limited studies suggest that marsh DIC and alkalinity export fluxes may be a significant player in regional and global carbon budgets, but the current estimates are still far too uncertain to be conclusive. Unfortunately, tidal marsh ecosystems have dramatically diminished in the recent past, and are likely to diminish further due to sea level rise, land development, eutrophication, and other anthropogenic pressures. To assess the potential impacts of this future change, it is imperative to understand its current status and accurately evaluate its significatce to other parts of the carbon cycle. Similarly, little is know about the distinct sources of DIC and alkalinity being exported from marshes via tidal exchange, although aerobic and various anaerobic respiration processes have been indicated. In this study, researchers will undertake an in-depth study using new methods to vastly improve export fluxes from intertidal salt marshes through tidal exchange over minutes to annual scales, characterize and evaluate the compostiion (carbonate versus non-carbonate alkalinity) of marsh exported TA, the role and significance of the DOC pool in altering carbonate chemistry and export fluxes, identify sources of DIC being exported in tidal water, and investigate how marsh export of TA and DIC impacts carbonate chemistry and the carbon and alkalinity budgets in coastal waters. |
attribute | NC_GLOBAL | projects_0_end_date | String | 2019-02 |
attribute | NC_GLOBAL | projects_0_geolocation | String | Sage Lot Pond salt marsh tidal creek in Waquoit Bay, MA at approx. 41.5546N, -70.5071W |
attribute | NC_GLOBAL | projects_0_name | String | Collaborative Research: The Paradox of Salt Marshes as a Source of Alkalinity and Low pH, High Carbon Dioxide Water to the Ocean: A First In-depth Study of A Diminishing Source |
attribute | NC_GLOBAL | projects_0_project_nid | String | 765032 |
attribute | NC_GLOBAL | projects_0_start_date | String | 2015-03 |
attribute | NC_GLOBAL | publisher_name | String | Biological and Chemical Oceanographic Data Management Office (BCO-DMO) |
attribute | NC_GLOBAL | publisher_type | String | institution |
attribute | NC_GLOBAL | sourceUrl | String | (local files) |
attribute | NC_GLOBAL | standard_name_vocabulary | String | CF Standard Name Table v55 |
attribute | NC_GLOBAL | summary | String | Sensor measurements for dissolved inorganic carbon from the Sage Lot Pond salt marsh tidal creek in Waquoit Bay, MA from July to December 2015. DIC was measured with an autonomous sensor called CHANnelized Optical Sensor (CHANOS). |
attribute | NC_GLOBAL | time_coverage_end | String | 2015-12-18T15:15:00Z |
attribute | NC_GLOBAL | time_coverage_start | String | 2015-07-07T20:15:00Z |
attribute | NC_GLOBAL | title | String | [Salt marsh continuous DIC] - Sensor measurements for dissolved inorganic carbon from the Sage Lot Pond salt marsh tidal creek in Waquoit Bay, MA from July to December 2015 (Collaborative Research: The Paradox of Salt Marshes as a Source of Alkalinity and Low pH, High Carbon Dioxide Water to the Ocean: A First In-depth Study of A Diminishing Source) |
attribute | NC_GLOBAL | version | String | 1 |
attribute | NC_GLOBAL | xml_source | String | osprey2erddap.update_xml() v1.3 |
variable | time | double | ||
attribute | time | _CoordinateAxisType | String | Time |
attribute | time | actual_range | double | 1.4363001E9, 1.4504517E9 |
attribute | time | axis | String | T |
attribute | time | bcodmo_name | String | date |
attribute | time | description | String | Date and time (UTC) formatted to ISO8601 standard. Format: yyyy-mm-ddTHH:MM |
attribute | time | ioos_category | String | Time |
attribute | time | long_name | String | ISO Date Time UTC |
attribute | time | nerc_identifier | String | https://vocab.nerc.ac.uk/collection/P01/current/ADATAA01/ |
attribute | time | source_name | String | ISO_DateTime_UTC |
attribute | time | standard_name | String | time |
attribute | time | time_origin | String | 01-JAN-1970 00:00:00 |
attribute | time | time_precision | String | 1970-01-01T00:00:00Z |
attribute | time | units | String | seconds since 1970-01-01T00:00:00Z |
variable | TEMPERATURE | float | ||
attribute | TEMPERATURE | _FillValue | float | NaN |
attribute | TEMPERATURE | actual_range | float | 4.85, 30.61 |
attribute | TEMPERATURE | bcodmo_name | String | temperature |
attribute | TEMPERATURE | description | String | Water temperature |
attribute | TEMPERATURE | long_name | String | TEMPERATURE |
attribute | TEMPERATURE | nerc_identifier | String | https://vocab.nerc.ac.uk/collection/P01/current/TEMPP901/ |
attribute | TEMPERATURE | units | String | degrees Celsius |
variable | SALINITY | float | ||
attribute | SALINITY | _FillValue | float | NaN |
attribute | SALINITY | actual_range | float | 14.47, 32.65 |
attribute | SALINITY | bcodmo_name | String | sal |
attribute | SALINITY | colorBarMaximum | double | 37.0 |
attribute | SALINITY | colorBarMinimum | double | 32.0 |
attribute | SALINITY | description | String | Water salinity |
attribute | SALINITY | long_name | String | Sea Water Practical Salinity |
attribute | SALINITY | nerc_identifier | String | https://vocab.nerc.ac.uk/collection/P01/current/PSALST01/ |
attribute | SALINITY | units | String | practical salinity scale |
variable | CHANOSDIC | float | ||
attribute | CHANOSDIC | _FillValue | float | NaN |
attribute | CHANOSDIC | actual_range | float | 1246.12, 2482.21 |
attribute | CHANOSDIC | bcodmo_name | String | DIC |
attribute | CHANOSDIC | description | String | Dissolved inorganic carbon |
attribute | CHANOSDIC | long_name | String | CHANOSDIC |
attribute | CHANOSDIC | units | String | micromoles per kilogram (umol/kg) |