New constraints on the postglacial shallow-water carbonate accumulation in the Great Barrier Reef

Gustavo Hinestrosa,Jody M Webster,Robin J Beaman

doi:10.1038/s41598-021-04586-w

Gustavo Hinestrosa, Jody M Webster + Show 1 more

Open Access

https://doi.org/10.1038/s41598-021-04586-w

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Journal: Scientific Reports	Publication Date: Jan 18, 2022
Citations: 5	License type: open-access

Affiliation: University of Sydney, James Cook University

Abstract

More accurate global volumetric estimations of shallow-water reef deposits are needed to better inform climate and carbon cycle models. Using recently acquired datasets and International Ocean Discovery Program (IODP) Expedition 325 cores, we calculated shallow-water CaCO3 volumetrics and mass for the Great Barrier Reef region and extrapolated these results globally. In our estimates, we include deposits that have been neglected in global carbonate budgets: Holocene Halimeda bioherms located on the shelf, and postglacial pre-Holocene (now) drowned coral reefs located on the shelf edge. Our results show that in the Great Barrier Reef alone, these drowned reef deposits represent ca. 135 Gt CaCO3, comparatively representing 16–20% of the younger Holocene reef deposits. Globally, under plausible assumptions, we estimate the presence of ca. 8100 Gt CaCO3 of Holocene reef deposits, ca. 1500 Gt CaCO3 of drowned reef deposits and ca. 590 Gt CaCO3 of Halimeda shelf bioherms. Significantly, we found that in our scenarios the periods of pronounced reefal mass accumulation broadly encompass the occurrence of the Younger Dryas and periods of CO2 surge (14.9–14.4 ka, 13.0–11.5 ka) observed in Antarctic ice cores. Our estimations are consistent with reef accretion episodes inferred from previous global carbon cycle models and with the chronology from reef cores from the shelf edge of the Great Barrier Reef.

Highlights

The role of calcium carbonate deposits in the carbon cycle, and the influence on climate change during the lateQuaternary is poorly constrained
We estimated the areal trends of the Holocene reefs in the Great Barrier Reef (GBR)
Reef area was estimated from GIS layers containing polygons representing the outline of the Holocene reefs (Figs. 1 and 2)

Summary

Introduction

The role of calcium carbonate deposits in the carbon cycle, and the influence on climate change during the lateQuaternary is poorly constrained. The authors assigned a medium degree of confidence to the current estimates of atm-CO2 contributions from coral reef accretion and carbonate compensation depth changes This uncertainty derives not just from the use of proxy data and their limited availability, but from the complex relationships between the carbon and other biogeochemical cycles. This hypothesis proposes that the increase of the atm-CO2 is at least partly due to the enhanced shallow-water CaCO3 accretion by corals This hypothesis relies on the availability of new areas of marine flooded shelf during the last transgression and on the consequent increase in coral reef development. Halimeda bioherms are another contributing component, with recent investigations from the GBR suggesting they are volumetrically relevant in postglacial carbonate b udgets[25,26,27]

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