Contrasting marine carbonate systems in two fjords in British Columbia, Canada: Seawater buffering capacity and the response to anthropogenic CO2 invasion.

Alex Hare,Katie Pocock,Wiley Evans,Carrie Weekes,Iria Gimenez,Nicholas Ward

doi:10.1371/journal.pone.0238432

Alex Hare, Katie Pocock + Show 4 more

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https://doi.org/10.1371/journal.pone.0238432

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Journal: PloS one	Publication Date: Sep 3, 2020
Citations: 15	License type: CC BY 4.0

Affiliation: Tula Foundation, University of British Columbia

Abstract

The carbonate system in two contrasting fjords, Rivers Inlet and Bute Inlet, on the coast of British Columbia, Canada, was evaluated to characterize the mechanisms driving carbonate chemistry dynamics and assess the impact of anthropogenic carbon. Differences in the character of deep water exchange between these fjords were inferred from their degree of exposure to continental shelf water and their salinity relationships with total alkalinity and total dissolved inorganic carbon, which determined seawater buffering capacity. Seawater buffering capacity differed between fjords and resulted in distinct carbonate system characteristics with implications on calcium carbonate saturation states and sensitivity to increasing anthropogenic carbon inputs. Saturation states of both aragonite and calcite mineral phases of calcium carbonate were seasonally at or below saturation throughout the entire water column in Bute Inlet, while only aragonite was seasonally under-saturated in portions of the water column in Rivers Inlet. The mean annual saturation states of aragonite in Rivers Inlet and calcite in Bute Inlet deep water layers have declined to below saturation within the last several decades due to anthropogenic carbon accumulation, and similar declines to undersaturation are projected in their surface layers as anthropogenic carbon continues to accumulate. This study demonstrates that the degree of fjord water exposure to open shelf water influences the uptake and sensitivity to anthropogenic carbon through processes affecting seawater buffering capacity, and that reduced uptake but greater sensitivity occurs where distance to ocean source waters and freshwater dilution are greater.

Highlights

Little information exists on marine carbonate system dynamics within fjords along the Pacific coast of North America
Bute is isolated from open continental shelf water to the southeast by ~400 km through the Salish Sea with which the majority of water exchange occurs over a relatively deep sill of ~265 m in intermediate channels [34, 36, 37], and roughly half that distance to the northwest from which additional minor water exchange occurs (Fig 1)
Given the trajectory of atmospheric pressure of CO2 (pCO2), sub-surface water would have experienced lower atmospheric pCO2 than modern surface water and contains lower TCO2_Anth content (e.g. [62, 63]) We considered the surface layer to vertically mix sufficiently to interact with current atmospheric pCO2 (Figs 2 and 3)

Summary

Introduction

Little information exists on marine carbonate system dynamics within fjords along the Pacific coast of North America. The few studies from Prince William Sound [1], Glacier Bay [2], and Puget Sound [3, 4], describe these settings as highly variable with strong seasonality in carbonate system parameters and sensitive to ‘anthropogenic carbon’ (TCO2_Anth). Seawater buffering capacity and anthropogenic CO2 invasion in North Pacific fjords

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