Upwellings mitigated Plio-Pleistocene heat stress for reef corals on the Florida platform (USA) release_laajbgiblfco7cpdb5y6p4idku

by Thomas Brachert, Markus Reuter, Stefan Krüger, Julia Kirkerowicz, James S. Klaus

Published in Biogeosciences by Copernicus GmbH.

2016   Volume 13, p1469-1489

Abstract

<strong>Abstract.</strong> The fast growing calcareous skeletons of zooxanthellate reef corals (z corals) represent unique environmental proxy archives through their oxygen and carbon stable isotope composition (<i>δ</i><sup>18</sup>O, <i>δ</i><sup>13</sup>C). In addition, the accretion of the skeleton itself is ultimately linked to the environment and responds with variable growth rates (extension rate) and density to environmental changes. Here we present classical proxy data (<i>δ</i><sup>18</sup>O, <i>δ</i><sup>13</sup>C) in combination with calcification records from 15 massive z corals. The z corals were sampled from four interglacial units of the Florida carbonate platform (USA) dated approximately 3.2, 2.9, 1.8 and 1.2<span class="thinspace"></span>Ma (middle Pliocene to early Pleistocene). The z corals (<i>Solenastrea</i>, <i>Orbicella</i>, <i>Porites</i>) derive from unlithified shallow marine carbonates and were carefully screened for primary preservation suited for proxy analysis. We show that skeletal accretion responded with decreasing overall calcification rates (decreasing extension rate but increasing density) to warmer water temperatures. Under high annual water temperatures, inferred from sub-annually resolved <i>δ</i><sup>18</sup>O data, skeletal bulk density was high, but extension rates and overall calcification rates were at a minimum (endmember scenario 1). Maximum skeletal density was reached during the summer season giving rise to a growth band of high density within the annually banded skeletons ("high density band", HDB). With low mean annual water temperatures (endmember scenario 2), bulk skeletal density was low but extension rates and calcification rates reached a maximum, and under these conditions the HDB formed during winter. Although surface water temperatures in the Western Atlantic warm pool during the interglacials of the late Neogene were  ∼ <span class="thinspace"></span>2<span class="thinspace"></span>°C higher than they are in the present day, intermittent upwelling of cool, nutrient-rich water mitigated water temperatures off south-western Florida and created temporary refuges for z coral growth. Based on the sub-annually resolved <i>δ</i><sup>18</sup>O and <i>δ</i><sup>13</sup>C records, the duration of the upwelling episodes causing the endmember 2 conditions was variable and lasted from a few years to a number of decades. The episodes of upwelling were interrupted by phases without upwelling (endmember 1) which lasted for at least a few years and led to high surface water temperatures. This variable environment is likely one of the reasons why the coral fauna is dominated by the eurytopic genus <i>Solenastrea</i>, also a genus resistant to high turbidity. Over a period of  ∼ <span class="thinspace"></span>50<span class="thinspace"></span>years, the oldest sub annually resolved proxy record available (3.2<span class="thinspace"></span>Ma) documents a persistent occurrence of the HDB during winter. In contrast, the HDB forms in summer in modern z corals from the Florida reef tract. We suggest this difference should be tested as being the expression of a tendency towards decreasing interglacial upwelling since the middle Pliocene. The number of z coral sclerochronological records for the Plio-Pleistocene is still rather low, however, and requires more data and an improved resolution, through records from additional time slices. Nonetheless, our calcification data from the warm periods of past interglacials may contribute to predicting the effects of future ocean warming on z coral health along the Florida reef tract. The inconsistent timing of the HDB within single coral records or among specimens and time slices is unexpected and contrasts the common practice of establishing chronologies on the basis of the density banding.
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