Origin of water masses in Floridan Aquifer System revealed by 81Kr

Origin of water masses in Floridan Aquifer System revealed by 81Kr

•Freshwater recharged to Floridan Aquifer System mostly during last glacial period.•Radiocarbon dilution by water rock interaction gave apparent 14C half-live of <2 kyr.•Late Pleistocene seawater was identified in the Floridan Aquifer System using 81Kr.•Sluggish seawater circulation in the Florid...

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Bibliographic Details
Published in:Earth and planetary science letters Vol. 569; p. 117060
Main Authors: Yokochi, Reika, Zappala, Jake C., Purtschert, Roland, Mueller, Peter
Format: Journal Article
Language:English
Published: United States Elsevier B.V 01-09-2021
Elsevier
Subjects:
coastal dolomitization
Floridan Aquifer System
fossil seawater
GEOSCIENCES
groundwater dating
NUCLEAR PHYSICS AND RADIATION PHYSICS
radiokrypton isotopes
radiokrypton isotopes
fossil seawater
groundwater dating
coastal dolomitization
Floridan Aquifer System
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Summary:•Freshwater recharged to Floridan Aquifer System mostly during last glacial period.•Radiocarbon dilution by water rock interaction gave apparent 14C half-live of <2 kyr.•Late Pleistocene seawater was identified in the Floridan Aquifer System using 81Kr.•Sluggish seawater circulation in the Floridan aquifer implies slow dolomitization.•Deep saline coastal aquifers may serve as a paleo-seawater archive. Groundwater in coastal aquifers serves as an essential resource in densely populated areas throughout the world. However, hydrological connection to the ocean leaves it at risk of salinization via changes in climate and hydrological cycles. Therefore, an accurate hydrological characterization of coastal aquifers is of the utmost importance. Although localized salinization of shallow aquifers has commonly been studied, geochemical constraints on the time scale of regional freshwater and seawater in coastal aquifers are limited especially in carbonate aquifers. Such information is not only crucial for water resource management, but also for understanding solute flux over the land-ocean boundary and for interpreting the geochemical signatures that each water mass carries. Toward this goal, we report tracer-based, subsurface residence times of groundwater in the Floridan Aquifer System in southern Florida, which is one of the most productive aquifers on Earth. The first application of 81Kr—an emerging tracer of old groundwater—to this aquifer has identified freshwater recharge during the last glacial period as anticipated from previous studies using other geochemical tools including radiocarbon, stable isotopes and noble gas concentrations. Moreover, freshwater of Holocene age was also detected at 100 km-distance from the recharge area, suggesting the possibility of an active flow system in the upgradient region. A contribution of fossil seawater that predates the last glacial maximum was locally identified, suggesting slow seawater circulation and limited but significant solute flux from the ocean into the aquifer for dolomitization. This also implies that the deep saline coastal groundwater can potentially serve as a paleo-seawater archive.
Bibliography:AC02-06CH11357
Ben Gurion University -Argonne National Laboratory - University of Chicago Collaborative Water Research Initiative
USDOE Office of Science (SC), Nuclear Physics (NP)
ISSN:0012-821X
1385-013X
DOI:10.1016/j.epsl.2021.117060