Dataset: Rosette Samples - HRS1415
Deployment: HRS1415

CTD data and analyses of bottles from CTD rosette samples collected on HRS1415

Principal Investigator:

George W. Luther (University of Delaware)

Co-Principal Investigator:

Bradley M. Tebo (Oregon Health & Science University, IEH/OHSU)

BCO-DMO Data Manager:

Shannon Rauch (Woods Hole Oceanographic Institution, WHOI BCO-DMO)

Project:

The role of soluble Mn(III) in the biogeochemical coupling of the Mn, Fe and sulfur cycles (Soluble ManganeseIII)

Current State:

Final no updates expected

Version:

24 Oct 2017

Deployment Synonyms:

140818GL

Version Date:

2017-10-24

Data URL:

https://www.bco-dmo.org/dataset-deployment/717759/data

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Description

CTD data and analyses of bottles from CTD rosette samples collected on cruise HRS1415.

Field Papers published as a result of this project (methods included):
Madison, A. S, B. M. Tebo, A. Mucci, B. Sundby and G. W. Luther, III. 2013. Abundant Mn(III) in porewaters is a major component of the sedimentary redox system. Science 341, 875-878. http://dx.doi.org/10.1126/science.1241396

MacDonald, D. J., A. J. Findlay, S. M. McAllister, J. M. Barnett, P. Hredzak-Showalter, S. T. Krepski, S. G. Cone, J. Scott, S. K. Bennett, C. S. Chan, D. Emerson and G.W. Luther III. 2014. Using in situ voltammetry as a tool to search for iron oxidizing bacteria: from fresh water wetlands to hydrothermal vent sites. Environmental Science: Processes & Impacts 16, 2117-2126. http://dx.DOI.org/10.1039/c4em00073k

Findlay, A. J., A. Gartman, D. J. MacDonald, T. E. Hanson, T. J. Shaw and G. W. Luther, III. 2014. Distribution and size fractionation of elemental sulfur in aqueous environments: The Chesapeake Bay and Mid-Atlantic Ridge. Geochimica Cosmochimica Acta 142, 334-348. http://dx.doi.org/10.1016/j.gca.2014.07.032

Oldham, V. O., S. M. Owings, M. Jones, B. M. Tebo and G. W. Luther, III. 2015. Evidence for the presence of strong Mn(III)-binding ligands in the water column of the Chesapeake Bay. Marine Chemistry 171, 58-66. http://dx.doi.org/10.1016/j.marchem.2015.02.008

Luther, G.W. III, A.S. Madison, A. Mucci, B. Sundby and V. E. Oldham. 2015. A kinetic approach to assess the strengths of ligands bound to soluble Mn(III). Marine Chemistry 173, 93-99. http://dx.doi.org/10.1016/j.marchem.2014.09.006

Findlay, A. J., A. J. Bennet, T. E. Hanson and G. W. Luther, III. 2015. Light-dependent sulfide oxidation in the anoxic zone of the Chesapeake Bay can be explained by small populations of phototrophic bacteria. Applied and Environmental Microbiology 81(21), 7560-7569. http://dx.doi.org/10.1128/AEM.02062-15

Olson, L. K. A Quinn, M. G. Siebecker, G.W. Luther III, D. Hastings and J. Morford. 2017. Trace metal diagenesis in sulfidic sediments: Insights from Chesapeake Bay. Chemical Geology 452, 47-59. http://dx.doi.org/10.1016/j.chemgeo.2017.01.018

Oldham, V. O., M. T. Miller, Laramie T. Jensen and G.W. Luther III. 2017. Revisiting Mn and Fe removal in humic rich estuaries. Geochimica Cosmochimica Acta 209, 267-283. http://dx.doi.org/10.1016/j.gca.2017.04.001

Cai, W.-J, W.-J. Huang, G. Luther, III, D. Pierrot, M. Li, J. Testa, M. Xue, A. Joesoef, R. Mann, J. Brodeur, Y-Y Xu, B. Chen, N. Hussain, G. G. Waldbusser, J. Cornwell, and W. M. Kemp. 2017. Redox reactions and weak buffer capacity lead to acidification in the Chesapeake Bay. Nature Communications 8, Article number: 369. http://dx.doi.org/10.1038/s41467-017-00417-7

Findlay, A. J., D. M. Di Toro and G. W. Luther, III. 2017. A model of phototrophic sulfide oxidation in a stratified estuary. Limnology & Oceanography 62, 1853-1867. http://dx.doi.org/10.1002/lno.10539

Oldham, V. O., M. R. Jones, B. M. Tebo and G.W. Luther III. 2017. Oxidative and reductive processes contributing to manganese cycling at oxic-anoxic interfaces. Marine Chemistry, in press.

Methods & Sampling

Dataset acquisition description

Description/methods for parameters measured:
C parameters performed by Dr. Wei-Jun Cai’s group for:
TA - Open cell Gran titration with semi-automatic AS-ALK2 Apollo Scitech titrator;
pH - glass electrode, NBS buffers;
DIC - infrared CO2 analyzer (AS-C3, Apollo Scitech).
Use Dickson CRM for calibration. DIC/TA samples were filtered (0.45um) and fixed with 100 ul of saturated mercury bichloride.
Use the methods of Gran (1952) and Huang, et al. (2012).

Fe parameters:
The method of Stookey (1972) is used to determine dissolved Fe(II) and on addition if hydroxylamine Fe total. Fe(III) is determined by difference. Modified and calibrated by many including Lewis et al (2007) and MacDonald et al (2014). Typically, triplicate measurements performed.

Dissolved Mn parameters:
The porphyrin spectrophotometric method of Madison et al (2011) measures dissolved Mn(II), Mn(III) bound to weaker ligands and total Mn. Method includes calibration and intercomparison of totals with other instrumentation (ICP, AA). Detection limit is 0.050 micromolar. Detection limit (DL) is 50 micromolar with a 1 cm path length cell.

Modification of Madison for Mn(III) bound to strong ligands by adding a reducing agent to a separate subsample with the porphyrin to obtain total Mn. Mn(III) bound to strong ligand complexes is determined by difference. Typically, triplicate measurements performed. Detection limit is 3.0 nanomolar.

MnOx on unfiltered samples:
The leucoberbelein blue method is that of Altmann (1972) and Krumblein and Altmann (1973) in 1 cm cells, but can be modified for longer path length cells.

S parameters:
O2, H2S and polysulfides by the voltammetry method of Luther et al (2008).
A flow cell was also used to collect in situ O2 and H2S data as well as some additional samples. Analysis by voltammetry (Luther et al, 2008).
Solid and nanoparticulate S8 (Yücel et al 2010 and Findlay et al 2014).
Typically, triplicate measurements performed.

Methods papers used in this project:
Dissolved Mn speciation parameters:
Madison, A., B. M. Tebo, G. W. Luther, III. 2011. Simultaneous determination of soluble manganese(III), manganese(II) and total manganese in natural (pore)waters. Talanta 84, 374-381. http://dx.doi.org/10.1016/j.talanta.2011.01.025

Madison, A. S, B. M. Tebo, A. Mucci, B. Sundby and G. W. Luther, III. 2013. Abundant Mn(III) in porewaters is a major component of the sedimentary redox system. Science 341, 875-878. http://dx.doi.org/10.1126/science.1241396

Oldham, V. O., A. Mucci, B. M. Tebo and G.W. Luther III. 2017. Soluble Mn(III)-L complexes are ubiquitous in oxygenated waters and stabilized by humic ligands. Geochimica Cosmochimica Acta 199, 238-246. http://dx.doi.org/10.1016/j.gca.2016.11.043
[[ Here, we modified the method of Madison et al. (2011) for water column samples to achieve a detection limit of 3.0 nM (3 times the standard deviation of a blank) by using a 100-cm liquid waveguide capillary cell and the addition of a heating step as well as a strong reducing agent for Mn Speciation [Mn3+ = MnT – Mn2+]. See Table 1 in this paper for recovery tests. As weak Mn(III)-L complexes could not be measured in our previous work (Oldham et al, 2015; paper above), this method was used throughout this cruise. ]]

MnOX solids:
Altmann, H.H., 1972. Bestimmung von inWasser gelöstem Sauerstoffmit Leukoberbelinblau I. Fresenius' Z. Anal. Chem. 6, 97–99.

Krumbein, W. E., and H. J. Altmann. 1973. ‘A New Method for the Detection and Enumeration of Manganese Oxidizing and Reducing Microorganisms’. Helgoländer Wissenschaftliche Meeresuntersuchungen 25 (2-3): 347–56. doi:10.1007/BF01611203.

Dissolved Fe speciation parameters:
Stookey L.L. 1970. Ferrozine- A New Spectrophotometric Reagent for Iron. Anal. Chem. 42, 779-781.

Lewis, B. L., B. T. Glazer, P. J. Montbriand, G. W. Luther, III, D. B. Nuzzio, T. Deering, S. Ma, and S. Theberge. 2007. Short-term and interannual variability of redox-sensitive chemical parameters in hypoxic/anoxic bottom waters of the Chesapeake Bay. Marine Chemistry 105, 296-308.

O2 and H2S, polysulfides:
Luther, III, G. W., B. T. Glazer, S. Ma, R. E. Trouwborst, T. S. Moore, E. Metzger, C. Kraiya, T. J. Waite, G. Druschel, B. Sundby, M. Taillefert, D. B. Nuzzio, T. M. Shank, B. L. Lewis and P. J. Brendel. 2008. Use of voltammetric solid-state (micro)electrodes for studying biogeochemical processes: laboratory measurements to real time measurements with an in situ electrochemical analyzer (ISEA). Marine Chemistry 108, 221-235. http://dx.doi.org/10.1016/j.marchem.2007.03.002

Luther, G. W., III, and A. S. Madison. 2013. Determination of Dissolved Oxygen, Hydrogen Sulfide, Iron(II), and Manganese(II) in Wetland Pore Waters. In: Methods in Biogeochemistry of Wetlands, R.D. DeLaune, K.R. Reddy, C.J. Richardson, and J.P. Megonigal, editors. SSSA Book Series, no. 10. SSSA, Madison, WI. p. 87-106. http://dx.doi.org/10.2136/sssabookser10.c6

S8:
Yücel, M., S. K. Konovalov, T. S. Moore, C. P. Janzen and G. W. Luther, III. 2010. Sulfur speciation in the upper Black Sea sediments. Chemical Geology 269, 364-375. http://dx.doi.org/10.1016/j.chemgeo.2009.10.010

pH and inorganic carbon parameters:
Gran G. 1952. Determination of the equivalence point in potentiometric titrations, Part II. Analyst, 77: 661-671.

Huang W.-J., Wang Y., and Cai W.-J. 2012. Assessment of sample storage techniques for total alkalinity and dissolved inorganic carbon in seawater. Limnology and Oceanography: Methods, 10: 711-717.

Data Processing Description

Dataset Processing Description

BCO-DMO Processing:
- added columns for cast, station, and description (were contained as headers/rows);
- modified parameter names to conform with BCO-DMO naming conventions;
- replaced blanks/missing data with "nd" ("no data");
- replaced "#N/A" with "NA";
- replaced "ND" (in all caps) with "not_detected";
- coverted lat and lon from degrees and decimal minutes to decimal degrees;
- added date-time in ISO8601 format using original date and time_GMT fields;
- 06 Nov 2017: corrected station number for cast 6 (change from 6 to 5) per PI.

More information about this dataset deployment

Funding

Award Number	Funding Source
OCE-1155385	NSF Division of Ocean Sciences

Instruments

Automatic titrator

Supplied Name: AS-ALK2 Apollo Scitech titrator

Supplied Description:

Instrument Type

Generic Name: Automatic titrator

Community Identifier: http://vocab.nerc.ac.uk/collection/L05/current/LAB12/

Generic Description:

Instruments that incrementally add quantified aliquots of a reagent to a sample until the end-point of a chemical reaction is reached.

CO2 Analyzer

Supplied Name: AS-C3, Apollo Scitech infrared CO2 analyzer

Supplied Description:

Instrument Type

Generic Name: CO2 Analyzer

Community Identifier: http://vocab.nerc.ac.uk/collection/L05/current/382/

Generic Description:

Measures atmospheric carbon dioxide (CO2) concentration.

CTD Sea-Bird

Supplied Name:

Supplied Description:

Samples were collected using R/V Sharp's Sea-Bird CTD.

Instrument Type

Generic Name: CTD Sea-Bird

Community Identifier: http://vocab.nerc.ac.uk/collection/L05/current/130/

Generic Description:

Conductivity, Temperature, Depth (CTD) sensor package from SeaBird Electronics, no specific unit identified. This instrument designation is used when specific make and model are not known. See also other SeaBird instruments listed under CTD. More information from Sea-Bird Electronics.

CTD-fluorometer

Supplied Name:

Supplied Description:

R/V Sharp's CTD fluorometer

Instrument Type

Generic Name: CTD-fluorometer

Community Identifier: http://vocab.nerc.ac.uk/collection/L05/current/113/

Generic Description:

A CTD-fluorometer is an instrument package designed to measure hydrographic information (pressure, temperature and conductivity) and chlorophyll fluorescence.

Niskin bottle

Supplied Name:

Supplied Description:

Instrument Type

Generic Name: Niskin bottle

Community Identifier: http://vocab.nerc.ac.uk/collection/L22/current/TOOL0412/

Generic Description:

A Niskin bottle (a next generation water sampler based on the Nansen bottle) is a cylindrical, non-metallic water collection device with stoppers at both ends. The bottles can be attached individually on a hydrowire or deployed in 12, 24, or 36 bottle Rosette systems mounted on a frame and combined with a CTD. Niskin bottles are used to collect discrete water samples for a range of measurements including pigments, nutrients, plankton, etc.

Oxygen Sensor

Supplied Name:

Supplied Description:

O2 sensor equipped on R/V Sharp's CTD rosette

Instrument Type

Generic Name: Oxygen Sensor

Acronym: Dissolved Oxygen Sensor

Generic Description:

An electronic device that measures the proportion of oxygen (O2) in the gas or liquid being analyzed

Parameters

Supplied Name	Supplied description	Supplied Units	Standard Name
Cast	Cast identifier	unitless	cast
Station	Station identifier	unitless	station
lat	Latitude; positive values = North	decimal degrees	lat
lon	Longitude; positive values = East	decimal degrees	lon
date	Date of sampling formatted as m/dd/yyyy	unitless	date
Description	Description and/or notes related to the sampling location or event	unitless	comment
Bottle_Num	Bottle number	unitless	bottle
time_local	Time of sampling (local time zone) formatted as HH:MM	unitless	time
time_GMT	Time of sampling (GMT) formatted as HH:MM	unitless	time
depth	Sample depth	meters (m)	depth
temp	Water temperature	degrees Celsius	temp
sal	Salinity	unitless	sal
CTD_O2	Oxygen measured by CTD	micromolar (uM)	O2
O2_sat_100pcnt	100% oxygen saturation	micromolar (uM)	O2sat
O2_sat	Percent oxygen saturation	unitless (percent)	O2_sat_pcnt
fluor_chla	Chlorophyll fluorescence. Reported in voltage (from the RV Sharp fluorometer sensor).	volts	flvolt
TA	Total alkalinity mesaured by open cell Gran titration with semi-automatic AS-ALK2 Apollo Scitech titrator	microles per kilogram (uM/kg)	TALK
DIC	Dissolved inorganic carbon measured by infrared CO2 analyzer (AS-C3, Apollo Scitech)	microles per kilogram (uM/kg)	DIC
pH	pH (primary) measured by glass electrode, NBS buffers	unitless (pH scale)	pH
Particulate_MnOx	Particulate Manganese oxide (MnOx). DL= 0.01 uM or 10 nM.	micromolar (uM)	no_bcodmo_term
Particulate_MnOx_stdev	Standard deviation of Particulate Manganese oxide	micromolar (uM)	no_bcodmo_term
Dissolved_Mn2plus	Dissolved Mn2+	micromolar (uM)	Mn
Dissolved_Mn2plus_stdev	Standard deviation of dissolved Mn2+	micromolar (uM)	Mn
Dissolved_Mn3plus	Dissolved Mn3+ where Mn3+ = [MnT - Mn2+]	micromolar (uM)	Mn
Dissolved_Mn3plus_stdev	Standard deviation of dissolved Mn3+	micromolar (uM)	Mn
Dissolved_MnT	Dissolved MnT	micromolar (uM)	Mn
Dissolved_MnT_stdev	Standard deviation of dissolved MnT	micromolar (uM)	Mn
Dissolved_sulfide	Dissolved sulfide	micromolar (uM)	sulfide
Dissolved_filtered_Fe2plus	Dissolved filtered Fe2+. DL for Fe is 0.100 micromolar.	micromolar (uM)	Fe
Dissolved_filtered_Fe2plus_stdev	Standard deviation of dissolved filtered Fe2+	micromolar (uM)	Fe
Particulate_unfiltered_Fe2plus	Particulate unfiltered Fe2+	micromolar (uM)	Fe
Particulate_unfiltered_Fe2plus_stdev	Standard deviation of particulate unfiltered Fe2+	micromolar (uM)	Fe
Dissolved_filtered_Fe3plus	Dissolved filtered Fe3+	micromolar (uM)	Fe
Dissolved_filtered_Fe3plus_stdev	Standard deviation of dissolved filtered Fe3+	micromolar (uM)	Fe
Particulate_unfiltered_Fe3plus	Particulate unfiltered Fe3+	micromolar (uM)	Fe
Particulate_unfiltered_Fe3plus_stdev	Standard deviation of particulate unfiltered Fe3+	micromolar (uM)	Fe
pH_secondary	pH (secondary) measured by glass electrode, NBS buffers	unitless (pH scale)	pH
nanoparticulate_S0	Nanoparticulate S(0) (<0.2um).	micromolar (uM)	sulfide
ISO_DateTime_UTC	Date and time of sampling formatted to ISO8601 standard (yyyy-mm-ddTHH:MM); constructed using original date and time_GMT fields.	yyyy-MM-dd'T'HH:mm:ss.SS	ISO_DateTime_UTC

Database

Contribute Data

Dataset: Rosette Samples - HRS1415
Deployment: HRS1415

Dataset acquisition description

Dataset Processing Description

Database

Contribute Data

Dataset: Rosette Samples - HRS1415Deployment: HRS1415

Dataset acquisition description

Dataset Processing Description

Dataset: Rosette Samples - HRS1415
Deployment: HRS1415