Mechanisms driving decadal changes in the carbonate system of a coastal plain estuary: Associated dataset

Authors

Fei Da, Virginia Institute of Marine ScienceFollow
Marjorie A.M. Friedrichs, Virginia Institute of Marine ScienceFollow
Pierre St-Laurent, Virginia Institute of Marine ScienceFollow

Document Type

Data

Department/Program

Virginia Institute of Marine Science

Publication Date

4-2021

Data Access

ACCESS DATA FILES HERE

Abstract

This dataset includes model outputs presented in the associated publication (Da et al. 2021, Journal of Geophysical Research: Oceans). This study used a three-dimensional ecosystem model to quantify the relative impacts of multiple anthropogenic drivers on the Chesapeake Bay carbonate system over the past three decades. Model simulations highlight that increased atmospheric CO₂ concentrations and decreased terrestrial nutrient inputs are two primary drivers causing nearly equal reductions in pH in surface waters of the Bay.

Description

These are daily model outputs used to generate results and figures shown in Da et al., Journal of Geophysical Research: Oceans, 2021. Please see associated journal article for details.

We conducted nine model simulations, and outputs of each simulation are saved in two folders. Therefore, there are 18 folders, including two for 1985-1989 reference model simulation, two for 2015-2019 reference model simulation, and 14 for sensitivity simulations (see details below).

All files are in netCDF format, which can be manipulated and displayed by a wide range of freely available (e.g., Python) and licensed software (e.g., MATLAB), see https://www.unidata.ucar.edu/software/netcdf/docs/. For detailed information about the open-source model: Regional Ocean Modeling System (ROMS), see: www.myroms.org.

Note that both ocean_avg*.nc and ocean_dia*.nc files save daily averaged model outputs. Primary production rate is read from ocean_dia*.nc files, while other variables are read from ocean_avg*.nc files.

Names of these simulations in the following “File Description Table” are also listed in Table 1 of the associated publication.

Files | Description

• out_ref1985_01: Model Output – Reference model simulation (1985-1986)
• out_ref1985_02: Model Output – Reference model simulation (1987-1989)
• out_ref2015_01: Model Output – Reference model simulation (2015-2016)
• out_ref2015_02: Model Output – Reference model simulation (2017-2019)
• out_airCO2_01: Model Output – Increased atmospheric CO₂ concentration, AtmCO₂ sensitivity experiment (2015-2016)
• out_airCO2_02: Model Output – Increased atmospheric CO₂ concentration, AtmCO₂ sensitivity experiment (2017-2019)
• out_airT_01: Model Output – Increased atmospheric temperature and longwave radiation, AtmT sensitivity experiment (2015-2016)
• out_airT_02: Model Output – Increased atmospheric temperature and longwave radiation, AtmT sensitivity experiment (2017-2019)
• out_bryDIC_01: Model Output – Increased oceanic dissolved inorganic carbon concentrations, OcnC sensitivity experiment (2015-2016)
• out_bryDIC_02: Model Output – Increased oceanic dissolved inorganic carbon concentrations, OcnC sensitivity experiment (2017-2019)
• out_rivDIN_01: Model Output – Decreased riverine nitrate concentrations, RivNO₃ sensitivity experiment (2015-2016)
• out_rivDIN_02: Model Output – Decreased riverine nitrate concentrations, RivNO₃ sensitivity experiment (2017-2019)
• out_rivON_01: Model Output – Decreased riverine organic nitrogen concentrations, RivON sensitivity experiment (2015-2016)
• out_rivON_02: Model Output – Decreased riverine organic nitrogen concentrations, RivON sensitivity experiment (2017-2019)
• out_rivTADIC_01: Model Output – Increased riverine total alkalinity and dissolved inorganic carbon concentrations, RivC sensitivity experiment (2015-2016)
• out_rivTADIC_02: Model Output – Increased riverine total alkalinity and dissolved inorganic carbon concentrations, RivC sensitivity experiment (2017-2019)
• out_all_01: Model Output – Modify all six drivers together, All sensitivity experiment (2015-2016)
• out_all_02: Model Output – Modify all six drivers together, All sensitivity experiment (2017-2019)

DOI

https://doi.org/10.25773/6087-bj68

Keywords

Chesapeake Bay, coastal acidification, carbonate system, decadal trends, anthropogenic drivers

Associated Publications

Da, F., Friedrichs, M.A.M., St-Laurent, P., Shadwick, E.H., Najjar, R.G., and Hinson, K. (2021). Mechanisms driving decadal change in the carbonate system of a coastal plain estuary. Journal of Geophysical Research: Oceans, in revision.

Publication Statement

Fei Da ORCID id: 0000-0002-5330-5962 | Marjorie A. M. Friedrichs ORCID id: 0000-0003-2828-7595 | Pierre St-Laurent ORCID id: 0000-0002-1700-9509

Funding

This work has been supported by the National Science Foundation (OCE-1537013, OCE-1536996), the Mid-Atlantic Sea Grant/NOAA OAP Graduate Research Fellowship (NA14OAR4170093, NA18OAR4170083) and the Virginia Institute of Marine Science Foundation. The authors also acknowledge the High Performance Computing facilities at William & Mary (https://www.wm.edu/it/rc), which are supported by the National Science Foundation, the Commonwealth of Virginia Equipment Trust Fund and the Office of Naval Research.

Recommended Citation

Da, Fei; Friedrichs, Marjorie A.M.; and St-Laurent, Pierre, "Mechanisms driving decadal changes in the carbonate system of a coastal plain estuary: Associated dataset" (2021). Data. William & Mary.

https://doi.org/10.25773/6087-bj68