Sediment nutrient fluxes, denitrification rates and sediment characteristics in Long Island Sound, NY

We collected sediment cores at five stations in Long Island Sound along a west to east transect to capture a range of environmental conditions within the estuary. We measured sediment fluxes of dissolved inorganic nutrients and dissolved gases at Execution Rocks (EXR), Western Long Island Sound (WLI...

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Main Authors: Mazur, Claudia, Fulweiler, Robinson W., Al-Haj, Alia, Ray, Nicholas, Sanchez-Viruet, Isabel
Format: Dataset
Language:unknown
Published: figshare 2021
Subjects:
Environmental Chemistry
Geochemistry
FOS Earth and related environmental sciences
Oceanography
Avery
Long Island
Long Island Sound
Petty
Underwood
National Environmental Research Institute
Online Access:https://dx.doi.org/10.6084/m9.figshare.13022843.v2
https://figshare.com/articles/dataset/Sediment_nutrient_fluxes_denitrification_rates_and_sediment_characteristics_in_Long_Island_Sound_NY/13022843/2
id ftdatacite:10.6084/m9.figshare.13022843.v2
record_format openpolar
institution Open Polar
collection DataCite Metadata Store (German National Library of Science and Technology)
op_collection_id ftdatacite
language unknown
topic Environmental Chemistry
Geochemistry
FOS Earth and related environmental sciences
Oceanography
spellingShingle Environmental Chemistry
Geochemistry
FOS Earth and related environmental sciences
Oceanography
Mazur, Claudia
Fulweiler, Robinson W.
Al-Haj, Alia
Ray, Nicholas
Sanchez-Viruet, Isabel
Sediment nutrient fluxes, denitrification rates and sediment characteristics in Long Island Sound, NY
topic_facet Environmental Chemistry
Geochemistry
FOS Earth and related environmental sciences
Oceanography
description We collected sediment cores at five stations in Long Island Sound along a west to east transect to capture a range of environmental conditions within the estuary. We measured sediment fluxes of dissolved inorganic nutrients and dissolved gases at Execution Rocks (EXR), Western Long Island Sound (WLIS), the ARTG Buoy (ARTG), Central Long Island Sound (CLIS) and Eastern Long Island Sound (ELIS). Stations were sampled twice during the summer (July 2016, June 2017, August 2017) and once during the winter (December 2016). In the field, we measured bottom dissolved oxygen (O 2 ), salinity, and temperature (Hach HQd using LD101, CDC401 probes) at each station. We collected duplicate water samples for quantification of dissolved inorganic nutrient concentrations (NH 4 + , NO 3 - , NO 2 - , DIP). Nutrient samples were run on a Seal Auto Analyzer 3 with segmented flow injection using standard colorimetric techniques (Solorzano 1969; Johnson and Petty 1983; Grasshoff et al. 2009). We also collected surface water samples for chlorophyll -a analysis (Foster and Fulweiler 2014). Sediment cores were collected using an Ocean Instruments MC-400 multi-corer. Cores were incubated and sampled for dissolved O 2 and dissolved inorganic nutrients (NH 4 + , NO 3 - , NO 2 - , DIP) at the start and end of each incubation. During the incubation we collected samples for N 2 and Ar concentrations and N 2 O and CH 4 concentrations (Fulweiler and Nixon 2009; Foster and Fulweiler 2014). N 2 and Ar concentrations were determined using using a quadrupole membrane inlet mass spectrometer (MIMS, Bay Instruments). N 2 O and CH 4 concentrations were determined using a gas chromatograph (GC-2014, Shimadzu, Japan). At the end of each incubation sediment samples were collected to determine sediment density, porosity, percent carbon (%C), percent nitrogen (%N), molar carbon to nitrogen (C:N) ratios and sediment chlorophyll- a . To determine sediment porosity, density we used techniques described by Nielsen et al. (2000). Methods described by Zimmermann et al. (1997) were used to determine %C %N. Percent C and N samples were run on an elemental analyzer at the Fichot Lab at Boston University. Sediment chlorophyll- a concentrations were determined using methods described by (Foster and Fulweiler 2014). Email questions and comments to cmazur@bu.edu Sampling Stations EXR = Execution Rocks (40° 53.00' N 73° 43.70' W, 18 m deep)WLIS = Western Long Island Sound (40° 57.35' N 73° 34.80' W, 19.8 m deep) ARTG = ARTG Buoy (41° 00.60' N 73° 17.29' W, 29 m deep) CLIS = Central Long Island Sound (41° 08.25' N 72° 39.30' W, 26.8 m deep) ELIS = Eastern Long Island Sound (41° 15.80' N, 72° 04.00' W, 22.9 m deep) Abbreviations and Units: Date = dd (day) - month - yy (year)Distance = Distance from NYC, metersTemp = Temperature, °CWC_Chla = Surface water chlorophyll -a , µg L -1 Sediment Characteristics: Density = g/mLPorosity = sediment pore space to total volume ratioC = percent carbon of total massN = percent nitrogen of total massCN = carbon to nitrogen molar ratioSed_Chla = sediment chlorophyll- a , mg m -2 Sed_Phaeo = Sediment phaeophytin, mg m -2 Bottom Water Characteristics: Bottom_DO = Bottom water dissolved oxygen, µmol L -1 Bottom_NH4 = Bottom water ammonium, µmol L -1 Bottom_NO2 = Bottom water nitrite, µmol L -1 Bottom_NO3 = Bottom water nitrate, µmol L -1 Bottom_NOx = Bottom water nitrite + nitrate, µmol L -1 Bottom_DIN = Bottom water nitrate + nitrite + ammonium, µmol L -1 Bottom_DIP = Bottom water dissolved inorganic phosphorus, µmol L -1 Initial_NH4 = ammonium concentration at the start of incubations, µmol L -1 Initial_NO2 = nitrite concentration at the start of incubations, µmol L -1 Initial_NO3 = nitrate concentration at the start of incubations, µmol L -1 Initial_NOx = nitrite + nitrate concentration at the start of incubations, µmol L -1 Initial_DIN = nitrite + nitrate + ammonium concentration at the start of incubations, µmol L -1 Initial_DIP = dissolved inorganic phosphorus concentration at the start of incubations, µmol L -1 Sediment-Water Fluxes: N2N = Net denitrification rate, µmol N 2 -N m -2 hr -1 SOD = Sediment oxygen demand, µmol O 2 m -2 hr -1 CH4 = methane flux, nmol CH 4 m -2 hr -1 N2O = nitrous oxide flux, nmol N 2 O m -2 hr -1 NH4 = ammonium flux, µmol NH 4 + m -2 hr -1 NO2 = nitrite flux, µmol NO 2 - m -2 hr -1 NO3 = nitrate flux, µmol NO 3 - m -2 hr -1 NOx = nitrite + nitrate, µmol NO x m -2 hr -1 DIN = ammonium + nitrite + nitrate flux, µmol N m -2 hr -1 DIP = dissolved inorganic phosphorus flux, µmol DIP m -2 hr -1 DIN.DIP = nitrite + nitrate + ammonium to dissolved inorganic phosphorus ratio Acknowledgments: We thank Aidan Borkan, Craig Tobias, Sydney Twarz, and the University of Connecticut Department of Marine Sciences Vessel Operations for their help with sediment core preparation and collection. We also thank Qile Chen and Carly Langan for helping process sediment samples. Thanks to Nilotpal Ghosh for help with analysis of sediment percent carbon and nitrogen and to Cédric Fichot for allowing us to use his elemental analyzer. References: Foster SQ and RW Fulweiler. 2014. Spatial and historic variability of benthic nitrogen cycling in an anthropogenically impacted estuary. Frontiers in Marine Science 1. https://doi.org/10.3389/fmars.2014.00056. Fulweiler RW, Nixon SW. 2009. Responses of benthic-pelagic coupling to climate change in a temperate estuary. Hydrobiologia 629:147–156. https://doi.org/10.1007/s10750-009-9766-0 Grasshoff K, Kremling K, Ehrhardt M. 2009. Methods of seawater analysis, 3rd edn. Wiley‐VCH, Verlag GmbH, D‐69469, Weinheim, Germany. Johnson KS, Petty RL.1983. Determination of nitrate and nitrite in seawater by flow injection analysis. Am Soc Limnol Oceanogr 28:1260–1266. Nielsen LP, V Brotas, P Viaroli, G Underwood, DB Nedwell, K Sundback, S Rysgaard, et al. 2000. Protocol handbook for NICE - Nitrogen Cycling in Estuaries: A Project under the EU reserach programme: Marine Science and Technology (MAST III). Edited by T Dalsgaard. National Environmental Research Institute, Silkborg, Denmark. Solorzano L. 1969. Determinatiom of Ammonia in Natural Waters by the Phenolhypochlorite Method. Limnol. Oceanogr. 14:799–801. Zimmermann CF, CW Keefe, and J Bashe. 1997. Determination of carbon and nitrogen in sediments and particulates of estuarine/coastal waters using elemental analysis. US Environmental Protection Agency, Method 440: 9. Funding Funding for this project was provided to RWF through the Long Island Sound Study Research Grant Program which is conducted by Connecticut Sea Grant, based at the University of Connecticut at Avery Point, and New York Sea Grant, based at Stony Brook University.
format Dataset
author Mazur, Claudia
Fulweiler, Robinson W.
Al-Haj, Alia
Ray, Nicholas
Sanchez-Viruet, Isabel
author_facet Mazur, Claudia
Fulweiler, Robinson W.
Al-Haj, Alia
Ray, Nicholas
Sanchez-Viruet, Isabel
author_sort Mazur, Claudia
title Sediment nutrient fluxes, denitrification rates and sediment characteristics in Long Island Sound, NY
title_short Sediment nutrient fluxes, denitrification rates and sediment characteristics in Long Island Sound, NY
title_full Sediment nutrient fluxes, denitrification rates and sediment characteristics in Long Island Sound, NY
title_fullStr Sediment nutrient fluxes, denitrification rates and sediment characteristics in Long Island Sound, NY
title_full_unstemmed Sediment nutrient fluxes, denitrification rates and sediment characteristics in Long Island Sound, NY
title_sort sediment nutrient fluxes, denitrification rates and sediment characteristics in long island sound, ny
publisher figshare
publishDate 2021
url https://dx.doi.org/10.6084/m9.figshare.13022843.v2
https://figshare.com/articles/dataset/Sediment_nutrient_fluxes_denitrification_rates_and_sediment_characteristics_in_Long_Island_Sound_NY/13022843/2
long_lat ENVELOPE(-65.433,-65.433,-66.883,-66.883)
ENVELOPE(-79.366,-79.366,54.800,54.800)
ENVELOPE(-67.467,-67.467,-67.583,-67.583)
ENVELOPE(49.350,49.350,-68.133,-68.133)
geographic Avery
Long Island
Long Island Sound
Petty
Underwood
geographic_facet Avery
Long Island
Long Island Sound
Petty
Underwood
genre National Environmental Research Institute
genre_facet National Environmental Research Institute
op_relation https://dx.doi.org/10.6084/m9.figshare.13022843
op_rights Creative Commons Attribution 4.0 International
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cc-by-4.0
op_rightsnorm CC-BY
op_doi https://doi.org/10.6084/m9.figshare.13022843.v2
https://doi.org/10.6084/m9.figshare.13022843
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spelling ftdatacite:10.6084/m9.figshare.13022843.v2 2023-05-15T17:14:17+02:00 Sediment nutrient fluxes, denitrification rates and sediment characteristics in Long Island Sound, NY Mazur, Claudia Fulweiler, Robinson W. Al-Haj, Alia Ray, Nicholas Sanchez-Viruet, Isabel 2021 https://dx.doi.org/10.6084/m9.figshare.13022843.v2 https://figshare.com/articles/dataset/Sediment_nutrient_fluxes_denitrification_rates_and_sediment_characteristics_in_Long_Island_Sound_NY/13022843/2 unknown figshare https://dx.doi.org/10.6084/m9.figshare.13022843 Creative Commons Attribution 4.0 International https://creativecommons.org/licenses/by/4.0/legalcode cc-by-4.0 CC-BY Environmental Chemistry Geochemistry FOS Earth and related environmental sciences Oceanography dataset Dataset 2021 ftdatacite https://doi.org/10.6084/m9.figshare.13022843.v2 https://doi.org/10.6084/m9.figshare.13022843 2021-11-05T12:55:41Z We collected sediment cores at five stations in Long Island Sound along a west to east transect to capture a range of environmental conditions within the estuary. We measured sediment fluxes of dissolved inorganic nutrients and dissolved gases at Execution Rocks (EXR), Western Long Island Sound (WLIS), the ARTG Buoy (ARTG), Central Long Island Sound (CLIS) and Eastern Long Island Sound (ELIS). Stations were sampled twice during the summer (July 2016, June 2017, August 2017) and once during the winter (December 2016). In the field, we measured bottom dissolved oxygen (O 2 ), salinity, and temperature (Hach HQd using LD101, CDC401 probes) at each station. We collected duplicate water samples for quantification of dissolved inorganic nutrient concentrations (NH 4 + , NO 3 - , NO 2 - , DIP). Nutrient samples were run on a Seal Auto Analyzer 3 with segmented flow injection using standard colorimetric techniques (Solorzano 1969; Johnson and Petty 1983; Grasshoff et al. 2009). We also collected surface water samples for chlorophyll -a analysis (Foster and Fulweiler 2014). Sediment cores were collected using an Ocean Instruments MC-400 multi-corer. Cores were incubated and sampled for dissolved O 2 and dissolved inorganic nutrients (NH 4 + , NO 3 - , NO 2 - , DIP) at the start and end of each incubation. During the incubation we collected samples for N 2 and Ar concentrations and N 2 O and CH 4 concentrations (Fulweiler and Nixon 2009; Foster and Fulweiler 2014). N 2 and Ar concentrations were determined using using a quadrupole membrane inlet mass spectrometer (MIMS, Bay Instruments). N 2 O and CH 4 concentrations were determined using a gas chromatograph (GC-2014, Shimadzu, Japan). At the end of each incubation sediment samples were collected to determine sediment density, porosity, percent carbon (%C), percent nitrogen (%N), molar carbon to nitrogen (C:N) ratios and sediment chlorophyll- a . To determine sediment porosity, density we used techniques described by Nielsen et al. (2000). Methods described by Zimmermann et al. (1997) were used to determine %C %N. Percent C and N samples were run on an elemental analyzer at the Fichot Lab at Boston University. Sediment chlorophyll- a concentrations were determined using methods described by (Foster and Fulweiler 2014). Email questions and comments to cmazur@bu.edu Sampling Stations EXR = Execution Rocks (40° 53.00' N 73° 43.70' W, 18 m deep)WLIS = Western Long Island Sound (40° 57.35' N 73° 34.80' W, 19.8 m deep) ARTG = ARTG Buoy (41° 00.60' N 73° 17.29' W, 29 m deep) CLIS = Central Long Island Sound (41° 08.25' N 72° 39.30' W, 26.8 m deep) ELIS = Eastern Long Island Sound (41° 15.80' N, 72° 04.00' W, 22.9 m deep) Abbreviations and Units: Date = dd (day) - month - yy (year)Distance = Distance from NYC, metersTemp = Temperature, °CWC_Chla = Surface water chlorophyll -a , µg L -1 Sediment Characteristics: Density = g/mLPorosity = sediment pore space to total volume ratioC = percent carbon of total massN = percent nitrogen of total massCN = carbon to nitrogen molar ratioSed_Chla = sediment chlorophyll- a , mg m -2 Sed_Phaeo = Sediment phaeophytin, mg m -2 Bottom Water Characteristics: Bottom_DO = Bottom water dissolved oxygen, µmol L -1 Bottom_NH4 = Bottom water ammonium, µmol L -1 Bottom_NO2 = Bottom water nitrite, µmol L -1 Bottom_NO3 = Bottom water nitrate, µmol L -1 Bottom_NOx = Bottom water nitrite + nitrate, µmol L -1 Bottom_DIN = Bottom water nitrate + nitrite + ammonium, µmol L -1 Bottom_DIP = Bottom water dissolved inorganic phosphorus, µmol L -1 Initial_NH4 = ammonium concentration at the start of incubations, µmol L -1 Initial_NO2 = nitrite concentration at the start of incubations, µmol L -1 Initial_NO3 = nitrate concentration at the start of incubations, µmol L -1 Initial_NOx = nitrite + nitrate concentration at the start of incubations, µmol L -1 Initial_DIN = nitrite + nitrate + ammonium concentration at the start of incubations, µmol L -1 Initial_DIP = dissolved inorganic phosphorus concentration at the start of incubations, µmol L -1 Sediment-Water Fluxes: N2N = Net denitrification rate, µmol N 2 -N m -2 hr -1 SOD = Sediment oxygen demand, µmol O 2 m -2 hr -1 CH4 = methane flux, nmol CH 4 m -2 hr -1 N2O = nitrous oxide flux, nmol N 2 O m -2 hr -1 NH4 = ammonium flux, µmol NH 4 + m -2 hr -1 NO2 = nitrite flux, µmol NO 2 - m -2 hr -1 NO3 = nitrate flux, µmol NO 3 - m -2 hr -1 NOx = nitrite + nitrate, µmol NO x m -2 hr -1 DIN = ammonium + nitrite + nitrate flux, µmol N m -2 hr -1 DIP = dissolved inorganic phosphorus flux, µmol DIP m -2 hr -1 DIN.DIP = nitrite + nitrate + ammonium to dissolved inorganic phosphorus ratio Acknowledgments: We thank Aidan Borkan, Craig Tobias, Sydney Twarz, and the University of Connecticut Department of Marine Sciences Vessel Operations for their help with sediment core preparation and collection. We also thank Qile Chen and Carly Langan for helping process sediment samples. Thanks to Nilotpal Ghosh for help with analysis of sediment percent carbon and nitrogen and to Cédric Fichot for allowing us to use his elemental analyzer. References: Foster SQ and RW Fulweiler. 2014. Spatial and historic variability of benthic nitrogen cycling in an anthropogenically impacted estuary. Frontiers in Marine Science 1. https://doi.org/10.3389/fmars.2014.00056. Fulweiler RW, Nixon SW. 2009. Responses of benthic-pelagic coupling to climate change in a temperate estuary. Hydrobiologia 629:147–156. https://doi.org/10.1007/s10750-009-9766-0 Grasshoff K, Kremling K, Ehrhardt M. 2009. Methods of seawater analysis, 3rd edn. Wiley‐VCH, Verlag GmbH, D‐69469, Weinheim, Germany. Johnson KS, Petty RL.1983. Determination of nitrate and nitrite in seawater by flow injection analysis. Am Soc Limnol Oceanogr 28:1260–1266. Nielsen LP, V Brotas, P Viaroli, G Underwood, DB Nedwell, K Sundback, S Rysgaard, et al. 2000. Protocol handbook for NICE - Nitrogen Cycling in Estuaries: A Project under the EU reserach programme: Marine Science and Technology (MAST III). Edited by T Dalsgaard. National Environmental Research Institute, Silkborg, Denmark. Solorzano L. 1969. Determinatiom of Ammonia in Natural Waters by the Phenolhypochlorite Method. Limnol. Oceanogr. 14:799–801. Zimmermann CF, CW Keefe, and J Bashe. 1997. Determination of carbon and nitrogen in sediments and particulates of estuarine/coastal waters using elemental analysis. US Environmental Protection Agency, Method 440: 9. Funding Funding for this project was provided to RWF through the Long Island Sound Study Research Grant Program which is conducted by Connecticut Sea Grant, based at the University of Connecticut at Avery Point, and New York Sea Grant, based at Stony Brook University. Dataset National Environmental Research Institute DataCite Metadata Store (German National Library of Science and Technology) Avery ENVELOPE(-65.433,-65.433,-66.883,-66.883) Long Island Long Island Sound ENVELOPE(-79.366,-79.366,54.800,54.800) Petty ENVELOPE(-67.467,-67.467,-67.583,-67.583) Underwood ENVELOPE(49.350,49.350,-68.133,-68.133)

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