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Grid DAP Data | Sub- set | Table DAP Data | Make A Graph | W M S | Source Data Files | Acces- sible | Title | Sum- mary | FGDC, ISO, Metadata | Back- ground Info | RSS | E | Institution | Dataset ID |
---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
set | data | graph | files | public | [ammonium removal by seaweeds] - Macroalgal contribution to NH4+ removal in tidepools from Cape Flattery, WA from 2010-2011 (Regenerated Nitrogen project) (The Role of Regenerated Nitrogen for Rocky Shore Productivity) | F I M | background | BCO-DMO | bcodmo_dataset_489420 |
Row Type | Variable Name | Attribute Name | Data Type | Value |
---|---|---|---|---|
attribute | NC_GLOBAL | access_formats | String | .htmlTable,.csv,.json,.mat,.nc,.tsv,.esriCsv,.geoJson |
attribute | NC_GLOBAL | acquisition_description | String | Laboratory analysis: NH4+ and NO3- concentrations were measured at the University of Washington Marine Chemistry Lab (methods from UNESCO 1994). Concentration values from 2011 were corrected for rain dilution using the change in salinity measured over the incubation period assuming no addition of NH4+ or NO3- to the pools from the rainfall. NH4+ isotopic composition was measured according to a modified version of Zhang et al. (2007) after isotope dilution to less than 500\u2030 to prevent isotopic contamination of the natural abundance-level mass spectrometer system. Briefly, NH4+ is oxidized to nitrite using hypobromite then reduced to N2O using acetic acid buffered sodium azide before analysis on an isotope ratio mass spectrometer (IRMS). In modification of the prior method, pre- existing NO2- was removed prior to hypobromite addition by reaction with sulfamic acid. To a 20 mL sample volume, 340 \u00b5L 20 mmol L-1 sulfamic acid and 10 \u00b5L 10% HCl was added and allowed to react for 12 hours at room temperature. A second improvement was the addition of 6 mol L-1 HCl to reduce the pH of the sample below 7 prior to the addition of an azide-100% acetic acid reagent. Isotope determinations were made at U. Massachusetts Dartmouth using a GV IsoPrime IRMS, a custom purge-trap sample preparation system, and a CTC PAL autosampler. Reproducibility was better than \u00b1 0.5\u2030. Filters and algal samples were dried at 60\u00b0C for 48 h and elemental and isotopic analyses were made at the University of Chicago and at Yale University. Samples were run using a Costech 4010 Elemental Analyzer combustion system coupled to a Thermo DeltaV Plus IRMS via a Thermo Conflo IV interface (University of Chicago), or using the same Elemental Analyzer coupled to a Thermo DeltaXP Advantage IRMS via a Thermo Conflo III interface (Yale University). \u00a0Reproducibility was better than \u00b1 0.1\u2030. |
attribute | NC_GLOBAL | awards_0_award_nid | String | 474676 |
attribute | NC_GLOBAL | awards_0_award_number | String | OCE-0928232 |
attribute | NC_GLOBAL | awards_0_data_url | String | http://www.nsf.gov/awardsearch/showAward?AWD_ID=0928232 |
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 | David L. Garrison |
attribute | NC_GLOBAL | awards_0_program_manager_nid | String | 50534 |
attribute | NC_GLOBAL | awards_1_award_nid | String | 474685 |
attribute | NC_GLOBAL | awards_1_award_number | String | OCE-0928015 |
attribute | NC_GLOBAL | awards_1_data_url | String | http://www.nsf.gov/awardsearch/showAward?AWD_ID=0928015 |
attribute | NC_GLOBAL | awards_1_funder_name | String | NSF Division of Ocean Sciences |
attribute | NC_GLOBAL | awards_1_funding_acronym | String | NSF OCE |
attribute | NC_GLOBAL | awards_1_funding_source_nid | String | 355 |
attribute | NC_GLOBAL | awards_1_program_manager | String | David L. Garrison |
attribute | NC_GLOBAL | awards_1_program_manager_nid | String | 50534 |
attribute | NC_GLOBAL | awards_2_award_nid | String | 474686 |
attribute | NC_GLOBAL | awards_2_award_number | String | OCE-0928152 |
attribute | NC_GLOBAL | awards_2_data_url | String | http://www.nsf.gov/awardsearch/showAward?AWD_ID=0928152 |
attribute | NC_GLOBAL | awards_2_funder_name | String | NSF Division of Ocean Sciences |
attribute | NC_GLOBAL | awards_2_funding_acronym | String | NSF OCE |
attribute | NC_GLOBAL | awards_2_funding_source_nid | String | 355 |
attribute | NC_GLOBAL | awards_2_program_manager | String | David L. Garrison |
attribute | NC_GLOBAL | awards_2_program_manager_nid | String | 50534 |
attribute | NC_GLOBAL | cdm_data_type | String | Other |
attribute | NC_GLOBAL | comment | String | Prionitis & Corallina NH4 removal S. Pather (UMass-SMAST) version: 2014-11-04 [added site column] replaces version: 24 January 2014 |
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 | 2014-02-03T13:54:03Z |
attribute | NC_GLOBAL | date_modified | String | 2016-08-20T03:10:46Z |
attribute | NC_GLOBAL | defaultDataQuery | String | &time<now |
attribute | NC_GLOBAL | doi | String | 10.1575/1912/6420 |
attribute | NC_GLOBAL | Easternmost_Easting | double | -124.57 |
attribute | NC_GLOBAL | geospatial_lat_max | double | 48.37 |
attribute | NC_GLOBAL | geospatial_lat_min | double | 48.37 |
attribute | NC_GLOBAL | geospatial_lat_units | String | degrees_north |
attribute | NC_GLOBAL | geospatial_lon_max | double | -124.57 |
attribute | NC_GLOBAL | geospatial_lon_min | double | -124.57 |
attribute | NC_GLOBAL | geospatial_lon_units | String | degrees_east |
attribute | NC_GLOBAL | infoUrl | String | https://www.bco-dmo.org/dataset/489420 |
attribute | NC_GLOBAL | institution | String | BCO-DMO |
attribute | NC_GLOBAL | instruments_0_acronym | String | IR Mass Spec |
attribute | NC_GLOBAL | instruments_0_dataset_instrument_description | String | GV IsoPrime IRMS: Isotope determinations were made at U. Massachusetts Dartmouth using a GV IsoPrime IRMS, a custom purge-trap sample preparation system, and a CTC PAL autosampler. Reproducibility was better than ± 0.5‰. |
attribute | NC_GLOBAL | instruments_0_dataset_instrument_nid | String | 489427 |
attribute | NC_GLOBAL | instruments_0_description | String | The Isotope-ratio Mass Spectrometer is a particular type of mass spectrometer used to measure the relative abundance of isotopes in a given sample (e.g. VG Prism II Isotope Ratio Mass-Spectrometer). |
attribute | NC_GLOBAL | instruments_0_instrument_external_identifier | String | https://vocab.nerc.ac.uk/collection/L05/current/LAB16/ |
attribute | NC_GLOBAL | instruments_0_instrument_name | String | Isotope-ratio Mass Spectrometer |
attribute | NC_GLOBAL | instruments_0_instrument_nid | String | 469 |
attribute | NC_GLOBAL | instruments_0_supplied_name | String | IR Mass Spec |
attribute | NC_GLOBAL | instruments_1_acronym | String | Nutrient Autoanalyzer |
attribute | NC_GLOBAL | instruments_1_dataset_instrument_description | String | The nutrient autoanalyzer at UWashington was used to determine the nutrient concentrations in the water. Analyses and calibration follow the protocols of the WOCE Hydrographic Program using a Technicon AAII system. For more information, see http://www.ocean.washington.edu/story/Marine+Chemistry+Laboratory |
attribute | NC_GLOBAL | instruments_1_dataset_instrument_nid | String | 489428 |
attribute | NC_GLOBAL | instruments_1_description | String | Nutrient Autoanalyzer is a generic term used when specific type, make and model were not specified. In general, a Nutrient Autoanalyzer is an automated flow-thru system for doing nutrient analysis (nitrate, ammonium, orthophosphate, and silicate) on seawater samples. |
attribute | NC_GLOBAL | instruments_1_instrument_external_identifier | String | https://vocab.nerc.ac.uk/collection/L05/current/LAB04/ |
attribute | NC_GLOBAL | instruments_1_instrument_name | String | Nutrient Autoanalyzer |
attribute | NC_GLOBAL | instruments_1_instrument_nid | String | 558 |
attribute | NC_GLOBAL | instruments_1_supplied_name | String | Nutrient Autoanalyzer |
attribute | NC_GLOBAL | instruments_2_acronym | String | CHN_EA |
attribute | NC_GLOBAL | instruments_2_dataset_instrument_description | String | Samples were run using a Costech 4010 Elemental Analyzer combustion system coupled to a Thermo DeltaV Plus IRMS via a Thermo Conflo IV interface (University of Chicago), or using the same Elemental Analyzer coupled to a Thermo DeltaXP Advantage IRMS via a Thermo Conflo III interface (Yale University). Reproducibility was better than ± 0.1‰. These instruments were used to look at the mass composition and isotopic signatures of the algal and filter material. |
attribute | NC_GLOBAL | instruments_2_dataset_instrument_nid | String | 489486 |
attribute | NC_GLOBAL | instruments_2_description | String | A CHN Elemental Analyzer is used for the determination of carbon, hydrogen, and nitrogen content in organic and other types of materials, including solids, liquids, volatile, and viscous samples. |
attribute | NC_GLOBAL | instruments_2_instrument_name | String | CHN Elemental Analyzer |
attribute | NC_GLOBAL | instruments_2_instrument_nid | String | 625 |
attribute | NC_GLOBAL | instruments_2_supplied_name | String | CHN_EA |
attribute | NC_GLOBAL | keywords | String | bco, bco-dmo, biological, C_pcent, chemical, d15, d15N, data, dataset, date, dmo, erddap, latitude, longitude, management, N_pcent, oceanography, office, pcent, preliminary, sample, site, species, station, treatment |
attribute | NC_GLOBAL | license | String | https://www.bco-dmo.org/dataset/489420/license |
attribute | NC_GLOBAL | metadata_source | String | https://www.bco-dmo.org/api/dataset/489420 |
attribute | NC_GLOBAL | Northernmost_Northing | double | 48.37 |
attribute | NC_GLOBAL | param_mapping | String | {'489420': {'lat': 'master - latitude', 'lon': 'master - longitude'}} |
attribute | NC_GLOBAL | parameter_source | String | https://www.bco-dmo.org/mapserver/dataset/489420/parameters |
attribute | NC_GLOBAL | people_0_affiliation | String | University of Massachusetts Dartmouth |
attribute | NC_GLOBAL | people_0_affiliation_acronym | String | UMASSD-SMAST |
attribute | NC_GLOBAL | people_0_person_name | String | Ms Santhiska Pather |
attribute | NC_GLOBAL | people_0_person_nid | String | 488866 |
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 | University of Massachusetts Dartmouth |
attribute | NC_GLOBAL | people_1_affiliation_acronym | String | UMASSD-SMAST |
attribute | NC_GLOBAL | people_1_person_name | String | Mark A. Altabet |
attribute | NC_GLOBAL | people_1_person_nid | String | 50571 |
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 | University of Chicago |
attribute | NC_GLOBAL | people_2_person_name | String | Dr Catherine Pfister |
attribute | NC_GLOBAL | people_2_person_nid | String | 474679 |
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 | Yale University |
attribute | NC_GLOBAL | people_3_person_name | String | Dr David Post |
attribute | NC_GLOBAL | people_3_person_nid | String | 474683 |
attribute | NC_GLOBAL | people_3_role | String | Co-Principal Investigator |
attribute | NC_GLOBAL | people_3_role_type | String | originator |
attribute | NC_GLOBAL | people_4_affiliation | String | University of Massachusetts Dartmouth |
attribute | NC_GLOBAL | people_4_affiliation_acronym | String | UMASSD-SMAST |
attribute | NC_GLOBAL | people_4_person_name | String | Ms Santhiska Pather |
attribute | NC_GLOBAL | people_4_person_nid | String | 488866 |
attribute | NC_GLOBAL | people_4_role | String | Student |
attribute | NC_GLOBAL | people_4_role_type | String | related |
attribute | NC_GLOBAL | people_5_affiliation | String | Woods Hole Oceanographic Institution |
attribute | NC_GLOBAL | people_5_affiliation_acronym | String | WHOI BCO-DMO |
attribute | NC_GLOBAL | people_5_person_name | String | Nancy Copley |
attribute | NC_GLOBAL | people_5_person_nid | String | 50396 |
attribute | NC_GLOBAL | people_5_role | String | BCO-DMO Data Manager |
attribute | NC_GLOBAL | people_5_role_type | String | related |
attribute | NC_GLOBAL | project | String | Regenerated Nitrogen |
attribute | NC_GLOBAL | projects_0_acronym | String | Regenerated Nitrogen |
attribute | NC_GLOBAL | projects_0_description | String | We described patterns of nitrogen isotopes that change over spatial gradients of animal abundance, with isotopic enrichment patterns consistent with a role for animal excretion (Pfister et al, ms). We have quantified the microbes associated with intertidal mussels with metagenomics (Pfister et al. 2010 and 16S rRNA sequencing of the v4 region (Pfister et al, submitted). We used a novel experimental approach in which stable isotope tracers were added to exposed tidepools utilizing them as temporary mesocosms to quantify N transformation rates (Pather et al.,L&O). Large tracer signals were observed over the typical 4-5 hr experimental period in both the dilution of the isotope label in its added form (NH4+ or NO3-) and the appearance of the label in products (e.g. NO2-) The primary advantage was that all members of community participated in the experiment allowing us to recognize the complexity of nitrogen cycling in this system. This funding also supported long-term global change research on Tatoosh Island (Wootton & Pfister 2012 ). Project Summary From Original Proposal A fundamental and persistent question in a multitude of ecosystems is the extent to which new versus regenerated nutrients support ecosystem productivity. In coastal marine systems, nitrate derived from upwelling (=new nitrogen) and ammonium regeneration in coastal waters and sediments (=regenerated nitrogen) are major nitrogen sources that fuel coastal ocean productivity. Because inorganic nitrogen availability clearly regulates production in a large number of areas, understanding nitrogen supply is essential. In open coast regions away from river mouths, nitrate inputs are determined by large-scale physical processes promoting upwelling of deep, nutrient-rich water including wind direction and intensity. In contrast, regenerated nitrogen (mainly ammonium) is generally the result of local animal and microbial processes. Along marine rocky shores, where upwelling is typically used as a proxy for productivity, we know very little about the dynamics of regenerated nutrients and their potential contribution to productivity at larger scales; only upwelling is typically used as a proxy for productivity. Associations of the abundant California mussel, Mytilus californianus, with water nutrients, algal productivity, stable isotope signatures, and microbial genetics indicate potentially strong regeneration of nitrogen by these animals and suggests an important secondary role of nitrifying microbes affiliated with these animals. We propose collaborative work to quantify the relative contribution of regenerated nitrogen on rocky shores through censuses and experiments across a gradient of mussel abundance. We will use stable nitrogen and oxygen isotopes of ammonium, nitrite, and nitrate to disentangle the contribution of different biological processes versus upwelling to the nitrogen supply and uptake of rocky shore regions. This includes both natural abundance and tracer addition studies. Relevant References: 2010. Pfister, C. A., F. Meyer, D. A. Antonopoulos. Metagenomic profiling of a microbial assemblage associated with the California mussel, Mytilus californianus: a node in networks of carbon and nitrogen cycling. PLoS ONE 5(5): e10518. doi:10.1371/ journal.pone.0010518. Metagenome data associated with this paper are uploaded to MGRAST server at http://metagenomics.anl.gov/ 2012. Wootton, J. T. & C. A. Pfister. Carbon system measurements and potential climatic drivers at a site of rapidly declining ocean pH. PLoS ONE 7(12): e53396. doi:10.1371/ journal.pone.0053396. Data associated with this paper are uploaded to the World Ocean DataBase, https://www.nodc.noaa.gov in press. Pather, S., C. A. Pfister, M. Altabet, D. M. Post. Ammonium cycling in the rocky intertidal: remineralization, removal and retention. Limnology and Oceanography in review (1/2014). Pfister, C. A., M. Altabet, D. Post. Animal Regeneration and microbial retention of nitrogen along coastal rocky shores. |
attribute | NC_GLOBAL | projects_0_end_date | String | 2013-08 |
attribute | NC_GLOBAL | projects_0_geolocation | String | coastal northeast Pacific Ocean |
attribute | NC_GLOBAL | projects_0_name | String | The Role of Regenerated Nitrogen for Rocky Shore Productivity |
attribute | NC_GLOBAL | projects_0_project_nid | String | 474677 |
attribute | NC_GLOBAL | projects_0_project_website | String | http://pfisterlab.uchicago.edu |
attribute | NC_GLOBAL | projects_0_start_date | String | 2009-09 |
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 | Southernmost_Northing | double | 48.37 |
attribute | NC_GLOBAL | standard_name_vocabulary | String | CF Standard Name Table v55 |
attribute | NC_GLOBAL | subsetVariables | String | site,latitude,longitude |
attribute | NC_GLOBAL | summary | String | We evaluated the role of mussels by adding 15N-labeled NH4+ to an assemblage of tidepools where they were either present at natural abundance levels, or absent through manual removal. \u00a0The role of phototrophs was separately examined by conducting these experiments both during the day and at night. \u00a0The tidal height of pools varied between 1.2 to 1.5 m above Mean Lower Low Water (MLLW). Tidepools were thus isolated from each other as well as the nearshore environment during the low tide period when experiments were conducted. Each experiment included 4 to 5 mussel removal (MR) tidepools (since 2002) and 4 to 5 mussel control (MC) tidepools with natural mussel densities. \u00a0In June 2010, we performed daytime NH4+ tracer experiments and in August 2010 nighttime experiments using the same tidepools. The following year (July 2011) these experiments were repeated with the addition of bottle incubations (see below) to evaluate the effects of suspended tidepool components and extended sampling for 6 days after the initial 15N addition to test for long-term retention of NH4+. \u00a0During the 2011 experiments, unforeseen rain reduced the salinity in some pools by up to 51%, and we have attempted to correct for the expected dilution of NH4+ in our tidepool rate calculations. Because isotope enrichment levels were relatively low, we used the conventional delta notation instead of atom% to describe variations in 15N enrichment (where delta-15NH4+ = {(15N:14N sample \u00f7 15N:14N standard) -1}\u00d71000\u2030, where the standard is atmospheric N2. \u00a0Tracer labeled ammonium chloride (15NH4Cl) was added to the pools to approximate a 1000\u2030 enrichment in 2010 (doubling the 15N-NH4+ concentration) and a 2000\u2030 enrichment in 2011(tripling the 15N-NH4+ concentration). 15N natural abundance is only 0.365% and these tracer additions thus had a negligible effect on the overall NH4+ concentrations increasing them by only ~0.4% and ~0.8%, respectively. Tidepool volumes were estimated spectrophotometrically using varying concentrations of food dye (Pfister 1995). Together with estimates of NH4+ concentration (from 2009 data), we estimated the tracer addition required to achieve the targeted 15N enrichments. However, the actual initial enrichments varied substantially, 684.4 - 2406.4\u2030 in 2010 and 781.4 - 3880.2\u2030 in 2011, likely due to error in tidepool volume estimation and natural variations in initial NH4+ concentrations. Fortunately, we sampled immediately following each tracer addition allowing for the determination of the true initial 15N enrichment. \u00a0 Prior to tracer addition at ebb tide, 100 mL of tidepool water was syringe- filtered (Whatman GF/F) into separate HDPE bottles for natural abundance 15NH4+ and concentration determination. \u00a0To each pool, tracer 15NH4+ was then added and distributed by stirring with a stick. Water samples were immediately collected for measuring initial 15N enrichment and subsequently at 2, 4, and 6 hour intervals to determine isotope and concentration time courses. All water samples were frozen until analysis. Tidepool oxygen, pH, and temperature (Hach HQ4D) were also collected at ~ 2 h intervals throughout the experiment. In 2011 we also assessed the contribution of the suspended microbial community to NH4+ cycling by enclosing tidepool water in a 250 mL transparent polycarbonate incubation bottle. Following tracer addition, the bottle was filled, then left to float in the tidepool for the duration of the experiment. Samples from bottles were filtered as described both immediately after containment and at the end of the experiment (~6 h later). We assessed macroalgal contribution to NH4+ removal by transplanting two tidepool-dwelling algae species. \u00a0Prionitis sternbergii were sampled 2 weeks prior to the experiment for baseline natural abundance 15N values and transplanted into the pools with Z-Spar Epoxy (Pfister 2007). On the day of the experiment, the red-alga, Corallina vancouveriensis from a single source patch, was also sampled for 15N natural abundance, inserted into pieces of Styrofoam, and floated in each pool. At the end of each experiment (~6 h sampling point), we sampled tidepool particulate organic material (POM) by filtering through combusted GF/F filters until they clogged (~ 600 mL), comparing these samples with POM similarly sampled from the immediate nearshore. \u00a0Floating Corallina spp. samples were collected into clean Eppendorf tubes, and similar sized pieces of Prionitis spp. were collected from each pool into clean foil packets.\u00a0 We evaluated the extent of longer-term 15N tracer retention in 2011 by sampling tidepool water, POM and transplanted Prionitis 1, 3, and 6 days following tracer addition. We sampled at ebb tide and at again at slack water just prior to high tide on the first day after tracer addition (that is, 24 h later) and at slack water prior to high tide on Day 3 and 6.\u00a0 Relevant References: 2014\. Pather, S., C. A. Pfister, M. Altabet, D. M. Post. Ammonium cycling in the rocky intertidal: remineralization, removal and retention. Limnology and Oceanography 59:361-372.\u00a0[http://aslo.org/lo/toc/vol_59/issue_2/0361.htm](\\http://aslo.org/lo/toc/vol_59/issue_2/0361.html\\) DOI for this dataset:\u00a0The role of regenerated nitrogen for rocky shore productivity, Cape Flattery, Washington, 2010 & 2011.\u00a0Handle:\u00a0[http://hdl.handle.net/1912/6420](\\http://hdl.handle.net/1912/6420\\).\u00a0DOI:10.1575/1912/6420 Related Datasets: [filter tracer content](\\https://www.bco-dmo.org/dataset/489283\\) [natural abundance N and C filter content](\\http://www.bco- dmo.org/dataset/489310\\) [tidepool ammonium and mussels](\\https://www.bco-dmo.org/dataset/488860\\) [tidepool incubation ammonium](\\https://www.bco-dmo.org/dataset/489085\\) |
attribute | NC_GLOBAL | title | String | [ammonium removal by seaweeds] - Macroalgal contribution to NH4+ removal in tidepools from Cape Flattery, WA from 2010-2011 (Regenerated Nitrogen project) (The Role of Regenerated Nitrogen for Rocky Shore Productivity) |
attribute | NC_GLOBAL | version | String | 1 |
attribute | NC_GLOBAL | Westernmost_Easting | double | -124.57 |
attribute | NC_GLOBAL | xml_source | String | osprey2erddap.update_xml() v1.3 |
variable | site | String | ||
attribute | site | bcodmo_name | String | site |
attribute | site | description | String | sampling location |
attribute | site | long_name | String | Site |
attribute | site | units | String | unitless |
variable | latitude | double | ||
attribute | latitude | _CoordinateAxisType | String | Lat |
attribute | latitude | _FillValue | double | NaN |
attribute | latitude | actual_range | double | 48.37, 48.37 |
attribute | latitude | axis | String | Y |
attribute | latitude | bcodmo_name | String | latitude |
attribute | latitude | colorBarMaximum | double | 90.0 |
attribute | latitude | colorBarMinimum | double | -90.0 |
attribute | latitude | description | String | latitude; north is positive |
attribute | latitude | ioos_category | String | Location |
attribute | latitude | long_name | String | Latitude |
attribute | latitude | nerc_identifier | String | https://vocab.nerc.ac.uk/collection/P09/current/LATX/ |
attribute | latitude | standard_name | String | latitude |
attribute | latitude | units | String | degrees_north |
variable | longitude | double | ||
attribute | longitude | _CoordinateAxisType | String | Lon |
attribute | longitude | _FillValue | double | NaN |
attribute | longitude | actual_range | double | -124.57, -124.57 |
attribute | longitude | axis | String | X |
attribute | longitude | bcodmo_name | String | longitude |
attribute | longitude | colorBarMaximum | double | 180.0 |
attribute | longitude | colorBarMinimum | double | -180.0 |
attribute | longitude | description | String | longitude; east is positive |
attribute | longitude | ioos_category | String | Location |
attribute | longitude | long_name | String | Longitude |
attribute | longitude | nerc_identifier | String | https://vocab.nerc.ac.uk/collection/P09/current/LONX/ |
attribute | longitude | standard_name | String | longitude |
attribute | longitude | units | String | degrees_east |
variable | species | String | ||
attribute | species | bcodmo_name | String | species |
attribute | species | description | String | seaweed species in tidepool |
attribute | species | long_name | String | Species |
attribute | species | units | String | unitless |
variable | station | byte | ||
attribute | station | _FillValue | byte | 127 |
attribute | station | actual_range | byte | 8, 40 |
attribute | station | bcodmo_name | String | sta |
attribute | station | description | String | tidepool identification number |
attribute | station | long_name | String | Station |
attribute | station | units | String | unitless |
variable | treatment | String | ||
attribute | treatment | bcodmo_name | String | treatment |
attribute | treatment | description | String | mussels removed or present in tidepool |
attribute | treatment | long_name | String | Treatment |
attribute | treatment | units | String | unitless |
variable | sample | String | ||
attribute | sample | bcodmo_name | String | sample |
attribute | sample | description | String | sample identification number |
attribute | sample | long_name | String | Sample |
attribute | sample | nerc_identifier | String | https://vocab.nerc.ac.uk/collection/P02/current/ACYC/ |
attribute | sample | units | String | unitless |
variable | date | int | ||
attribute | date | _FillValue | int | 2147483647 |
attribute | date | actual_range | int | 20110713, 20110722 |
attribute | date | bcodmo_name | String | date |
attribute | date | description | String | date samples collected in yyyymmdd format |
attribute | date | long_name | String | Date |
attribute | date | nerc_identifier | String | https://vocab.nerc.ac.uk/collection/P01/current/ADATAA01/ |
attribute | date | units | String | unitless |
variable | d15N | float | ||
attribute | d15N | _FillValue | float | NaN |
attribute | d15N | actual_range | float | 5.28, 150.67 |
attribute | d15N | bcodmo_name | String | unknown |
attribute | d15N | description | String | nitrogen isotopic composition (delta 15N:N14) of the (mostly organic) material trapped on the filter |
attribute | d15N | long_name | String | D15 N |
attribute | d15N | units | String | parts per thousand vs. VSMOW (Vienna Standard Mean Ocean Water) |
variable | N_pcent | float | ||
attribute | N_pcent | _FillValue | float | NaN |
attribute | N_pcent | actual_range | float | 0.584, 9.73 |
attribute | N_pcent | bcodmo_name | String | unknown |
attribute | N_pcent | description | String | percent nitrogen of filter |
attribute | N_pcent | long_name | String | N Pcent |
attribute | N_pcent | units | String | percent |
variable | C_pcent | float | ||
attribute | C_pcent | _FillValue | float | NaN |
attribute | C_pcent | actual_range | float | 4.493, 163.757 |
attribute | C_pcent | bcodmo_name | String | unknown |
attribute | C_pcent | description | String | percent carbon of filter |
attribute | C_pcent | long_name | String | C Pcent |
attribute | C_pcent | units | String | percent |
The information in the table above is also available in other file formats (.csv, .htmlTable, .itx, .json, .jsonlCSV1, .jsonlCSV, .jsonlKVP, .mat, .nc, .nccsv, .tsv, .xhtml) via a RESTful web service.