Dataset: Benthic flux data from sediment cores collected in the York River Estuary, VA in 2020

Benthic Fluxes:
In January, June, August, and October of 2020, triplicate sediment cores (5.7 cm diameter, 10 cm height) were collected from three shoal stations and three channel stations during bimonthly cruises of the York River Estuary (YRE) on 24ft Carolina skiffs. In July and September 2020, triplicate sediment cores of the same parameters were collected from three shoal and three channel stations in the lower YRE before and after the occurrence of intense phytoplankton blooms. Depths at which the sediment cores were sampled were about 1m at the shoal stations and 10m at the channel stations. After collection, the sediment cores were stored in coolers on ice. As sampling at all of the stations took six hours, the cores were stored in coolers for one to five hours depending on when a particular station was sampled. After transport, the sediment cores were placed in an environmental chamber under in situ conditions of temperature in buckets filled with ambient YRE water with constant stirring. The cores were left in the dark overnight to equilibrate. The following day, the overlying water in the cores was replaced with filter-sterilized (0.2 μm) site water and capped. The cores were then incubated for seven hours (three hours in the dark, followed by 1 hour for equilibration with light, followed by three hours in the light). Ambient light conditions were simulated by high-intensity UV/ VIS lamps. Dissolved inorganic carbon (DIC), dissolved organic carbon (DOC), dissolved inorganic nitrogen and phosphorus (DIN), and dissolved organic nitrogen (DON) samples were collected every hour throughout the six-hour incubation. DOC, DIN, and DON samples were filtered through 0.45 μm polysulfone filters. For DIC, 12 mL of water were collected and preserved with 0.1 μL of mercuric chloride. Dissolved oxygen (DO) concentrations were monitored every hour using a PreSens OXY-4 SMA (G2) oxygen sensor. Water was simultaneously replaced during sampling with filter sterilized (0.2 μm) site water.

One additional sediment core (5 cm diameter) was taken at each shoal and channel station for sediment characterization (Anderson et al. 2003) and benthic chlorophyll-a analysis. After collection, one of the cores from each site was sectioned at 0-2cm and 2-5 cm. Half of each section was collected in whirlpak bags filled with a volume of KCl equal to 2x the volume of the sediment (35mL for 0-2cm section, 50mL for 2-5cm section), shaken for one hour, centrifuged, filtered (0.45 μm polysulfone), and analyzed for ammonium (NH₄⁺), nitrate (NO₃⁻), and nitrite (NO₂⁻) on a QuikChem FIA+ 8000 Series Latchet autoanalyzer. The other half of each section (0-2cm and 2-5cm) was used to calculate bulk density, water content, and organic content via measurement of wet weights, dry weights, and combusted weights of the sediment sample. To determine benthic chlorophyll-a concentrations, sediment from each site was sampled in situ at 0-3mm and 3-10mm and frozen until analysis. For analysis, acetone extractant (10 mL) was added to the samples, each sample was sonicated for 30 seconds, and the sonicated samples were placed in a freezer for 24 hours before analysis on a spectrophotometer (Lorenzen 1967, Pinckney et al. 1995; Jeffrey and Welchmeyer 1997).

Benthic N Cycling Rates:
Actual rates of denitrification and DNRA were determined via the isotope pairing technique (IPT) (Murphy et al. 2016). IPT relies on using added ¹⁵NO₃⁻ to water overlying sediments to distinguish between direct, coupled, and actual vs. potential rates of denitrification and DNRA. At the time of core collection, an additional set of two cores (5.7 cm diameter, 10 cm height) were collected from each station and kept in the same conditions as the flux cores to serve as T0 cores for IPT. After the flux experiment described above, the cores were uncapped and left in the dark overnight in buckets filled with ambient YRE water with constant stirring. The following morning, each core was spiked with 5.37 mL of 10 mM 98 atom% ¹⁵NO₃⁻ to bring the concentration of nitrate within the cores to 100 μM. A water sample was collected from each core and analyzed for total NO₃⁻ (¹⁴NO₃⁻ + ¹⁵NO₃⁻). The DO concentrations were measured in each core using a PreSens OXY-4 SMA (G2) oxygen sensor. The T0 cores were left uncapped in the environmental chamber and the remaining cores (TF) were capped and placed in buckets of ambient YRE water for one hour to allow the ¹⁵NO₃⁻ to diffuse to the active zone of denitrification and DNRA. The overlying water in the T0 cores was then be sampled for total NO₃ - and the cores were slurried and sampled for ²⁹N₂ and ³⁰N₂ (12 mL of slurry preserved with 0.1 mL of saturated zinc chloride) and KCl-extractable NH₄⁺ (60 mL of slurry placed in whirlpak bags filled with 17.7 g of powdered KCl). The NH₄⁺ was reduced by the OX/MIMS method (Yin et al. 2014) and ²⁹N₂ and ³⁰N₂ measured by the MIMS. The DO concentrations in the TF cores were monitored using the PreSens OXY – 4 SMA (G2) oxygen sensor) every 30 to 60 minutes until DO concentrations reached no less than 70% of initial concentrations (or a 30% drop). Each core was then uncapped and the overlying water sampled and analyzed for total NO₃⁻. The cores were slurried sampled and analyzed for ²⁹N₂, ³⁰N₂, and ¹⁵NH₄⁺ concentrations as described above.

Instruments:
Nutrient analyses (NO₃, NO₂, NH₄) were performed with a Lachat QuikChem 8000 automated ion analyzer (Lachat Instruments, Milwaukee, WI, USA); detection limits for NO₃, and NH₄, are 0.20 and 0.36 μM, respectively). DIC was analyzed on an Apollo, model AS-C3 (Apollo SciTech, Newark DE); DOC on a Shimadzu TOC-VCSN combustion analyzer, and extracted chlorophyll-a on a Beckman Coulter DU800 Spectrophotometer. ²⁹N₂ and ³⁰N₂ measured by the membrane inlet mass spectrometer (MIMS, Balzers Prisma).