DataSheet_1_Seasonal and Spatial Production Patterns of Dissolved Inorganic Carbon and Total Alkalinity in a Shallow Beach Aquifer.docx

Dissolved inorganic carbon (DIC) and total alkalinity (Alk T ) fluxes to the nearshore ocean can directly impact the rates of primary production, coral reef formation, coastal ocean acidification, and continental shelf ecology. Current understanding of the transformations that DIC and Alk T undergo...

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Bibliographic Details
Main Authors: Kyra H. Kim, James W. Heiss, Holly A. Michael, William J. Ullman, Wei-Jun Cai
Format: Dataset
Language:unknown
Published: 2022
Subjects:
Oceanography
Marine Biology
Marine Geoscience
Biological Oceanography
Chemical Oceanography
Physical Oceanography
Marine Engineering
beach aquifer
total alkalinity (Alk-T)
dissolved inorganic carbon (DIC)
intertidal circulation cell
carbon chemistry
subterranean estuary
Sandy Beach
Ocean acidification
Online Access:https://doi.org/10.3389/fmars.2022.856281.s001
https://figshare.com/articles/dataset/DataSheet_1_Seasonal_and_Spatial_Production_Patterns_of_Dissolved_Inorganic_Carbon_and_Total_Alkalinity_in_a_Shallow_Beach_Aquifer_docx/19947104
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Summary:Dissolved inorganic carbon (DIC) and total alkalinity (Alk T ) fluxes to the nearshore ocean can directly impact the rates of primary production, coral reef formation, coastal ocean acidification, and continental shelf ecology. Current understanding of the transformations that DIC and Alk T undergo as they move from land to sea are limited, leading to difficulties in estimating future DIC and Alk T export that may be altered under a changing climate. While much research has focused on carbon fluxes in carbon-rich mangroves and coastal wetlands, DIC and Alk T transformations and distributions in sandy beach aquifers, which are comparatively carbon-poor, have not been studied as extensively. We monitored DIC and Alk T concentrations in a sandy beach system over six sampling events spanning two years. Substantial changes to DIC and Alk T occurred along subsurface flowpaths due to aerobic respiration and anoxic reactions, resulting in an additional mean flux to the ocean of 191 and 134 mmol/d per meter length of shoreline, respectively. The chemical alterations occurred within the saltwater-freshwater mixing zone beneath the beach surface. Both aerobic and anaerobic reactions actively contributed to DIC and Alk T production within the system, as indicated by DIC: Alk T and dDIC:dAlk T ratios relative to the theoretical dilution line. The work indicates that beach aquifers support active transformation of inorganic carbon and highlights a potentially important and overlooked source of DIC and Alk T to coastal systems.

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