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 | Physiological Methods\n \nPhotosynthesis, respiration, and calcification measurements were performed on\neach fragment using 300 mL temperature-controlled respirometry chambers filled\nwith seawater from the treatment aquaria that was continuously stirred with a\nmagnetic stir bar. \\u00a0The chambers were used to assess the rates of\nrespiration (Rd) in the dark and rates of photosynthesis (Pn) and\ncalcification in the light. \\u00a0Light was supplied by a series of blue and\nred LEDs with adjustable intensity (150 uMol quanta m-2 sec-1). \\u00a0Water\nsamples were taken from each chamber prior to a cycle and also at the end of\nboth dark and light incubations (60 minutes each) for measurements of pHT (pH\non the total scale) and total alkalinity (AT) as described in Martin and\nGattuso (2009). \\u00a0\n \nCalcification - Total alkalinity (TA) values were measured using an automatic\npotentiometric titrator (Metrohm 807 Titrando, Riverview, FL) to the second\nend point of a 15.3-g accurately weighed seawater sample. \\u00a0Total\nalkalinity values were then computed using the Gran equation (DOE, 1994) with\npH values lower than 3.9 for creating the Gran plot. The pH electrodes\n(Metrohm 807 Titrando) were calibrated daily as described above. \\u00a0The\nacid titrant concentration was 0.05N HCl (JT Baker, Phillipsburg, NJ).\n\\u00a0Alkalinity was calculated using the first derivative of the curve for\nthe evaluation of the exact end point. \\u00a0Standards for total seawater\nalkalinity and provided by Dickson were run daily (Dickson, 2007). \\u00a0The\ndifferences between duplicate samples and standards were less than 5 uEq kg-1\n(for calibration of the titrator, differences were measured between triplicate\nsamples). \\u00a0Water samples were analyzed immediately or stored in darkness\nat 4C and processed within 24 hours of collection. \\u00a0\n \nDickson AG, Sabine CL, and Christian JR (2007) Guide to best practices for\nocean CO2 measurements: PICES Special Publication. 3, 191 p.\n \nMartin S and Gattuso J-P (2009) Response of Mediterranean coralline algae to\nocean acidification and elevated temperature. Glob Change Biol\n15:2089-2100.\\u00a0 \n Marubini F and Thake B (1999) Bicarbonate addition promotes coral growth.\nLimnol and Oceanogr 44: 716-720.\n \nRiebesell U, Fabry VJ, Hansson L, and Gattuso JP (2010) Guide to best\npractices for ocean acidification research and data reporting. European\nCommission, European Research Area. Brussels. 258 p\n \n\\u00a0 |
attribute | NC_GLOBAL | awards_0_award_nid | String | 642851 |
attribute | NC_GLOBAL | awards_0_award_number | String | OCE-1452538 |
attribute | NC_GLOBAL | awards_0_data_url | String | http://www.nsf.gov/awardsearch/showAward?AWD_ID=1452538&HistoricalAwards=false |
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 | Michael E. Sieracki |
attribute | NC_GLOBAL | awards_0_program_manager_nid | String | 50446 |
attribute | NC_GLOBAL | cdm_data_type | String | Other |
attribute | NC_GLOBAL | comment | String | Acropora cervicornis calcification \n PI: Erinn Muller \n data version: 2017-10-05 |
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 | 2017-08-08T15:40:41Z |
attribute | NC_GLOBAL | date_modified | String | 2019-10-18T16:32:43Z |
attribute | NC_GLOBAL | defaultDataQuery | String | &time<now |
attribute | NC_GLOBAL | doi | String | 10.1575/1912/bco-dmo.712377.1 |
attribute | NC_GLOBAL | infoUrl | String | https://www.bco-dmo.org/dataset/712377 |
attribute | NC_GLOBAL | institution | String | BCO-DMO |
attribute | NC_GLOBAL | instruments_0_acronym | String | YSI ProPlus |
attribute | NC_GLOBAL | instruments_0_dataset_instrument_description | String | temperature measured with YSI Pro 2030 |
attribute | NC_GLOBAL | instruments_0_dataset_instrument_nid | String | 716203 |
attribute | NC_GLOBAL | instruments_0_description | String | The YSI Professional Plus handheld multiparameter meter provides for the measurement of a variety of combinations for dissolved oxygen, conductivity, specific conductance, salinity, resistivity, total dissolved solids (TDS), pH, ORP, pH/ORP combination, ammonium (ammonia), nitrate, chloride and temperature. More information from the manufacturer. |
attribute | NC_GLOBAL | instruments_0_instrument_name | String | YSI Professional Plus Multi-Parameter Probe |
attribute | NC_GLOBAL | instruments_0_instrument_nid | String | 666 |
attribute | NC_GLOBAL | instruments_0_supplied_name | String | YSI Pro 2030 |
attribute | NC_GLOBAL | instruments_1_acronym | String | pH Sensor |
attribute | NC_GLOBAL | instruments_1_dataset_instrument_nid | String | 716206 |
attribute | NC_GLOBAL | instruments_1_description | String | General term for an instrument that measures the pH or how acidic or basic a solution is. |
attribute | NC_GLOBAL | instruments_1_instrument_name | String | pH Sensor |
attribute | NC_GLOBAL | instruments_1_instrument_nid | String | 674 |
attribute | NC_GLOBAL | instruments_1_supplied_name | String | Mettler Toledo SevenGo Pro |
attribute | NC_GLOBAL | instruments_2_acronym | String | Automatic titrator |
attribute | NC_GLOBAL | instruments_2_dataset_instrument_nid | String | 712520 |
attribute | NC_GLOBAL | instruments_2_description | String | Instruments that incrementally add quantified aliquots of a reagent to a sample until the end-point of a chemical reaction is reached. |
attribute | NC_GLOBAL | instruments_2_instrument_external_identifier | String | https://vocab.nerc.ac.uk/collection/L05/current/LAB12/ |
attribute | NC_GLOBAL | instruments_2_instrument_name | String | Automatic titrator |
attribute | NC_GLOBAL | instruments_2_instrument_nid | String | 682 |
attribute | NC_GLOBAL | instruments_2_supplied_name | String | Metrohm 807 Titrando |
attribute | NC_GLOBAL | keywords | String | bco, bco-dmo, biological, calcification, chamber, chemical, cycle, data, dataset, date, dmo, erddap, genotype, management, oceanography, office, preliminary, tank, Temp, temperature, time |
attribute | NC_GLOBAL | license | String | https://www.bco-dmo.org/dataset/712377/license |
attribute | NC_GLOBAL | metadata_source | String | https://www.bco-dmo.org/api/dataset/712377 |
attribute | NC_GLOBAL | param_mapping | String | {'712377': {}} |
attribute | NC_GLOBAL | parameter_source | String | https://www.bco-dmo.org/mapserver/dataset/712377/parameters |
attribute | NC_GLOBAL | people_0_affiliation | String | Mote Marine Laboratory |
attribute | NC_GLOBAL | people_0_affiliation_acronym | String | Mote |
attribute | NC_GLOBAL | people_0_person_name | String | Dr Erinn Muller |
attribute | NC_GLOBAL | people_0_person_nid | String | 642853 |
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 | Woods Hole Oceanographic Institution |
attribute | NC_GLOBAL | people_1_affiliation_acronym | String | WHOI BCO-DMO |
attribute | NC_GLOBAL | people_1_person_name | String | Amber York |
attribute | NC_GLOBAL | people_1_person_nid | String | 643627 |
attribute | NC_GLOBAL | people_1_role | String | BCO-DMO Data Manager |
attribute | NC_GLOBAL | people_1_role_type | String | related |
attribute | NC_GLOBAL | project | String | Resilient Acerv |
attribute | NC_GLOBAL | projects_0_acronym | String | Resilient Acerv |
attribute | NC_GLOBAL | projects_0_description | String | ABSTRACT\nCaribbean staghorn coral was one of the most common corals within reefs of the Florida Keys several decades ago. Over the last 40 years disease, bleaching, overfishing and habitat degradation caused a 95% reduction of the population. Staghorn coral is now listed as threatened under the U.S. Endangered Species Act of 1973. Within the past few years, millions of dollars have been invested for the purpose of restoring the population of staghorn coral within Florida and the U.S. Virgin Islands. Significant effort has been placed on maintaining and propagating corals of known genotypes within coral nurseries for the purpose of outplanting. However, little is known about the individual genotypes that are currently being outplanted from nurseries onto coral reefs. Are the genotypes being used for outplanting resilient enough to survive the three major stressors affecting the population in the Florida Keys: disease, high water temperatures, and ocean acidification? The research within the present study will be the first step in answering this critically important question. The funded project will additionally develop a research-based afterschool program with K-12 students in the Florida Keys and U.S. Virgin Islands that emphasizes an inquiry-based curriculum, STEM research activities, and peer-to-peer mentoring. The information from the present study will help scientists predict the likelihood of species persistence within the lower Florida Keys under future climate-change and ocean-acidification scenarios. Results of this research will also help guide restoration efforts throughout Florida and the Caribbean, and lead to more informative, science-based restoration activities.\nAcropora cervicornis dominated shallow-water reefs within the Florida Keys for at least the last half a million years, but the population has recently declined due to multiple stressors. Understanding the current population level of resilience to three major threats - disease outbreaks, high water temperatures, and ocean acidification conditions - is critical for the preservation of this threatened species. Results from the present study will answer the primary research question: will representative genotypes from the lower Florida Keys provide enough phenotypic variation for this threatened species to survive in the future? The present proposal will couple controlled laboratory challenge experiments with field data and modeling applications, and collaborate with local educators to fulfill five objectives: 1) identify A. cervicornis genotypes resistant to disease, 2) identify A. cervicornis genotypes resilient to high water temperature and ocean acidification conditions, 3) quantify how high water temperature and ocean acidification conditions impact disease dynamics on A. cervicornis; 4) determine tradeoffs in life-history traits because of resilience factors; and 5) apply a trait-based model, which will predict genotypic structure of a population under different environmental scenarios. |
attribute | NC_GLOBAL | projects_0_end_date | String | 2020-05 |
attribute | NC_GLOBAL | projects_0_geolocation | String | Florida Keys, Summerland Key, FL 24.563595°, -81.278572° |
attribute | NC_GLOBAL | projects_0_name | String | CAREER: Applying phenotypic variability to identify resilient Acropora cervicornis genotypes in the Florida Keys |
attribute | NC_GLOBAL | projects_0_project_nid | String | 642850 |
attribute | NC_GLOBAL | projects_0_start_date | String | 2015-04 |
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 | This dataset contains Acropora cervicornis calcification data from experiments conducted in tanks at Summerland Key, Florida (24.6616,-81.4538) between 2016-09-02 and 2016-09-10 with corals from a nursery located near Looe Key Reef (24.5636, -81.2786). |
attribute | NC_GLOBAL | title | String | [Acropora cervicornis calcification rates] - Acropora cervicornis growth rates under different pH and temperature treatments from experiments at Summerland Key, Florida in September of 2016 (CAREER: Applying phenotypic variability to identify resilient Acropora cervicornis genotypes in the Florida Keys) |
attribute | NC_GLOBAL | version | String | 1 |
attribute | NC_GLOBAL | xml_source | String | osprey2erddap.update_xml() v1.3 |
variable | pH | String | ||
attribute | pH | bcodmo_name | String | pH |
attribute | pH | description | String | Treatment pH level; ambient = 8.1 pH; hCO2 = 7.7 pH |
attribute | pH | long_name | String | pH |
attribute | pH | nerc_identifier | String | https://vocab.nerc.ac.uk/collection/P01/current/PHXXZZXX/ |
attribute | pH | units | String | unitless |
variable | Temp | byte | ||
attribute | Temp | _FillValue | byte | 127 |
attribute | Temp | actual_range | byte | 27, 31 |
attribute | Temp | bcodmo_name | String | temperature |
attribute | Temp | description | String | Treatment temperature level |
attribute | Temp | long_name | String | Temperature |
attribute | Temp | nerc_identifier | String | https://vocab.nerc.ac.uk/collection/P01/current/TEMPP901/ |
attribute | Temp | units | String | Celsius |
variable | Tank | byte | ||
attribute | Tank | _FillValue | byte | 127 |
attribute | Tank | actual_range | byte | 1, 20 |
attribute | Tank | bcodmo_name | String | tank |
attribute | Tank | description | String | Tank number that held the particular coral fragment |
attribute | Tank | long_name | String | Tank |
attribute | Tank | units | String | unitless |
variable | Chamber | String | ||
attribute | Chamber | bcodmo_name | String | treatment |
attribute | Chamber | description | String | Chamber number that held the coral fragment during the light and dark cycle |
attribute | Chamber | long_name | String | Chamber |
attribute | Chamber | units | String | unitless |
variable | Genotype | byte | ||
attribute | Genotype | _FillValue | byte | 127 |
attribute | Genotype | actual_range | byte | 1, 63 |
attribute | Genotype | bcodmo_name | String | sample_descrip |
attribute | Genotype | description | String | Genotype number of the coral animal for each fragment |
attribute | Genotype | long_name | String | Genotype |
attribute | Genotype | units | String | unitless |
variable | Cycle | String | ||
attribute | Cycle | bcodmo_name | String | treatment |
attribute | Cycle | description | String | Characterizes whether the coral was exposed to light or held in the dark prior to final measurements |
attribute | Cycle | long_name | String | Cycle |
attribute | Cycle | units | String | unitless |
variable | Calcification | float | ||
attribute | Calcification | _FillValue | float | NaN |
attribute | Calcification | actual_range | float | -0.307, 1.594 |
attribute | Calcification | bcodmo_name | String | calcification |
attribute | Calcification | description | String | Rate at which the coral is utilizing calcium carbonate for skeletal growth |
attribute | Calcification | long_name | String | Calcification |
attribute | Calcification | units | String | micromoles of calcium carbonate per centimeter squred per hour (CaCO3/cm2/h) |
variable | Date | String | ||
attribute | Date | bcodmo_name | String | date |
attribute | Date | description | String | Date in format yyyy-mm-dd |
attribute | Date | long_name | String | Date |
attribute | Date | nerc_identifier | String | https://vocab.nerc.ac.uk/collection/P01/current/ADATAA01/ |
attribute | Date | source_name | String | Date |
attribute | Date | time_precision | String | 1970-01-01 |
attribute | Date | units | String | unitless |