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     data   graph     files  public Series 3A: Multiple stressor experiments on T. pseudonana (CCMP1014) - photophysiology
measurements
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The Dataset's Variables and Attributes

Row Type Variable Name Attribute Name Data Type Value
attribute NC_GLOBAL access_formats String .htmlTable,.csv,.json,.mat,.nc,.tsv
attribute NC_GLOBAL acquisition_description String Three CO2 concentrations were tested: 410 ppm, 750 ppm, and 1000 ppm
respectively. For each CO2 concentration, four temperatures were tested: 15
degrees-C, 20 degrees-C, 25 degrees-C, and 30 degrees-C. Within each
temperature, three light levels were tested: a sub-optimum light (SOL)
intensity of 60 umol photons \u00b7 m-2 \u00b7 s-1, an optimum light (OL)
intensity of 400 umol photons \u00b7 m-2 \u00b7 s-1 and an extreme light (EL)
intensity of 800 umol photons \u00b7 m-2 \u00b7 s-1. All lights were set at a
12 h day: 12 h dark cycle. For logistical reasons, experiments were partially
conducted in series, with all light treatments at two temperatures (either 15
degrees-C and 25 degrees-C or 20 degrees-C and 30 degrees-C) running
simultaneously. This was repeated for each CO2 concentration.

Experiments were conducted in Multicultivator MC-1000 OD units (Photon Systems
Instruments, Drasov, Czech Republic). Each unit consists of eight 85 ml test-
tubes immersed in a thermostated water bath, each independently illuminated by
an array of cool white LEDs set at specific intensity and timing. A 0.2um
filtered CO2-air mix (Praxair Distribution Inc.) was bubbled through sterile
artificial seawater, and the humidified gas mix was supplied to each tube via
gentle sparging through a 2um stainless steel diffuser. Flow rates were
gradually increased over the course of the incubation to compensate for the
DIC uptake of actively growing cells, and ranged from <0.04 Liters per minute
(LPM) at the start of the incubations to 0.08 LPM in each tube after 2 days.
For each CO2 and temperature level, replication was achieved by incubating
three tubes at sub-optimum light intensities, two tubes at optimum light
intensity, and three tubes at extreme light intensities. Each experiment was
split into two phases: An acclimation phase spanning 4 days, was used to
acclimate cultures to their new environment. Pre-acclimated, exponentially-
growing cultures were then inoculated into fresh media and incubated through a
3-day experimental phase during which assessments of growth, photophysiology,
and nutrient cycling were carried out daily. All sampling started 5 hours into
the daily light cycle to minimize the effects of diurnal cycles.

Experiments were conducted with artificial seawater (ASW) prepared using
previously described methods (Kester et. al 1967), and enriched with nitrate
(NO3), phosphate (PO4), silicic acid (Si[OH]4), at levels ensuring that the
cultures would remain nutrient-replete over the course of the experiment.
Trace metals and vitamins were added as in f/2 (Guillard 1975). The expected
DIC concentration and pH of the growth media was determined for the different
pCO2 and temperatures using the CO2SYS calculator (Pierrot et al. 2006), with
constants from Mehrbach et al. (1973, refit by Dickson & Millero 1987), and
inputs of temperature, salinity, total alkalinity (2376.5 umol \u00b7 kg-1),
pCO2, phosphate, and silicic acid. DIC levels in ASW at the start of each
phase of the experiments were manipulated by the addition of NaHCO3, and was
then maintained by bubbling a CO2-Air mix through the cultures over the course
of the experiments. The pH of the growth media was measured
spectrophometrically using the m-cresol purple method (Dickson 1993), and
adjusted using 0.1N HCl or 0.1M NaOH. The media was distributed into 75 ml
aliquots and each aliquot was inoculated with 5 ml of the T. pseudonana CCMP
1014 (TP1014) stock culture at the start of the experiments.

Photophysiology:
Photophysiology was assessed daily using a handheld Pulse Amplitude
Modulated (PAM) fluorometer (AquaPen-C AP-C 100, Photon System Instruments,
Czech Republic). A sample was collected from each light treatment for each, 5
hours after the start of the daily light cycle, and placed in the dark for a
minimum of 30 minutes prior to measurements. The dark-adapted sample was used
to generate light curves that provide measurements of in-vivo chlorophyll
autofluorescence (F0), the maximum quantum yield (QYmax or Fv/Fm), and
relative photosynthesis rates based on PSII quantum yields at varying light
intensities - using the instrument\u2019s LC3 protocol. The LC3 protocol
involves measurements of baseline and maximal fluorescence over seven
60-second phases, with each phase representing a light intensity from 10 to
1000 \u03bcmol photons m-2 \u00b7 s-1.\u00a0 Blue light (455 nm) was used as
actinic light in these experiments, and measurements were made at measuring
illumination (f-pulse) intensity of 0.03 \u03bcmol photons m-2 \u00b7 s-1, and
saturating (F-pulse) illumination of 2100\u2009micro-mol photons m-2 \u00b7
s-1, and actinic illumination (A-pulse) controlled by the instrument's
protocol were set at 10, 20, 50, 100, 300, 500, and 1000 micro-mol photons m-2
\u00b7 s-1 (for each 60-second phase).
attribute NC_GLOBAL awards_0_award_nid String 654346
attribute NC_GLOBAL awards_0_award_number String OCE-1538602
attribute NC_GLOBAL awards_0_data_url String http://www.nsf.gov/awardsearch/showAward.do?AwardNumber=1538602 (external link)
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 Series 3A-3: Multiple stressor experiments on T. pseudonana (CCMP1014): photophysiology
PI: U. Passow, N. D'Souza (UCSB), E. Laws (LSU)
version date: 2019-06-17
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/ (external link)
attribute NC_GLOBAL data_source String extract_data_as_tsv version 2.3 19 Dec 2019
attribute NC_GLOBAL dataset_current_state String Final and no updates
attribute NC_GLOBAL date_created String 2019-06-20T13:24:12Z
attribute NC_GLOBAL date_modified String 2020-06-29T19:08:12Z
attribute NC_GLOBAL defaultDataQuery String &amp;time&lt;now
attribute NC_GLOBAL doi String 10.26008/1912/bco-dmo.771461.1
attribute NC_GLOBAL infoUrl String https://www.bco-dmo.org/dataset/771461 (external link)
attribute NC_GLOBAL institution String BCO-DMO
attribute NC_GLOBAL instruments_0_acronym String Fluorometer
attribute NC_GLOBAL instruments_0_dataset_instrument_description String Used for assessment of photochemistry.
attribute NC_GLOBAL instruments_0_dataset_instrument_nid String 771562
attribute NC_GLOBAL instruments_0_description String A fluorometer or fluorimeter is a device used to measure parameters of fluorescence: its intensity and wavelength distribution of emission spectrum after excitation by a certain spectrum of light. The instrument is designed to measure the amount of stimulated electromagnetic radiation produced by pulses of electromagnetic radiation emitted into a water sample or in situ.
attribute NC_GLOBAL instruments_0_instrument_external_identifier String https://vocab.nerc.ac.uk/collection/L05/current/113/ (external link)
attribute NC_GLOBAL instruments_0_instrument_name String Fluorometer
attribute NC_GLOBAL instruments_0_instrument_nid String 484
attribute NC_GLOBAL instruments_0_supplied_name String hand-held Aquapen-C AP-C 100 (Photon Systems Instruments)
attribute NC_GLOBAL instruments_1_acronym String Spectrophotometer
attribute NC_GLOBAL instruments_1_dataset_instrument_description String Used to measure pH.
attribute NC_GLOBAL instruments_1_dataset_instrument_nid String 771470
attribute NC_GLOBAL instruments_1_description String An instrument used to measure the relative absorption of electromagnetic radiation of different wavelengths in the near infra-red, visible and ultraviolet wavebands by samples.
attribute NC_GLOBAL instruments_1_instrument_external_identifier String https://vocab.nerc.ac.uk/collection/L05/current/LAB20/ (external link)
attribute NC_GLOBAL instruments_1_instrument_name String Spectrophotometer
attribute NC_GLOBAL instruments_1_instrument_nid String 707
attribute NC_GLOBAL instruments_1_supplied_name String Genesys 10SVIS spectrophotometer
attribute NC_GLOBAL instruments_2_dataset_instrument_description String Used for incubation of TP1014 cultures.
attribute NC_GLOBAL instruments_2_dataset_instrument_nid String 771469
attribute NC_GLOBAL instruments_2_description String An instrument used for the purpose of culturing small cells such as algae or bacteria. May provide temperature and light control and bubbled gas introduction.
attribute NC_GLOBAL instruments_2_instrument_name String Cell Cultivator
attribute NC_GLOBAL instruments_2_instrument_nid String 714540
attribute NC_GLOBAL instruments_2_supplied_name String Multicultivator MC-1000 OD (Qubit Systems)
attribute NC_GLOBAL keywords String bco, bco-dmo, biological, carbon, carbon dioxide, chemical, co2, CO2_expt, data, dataset, day, dioxide, dmo, erddap, expt, Fm_L1, Fm_L2, Fm_L3, Fm_L4, Fm_L5, Fm_L6, Fm_L7, Ft_L1, Ft_L2, Ft_L3, Ft_L4, Ft_L5, Ft_L6, Ft_L7, irradiance, L2, L3, L4, management, max, oceanography, office, phase, preliminary, QY_L1, QY_L2, QY_L3, QY_L4, QY_L5, QY_L6, QY_L7, QY_max, replicate, temperature
attribute NC_GLOBAL license String https://www.bco-dmo.org/dataset/771461/license (external link)
attribute NC_GLOBAL metadata_source String https://www.bco-dmo.org/api/dataset/771461 (external link)
attribute NC_GLOBAL param_mapping String {'771461': {}}
attribute NC_GLOBAL parameter_source String https://www.bco-dmo.org/mapserver/dataset/771461/parameters (external link)
attribute NC_GLOBAL people_0_affiliation String University of California-Santa Barbara
attribute NC_GLOBAL people_0_affiliation_acronym String UCSB-MSI
attribute NC_GLOBAL people_0_person_name String Uta Passow
attribute NC_GLOBAL people_0_person_nid String 51317
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 Louisiana State University
attribute NC_GLOBAL people_1_affiliation_acronym String LSU-SC&E
attribute NC_GLOBAL people_1_person_name String Dr Edward Laws
attribute NC_GLOBAL people_1_person_nid String 50767
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 California-Santa Barbara
attribute NC_GLOBAL people_2_affiliation_acronym String UCSB-MSI
attribute NC_GLOBAL people_2_person_name String Nigel D'Souza
attribute NC_GLOBAL people_2_person_nid String 748936
attribute NC_GLOBAL people_2_role String Scientist
attribute NC_GLOBAL people_2_role_type String originator
attribute NC_GLOBAL people_3_affiliation String University of California-Santa Barbara
attribute NC_GLOBAL people_3_affiliation_acronym String UCSB-MSI
attribute NC_GLOBAL people_3_person_name String Nigel D'Souza
attribute NC_GLOBAL people_3_person_nid String 748936
attribute NC_GLOBAL people_3_role String Contact
attribute NC_GLOBAL people_3_role_type String related
attribute NC_GLOBAL people_4_affiliation String Woods Hole Oceanographic Institution
attribute NC_GLOBAL people_4_affiliation_acronym String WHOI BCO-DMO
attribute NC_GLOBAL people_4_person_name String Nancy Copley
attribute NC_GLOBAL people_4_person_nid String 50396
attribute NC_GLOBAL people_4_role String BCO-DMO Data Manager
attribute NC_GLOBAL people_4_role_type String related
attribute NC_GLOBAL project String Stressors on Marine Phytoplankton
attribute NC_GLOBAL projects_0_acronym String Stressors on Marine Phytoplankton
attribute NC_GLOBAL projects_0_description String The overarching goal of this project is to develop a framework for understanding the response of phytoplankton to multiple environmental stresses. Marine phytoplankton, which are tiny algae, produce as much oxygen as terrestrial plants and provide food, directly or indirectly, to all marine animals. Their productivity is thus important both for global elemental cycles of oxygen and carbon, as well as for the productivity of the ocean. Globally the productivity of marine phytoplankton appears to be changing, but while we have some understanding of the response of phytoplankton to shifts in one environmental parameter at a time, like temperature, there is very little knowledge of their response to simultaneous changes in several parameters. Increased atmospheric carbon dioxide concentrations result in both ocean acidification and increased surface water temperatures. The latter in turn leads to greater ocean stratification and associated changes in light exposure and nutrient availability for the plankton. Recently it has become apparent that the response of phytoplankton to simultaneous changes in these growth parameters is not additive. For example, the effect of ocean acidification may be severe at one temperature-light combination and negligible at another. The researchers of this project will carry out experiments that will provide a theoretical understanding of the relevant interactions so that the impact of climate change on marine phytoplankton can be predicted in an informed way. This project will engage high schools students through training of a teacher and the development of a teaching unit. Undergraduate and graduate students will work directly on the research. A cartoon journalist will create a cartoon story on the research results to translate the findings to a broader general public audience.
Each phytoplankton species has the capability to acclimatize to changes in temperature, light, pCO2, and nutrient availability - at least within a finite range. However, the response of phytoplankton to multiple simultaneous stressors is frequently complex, because the effects on physiological responses are interactive. To date, no datasets exist for even a single species that could fully test the assumptions and implications of existing models of phytoplankton acclimation to multiple environmental stressors. The investigators will combine modeling analysis with laboratory experiments to investigate the combined influences of changes in pCO2, temperature, light, and nitrate availability on phytoplankton growth using cultures of open ocean and coastal diatom strains (Thalassiosira pseudonana) and an open ocean cyanobacteria species (Synechococcus sp.). The planned experiments represent ideal case studies of the complex and interactive effects of environmental conditions on organisms, and results will provide the basis for predictive modeling of the response of phytoplankton taxa to multiple environmental stresses.
attribute NC_GLOBAL projects_0_end_date String 2018-09
attribute NC_GLOBAL projects_0_name String Collaborative Research: Effects of multiple stressors on Marine Phytoplankton
attribute NC_GLOBAL projects_0_project_nid String 654347
attribute NC_GLOBAL projects_0_start_date String 2015-10
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 The experiments were designed to test the combined effects of CO2, temperatures, and light on the growth of the diatom T. pseudonana CCMP1014 in a multifactorial design. This dataset contains measurements of photophysiology using the Light curve (LC3) protocol of the Aquapen-C AP-C 100 fluorometer.
attribute NC_GLOBAL title String Series 3A: Multiple stressor experiments on T. pseudonana (CCMP1014) - photophysiology measurements
attribute NC_GLOBAL version String 1
attribute NC_GLOBAL xml_source String osprey2erddap.update_xml() v1.5
variable CO2_expt   short  
attribute CO2_expt _FillValue short 32767
attribute CO2_expt actual_range short 410, 1000
attribute CO2_expt bcodmo_name String brief_desc
attribute CO2_expt description String Indicates the experiment CO2 level: 410/750/1000 ppm
attribute CO2_expt long_name String CO2 Expt
attribute CO2_expt units String unitless
variable Phase   String  
attribute Phase bcodmo_name String sample_descrip
attribute Phase description String Indicates whether the sample was collected during the acclimation phase or the experiment phase of the experiment.
attribute Phase long_name String Phase
attribute Phase units String unitless
variable CO2   short  
attribute CO2 _FillValue short 32767
attribute CO2 actual_range short 410, 1000
attribute CO2 bcodmo_name String pCO2
attribute CO2 description String Indicates the concentration of CO2 in the CO2-Air mix that was bubbled through the samples over the course of the experiment
attribute CO2 long_name String CO2
attribute CO2 nerc_identifier String https://vocab.nerc.ac.uk/collection/P01/current/PCO2C101/ (external link)
attribute CO2 units String parts per million (ppm)
variable Temperature   String  
attribute Temperature bcodmo_name String temperature
attribute Temperature description String Indicates the temperature at which the samples were incubated.
attribute Temperature long_name String Temperature
attribute Temperature nerc_identifier String https://vocab.nerc.ac.uk/collection/P01/current/TEMPP901/ (external link)
attribute Temperature units String degrees Celsius
variable Day   String  
attribute Day bcodmo_name String days
attribute Day description String Indicates the timepoint (day) of sampling. D0 = day 0; D1 = day 1; etc.
attribute Day long_name String Day
attribute Day units String unitless
variable Replicate   byte  
attribute Replicate _FillValue byte 127
attribute Replicate actual_range byte 1, 3
attribute Replicate bcodmo_name String replicate
attribute Replicate description String Indicates replication within a treatment. "NA" indicates "not applicable"
attribute Replicate long_name String Replicate
attribute Replicate units String unitless
variable Irradiance   String  
attribute Irradiance bcodmo_name String treatment
attribute Irradiance description String Irradiance level: SOL = sub-optimum light; OL = optimum light; EL = extreme light
attribute Irradiance long_name String Irradiance
attribute Irradiance units String unitless
variable Fo   short  
attribute Fo _FillValue short 32767
attribute Fo actual_range short 95, 23180
attribute Fo bcodmo_name String fluorescence
attribute Fo description String minimum fluorescence in dark-adapted state.
attribute Fo long_name String Fo
attribute Fo nerc_identifier String https://vocab.nerc.ac.uk/collection/P01/current/CPHLPM01/ (external link)
attribute Fo units String RFU (Relative Fluorscence Units)
variable Fm   int  
attribute Fm _FillValue int 2147483647
attribute Fm actual_range int 124, 67785
attribute Fm bcodmo_name String fluorescence
attribute Fm description String the maximum fluorescence in dark-adapted state; measured during the first saturation flash after dark adaptation
attribute Fm long_name String FM
attribute Fm nerc_identifier String https://vocab.nerc.ac.uk/collection/P01/current/CPHLPM01/ (external link)
attribute Fm units String RFU (Relative Fluorscence Units)
variable Fm_L1   int  
attribute Fm_L1 _FillValue int 2147483647
attribute Fm_L1 actual_range int 121, 67753
attribute Fm_L1 bcodmo_name String fluorescence
attribute Fm_L1 description String The first measurement of the maximum fluorescence following exposure to actinic light at 10 micro-mol photons·m-2·sec-1 for 60 seconds (L1 indicates the first measurement in the "light" phase)
attribute Fm_L1 long_name String FM L1
attribute Fm_L1 nerc_identifier String https://vocab.nerc.ac.uk/collection/P01/current/CPHLPM01/ (external link)
attribute Fm_L1 units String RFU (Relative Fluorscence Units)
variable Fm_L2   int  
attribute Fm_L2 _FillValue int 2147483647
attribute Fm_L2 actual_range int 125, 69931
attribute Fm_L2 bcodmo_name String fluorescence
attribute Fm_L2 description String The second measurement of the maximum fluorescence following exposure to actinic light at 20 micro-mol photons·m-2·sec-1 for 60 seconds (L1 indicates the first measurement in the "light" phase)
attribute Fm_L2 long_name String FM L2
attribute Fm_L2 nerc_identifier String https://vocab.nerc.ac.uk/collection/P01/current/CPHLPM01/ (external link)
attribute Fm_L2 units String RFU (Relative Fluorscence Units)
variable Fm_L3   int  
attribute Fm_L3 _FillValue int 2147483647
attribute Fm_L3 actual_range int 89, 71719
attribute Fm_L3 bcodmo_name String fluorescence
attribute Fm_L3 description String The third measurement of the maximum fluorescence following exposure to actinic light at 50 micro-mol photons·m-2·sec-1 for 60 seconds (L1 indicates the first measurement in the "light" phase)
attribute Fm_L3 long_name String FM L3
attribute Fm_L3 nerc_identifier String https://vocab.nerc.ac.uk/collection/P01/current/CPHLPM01/ (external link)
attribute Fm_L3 units String RFU (Relative Fluorscence Units)
variable Fm_L4   int  
attribute Fm_L4 _FillValue int 2147483647
attribute Fm_L4 actual_range int 83, 73475
attribute Fm_L4 bcodmo_name String fluorescence
attribute Fm_L4 description String The fourth measurement of the maximum fluorescence following exposure to actinic light at 100 micro-mol photons·m-2·sec-1 for 60 seconds (L1 indicates the first measurement in the "light" phase)
attribute Fm_L4 long_name String FM L4
attribute Fm_L4 nerc_identifier String https://vocab.nerc.ac.uk/collection/P01/current/CPHLPM01/ (external link)
attribute Fm_L4 units String RFU (Relative Fluorscence Units)
variable Fm_L5   int  
attribute Fm_L5 _FillValue int 2147483647
attribute Fm_L5 actual_range int -306, 56017
attribute Fm_L5 bcodmo_name String fluorescence
attribute Fm_L5 description String The fifth measurement of the maximum fluorescence following exposure to actinic light at 300 micro-mol photons·m-2·sec-1 for 60 seconds (L1 indicates the first measurement in the "light" phase)
attribute Fm_L5 long_name String FM L5
attribute Fm_L5 nerc_identifier String https://vocab.nerc.ac.uk/collection/P01/current/CPHLPM01/ (external link)
attribute Fm_L5 units String RFU (Relative Fluorscence Units)
variable Fm_L6   int  
attribute Fm_L6 _FillValue int 2147483647
attribute Fm_L6 actual_range int -424, 39501
attribute Fm_L6 bcodmo_name String fluorescence
attribute Fm_L6 description String The sixth measurement of the maximum fluorescence following exposure to actinic light at 500 micro-mol photons·m-2·sec-1 for 60 seconds (L1 indicates the first measurement in the "light" phase)
attribute Fm_L6 long_name String FM L6
attribute Fm_L6 nerc_identifier String https://vocab.nerc.ac.uk/collection/P01/current/CPHLPM01/ (external link)
attribute Fm_L6 units String RFU (Relative Fluorscence Units)
variable Fm_L7   short  
attribute Fm_L7 _FillValue short 32767
attribute Fm_L7 actual_range short -124, 27504
attribute Fm_L7 bcodmo_name String fluorescence
attribute Fm_L7 description String The seventh measurement of the maximum fluorescence following exposure to actinic light at 1000 micro-mol photons·m-2·sec-1 for 60 seconds (L1 indicates the first measurement in the "light" phase)
attribute Fm_L7 long_name String FM L7
attribute Fm_L7 nerc_identifier String https://vocab.nerc.ac.uk/collection/P01/current/CPHLPM01/ (external link)
attribute Fm_L7 units String RFU (Relative Fluorscence Units)
variable Ft_L1   short  
attribute Ft_L1 _FillValue short 32767
attribute Ft_L1 actual_range short 115, 31243
attribute Ft_L1 bcodmo_name String fluorescence
attribute Ft_L1 description String The first measurement of the maximum fluorescence following exposure to actinic light at 10 micro-mol photons·m-2·sec-1 for 60 seconds (L1 indicates the first measurement in the "light" phase)
attribute Ft_L1 long_name String FT L1
attribute Ft_L1 nerc_identifier String https://vocab.nerc.ac.uk/collection/P01/current/CPHLPM01/ (external link)
attribute Ft_L1 units String RFU (Relative Fluorscence Units)
variable Ft_L2   short  
attribute Ft_L2 _FillValue short 32767
attribute Ft_L2 actual_range short 114, 31795
attribute Ft_L2 bcodmo_name String fluorescence
attribute Ft_L2 description String The second measurement of the maximum fluorescence following exposure to actinic light at 20 micro-mol photons·m-2·sec-1 for 60 seconds (L1 indicates the first measurement in the "light" phase)
attribute Ft_L2 long_name String FT L2
attribute Ft_L2 nerc_identifier String https://vocab.nerc.ac.uk/collection/P01/current/CPHLPM01/ (external link)
attribute Ft_L2 units String RFU (Relative Fluorscence Units)
variable Ft_L3   int  
attribute Ft_L3 _FillValue int 2147483647
attribute Ft_L3 actual_range int 133, 34266
attribute Ft_L3 bcodmo_name String fluorescence
attribute Ft_L3 description String The third measurement of the maximum fluorescence following exposure to actinic light at 50 micro-mol photons·m-2·sec-1 for 60 seconds (L1 indicates the first measurement in the "light" phase)
attribute Ft_L3 long_name String FT L3
attribute Ft_L3 nerc_identifier String https://vocab.nerc.ac.uk/collection/P01/current/CPHLPM01/ (external link)
attribute Ft_L3 units String RFU (Relative Fluorscence Units)
variable Ft_L4   int  
attribute Ft_L4 _FillValue int 2147483647
attribute Ft_L4 actual_range int 134, 37225
attribute Ft_L4 bcodmo_name String fluorescence
attribute Ft_L4 description String The fourth measurement of the maximum fluorescence following exposure to actinic light at 100 micro-mol photons·m-2·sec-1 for 60 seconds (L1 indicates the first measurement in the "light" phase)
attribute Ft_L4 long_name String FT L4
attribute Ft_L4 nerc_identifier String https://vocab.nerc.ac.uk/collection/P01/current/CPHLPM01/ (external link)
attribute Ft_L4 units String RFU (Relative Fluorscence Units)
variable Ft_L5   int  
attribute Ft_L5 _FillValue int 2147483647
attribute Ft_L5 actual_range int 139, 38038
attribute Ft_L5 bcodmo_name String fluorescence
attribute Ft_L5 description String The fifth measurement of the maximum fluorescence following exposure to actinic light at 300 micro-mol photons·m-2·sec-1 for 60 seconds (L1 indicates the first measurement in the "light" phase)
attribute Ft_L5 long_name String FT L5
attribute Ft_L5 nerc_identifier String https://vocab.nerc.ac.uk/collection/P01/current/CPHLPM01/ (external link)
attribute Ft_L5 units String RFU (Relative Fluorscence Units)
variable Ft_L6   short  
attribute Ft_L6 _FillValue short 32767
attribute Ft_L6 actual_range short 125, 31015
attribute Ft_L6 bcodmo_name String fluorescence
attribute Ft_L6 description String The sixth measurement of the maximum fluorescence following exposure to actinic light at 500 micro-mol photons·m-2·sec-1 for 60 seconds (L1 indicates the first measurement in the "light" phase)
attribute Ft_L6 long_name String FT L6
attribute Ft_L6 nerc_identifier String https://vocab.nerc.ac.uk/collection/P01/current/CPHLPM01/ (external link)
attribute Ft_L6 units String RFU (Relative Fluorscence Units)
variable Ft_L7   short  
attribute Ft_L7 _FillValue short 32767
attribute Ft_L7 actual_range short 127, 24350
attribute Ft_L7 bcodmo_name String fluorescence
attribute Ft_L7 description String The seventh measurement of the maximum fluorescence following exposure to actinic light at 1000 micro-mol photons·m-2·sec-1 for 60 seconds (L1 indicates the first measurement in the "light" phase)
attribute Ft_L7 long_name String FT L7
attribute Ft_L7 nerc_identifier String https://vocab.nerc.ac.uk/collection/P01/current/CPHLPM01/ (external link)
attribute Ft_L7 units String RFU (Relative Fluorscence Units)
variable QY_max   float  
attribute QY_max _FillValue float NaN
attribute QY_max actual_range float -2.02, 0.74
attribute QY_max bcodmo_name String Fv2Fm
attribute QY_max description String The maximum Quantum yield. A measure of the Photosystem II efficiency. In a dark-adapted sample this is equivalent to Fv/Fm. In a light-adapted sample it is equivalent to Fv’/Fm’.
attribute QY_max long_name String QY Max
attribute QY_max units String unitless
variable QY_L1   float  
attribute QY_L1 _FillValue float NaN
attribute QY_L1 actual_range float -4.72, 0.62
attribute QY_L1 bcodmo_name String Fv2Fm
attribute QY_L1 description String The first measurement of the instantenous photosystem II quantum yield following exposure to actinic light at 10 micro-mol photons·m-2·sec-1 for 60 seconds (L1 indicates the first measurement in the "light" phase)
attribute QY_L1 long_name String QY L1
attribute QY_L1 units String unitless
variable QY_L2   float  
attribute QY_L2 _FillValue float NaN
attribute QY_L2 actual_range float -4.34, 0.62
attribute QY_L2 bcodmo_name String Fv2Fm
attribute QY_L2 description String The second measurement of the instantenous photosystem II quantum yield following exposure to actinic light at 20 micro-mol photons·m-2·sec-1 for 60 seconds (L1 indicates the first measurement in the "light" phase)
attribute QY_L2 long_name String QY L2
attribute QY_L2 units String unitless
variable QY_L3   float  
attribute QY_L3 _FillValue float NaN
attribute QY_L3 actual_range float -6.46, 0.58
attribute QY_L3 bcodmo_name String Fv2Fm
attribute QY_L3 description String The third measurement of the instantenous photosystem II quantum yield following exposure to actinic light at 50 micro-mol photons·m-2·sec-1 for 60 seconds (L1 indicates the first measurement in the "light" phase)
attribute QY_L3 long_name String QY L3
attribute QY_L3 units String unitless
variable QY_L4   float  
attribute QY_L4 _FillValue float NaN
attribute QY_L4 actual_range float -7.19, 0.54
attribute QY_L4 bcodmo_name String Fv2Fm
attribute QY_L4 description String The fourth measurement of the instantenous photosystem II quantum yield following exposure to actinic light at 100 micro-mol photons·m-2·sec-1 for 60 seconds (L1 indicates the first measurement in the "light" phase)
attribute QY_L4 long_name String QY L4
attribute QY_L4 units String unitless
variable QY_L5   float  
attribute QY_L5 _FillValue float NaN
attribute QY_L5 actual_range float 0.05, 4.4
attribute QY_L5 bcodmo_name String Fv2Fm
attribute QY_L5 description String The fifth measurement of the instantenous photosystem II quantum yield following exposure to actinic light at 300 micro-mol photons·m-2·sec-1 for 60 seconds (L1 indicates the first measurement in the "light" phase)
attribute QY_L5 long_name String QY L5
attribute QY_L5 units String unitless
variable QY_L6   float  
attribute QY_L6 _FillValue float NaN
attribute QY_L6 actual_range float 0.07, 3.37
attribute QY_L6 bcodmo_name String Fv2Fm
attribute QY_L6 description String The sixth measurement of the instantenous photosystem II quantum yield following exposure to actinic light at 500 micro-mol photons·m-2·sec-1 for 60 seconds (L1 indicates the first measurement in the "light" phase)
attribute QY_L6 long_name String QY L6
attribute QY_L6 units String unitless
variable QY_L7   float  
attribute QY_L7 _FillValue float NaN
attribute QY_L7 actual_range float -0.07, 6.0
attribute QY_L7 bcodmo_name String Fv2Fm
attribute QY_L7 description String The seventh measurement of the instantenous photosystem II quantum yield following exposure to actinic light at 1000 micro-mol photons·m-2·sec-1 for 60 seconds (L1 indicates the first measurement in the "light" phase)
attribute QY_L7 long_name String QY L7
attribute QY_L7 units String unitless

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.


 
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