Temperature Evolution of the Indo‐Pacific Warm Pool Over the Holocene and the Last Deglaciation

Moffa-Sánchez, Paola; Rosenthal, Yair; Babila, Tali L.; Mohtadi, Mahyar; Zhang, Xu

doi:10.1029/2018pa003455

Cited by 25 publications

(17 citation statements)

References 155 publications

(238 reference statements)

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“…The evolution of atmospheric CO 2 since the LGM is also correlated to moraine‐based late glacial warming observations (e.g., Kaplan et al, 2010; Koffman et al, 2017; Strand et al, 2019). This air temperature‐CO 2 relationship is consistent with a compilation of foraminiferal‐based SST records throughout the IPWP (South China Sea: Moffa‐Sanchez et al, 2019, Steinke et al, 2008, 2011, Sumatra: Mohtadi et al, 2014, Papua New Guinea: Moffa‐Sanchez et al, 2019, Timor Sea: Gibbons et al, 2014; Holbourn et al, 2011; Levi et al, 2007; Xu et al, 2008, and the Indonesian Throughflow: Fan et al, 2013; Linsley et al, 2010; Rosenthal et al, 2003; Schröder et al, 2016, 2018; Stott et al, 2004) (Moffa‐Sanchez et al, 2019). The coevolution of SST and CO 2 is also evident in our SSTA record when corals record near modern temperatures during the YDC and there is a coincident rise in atmospheric CO 2 commencing around 12 kyr BP (Bereiter et al, 2015) (Figure 3).…”

Section: Discussionsupporting

confidence: 88%

Coral Record of Younger Dryas Chronozone Warmth on the Great Barrier Reef

Brenner

Linsley

Webster

et al. 2020

Paleoceanog and Paleoclimatol

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The Great Barrier Reef (GBR) is an internationally recognized and widely studied ecosystem, yet little is known about its sea surface temperature (SST) evolution since the Last Glacial Maximum (LGM) (~20 kyr BP). Here, we present the first paleo‐application of Isopora coral‐derived SST calibrations to a suite of 25 previously published fossil Isopora from the central GBR spanning ~25–11 kyr BP. The resultant multicoral Sr/Ca‐ and δ18O‐derived SST anomaly (SSTA) histories are placed within the context of published relative sea level, reef sequence, and coralgal reef assemblage evolution. Our new calculations indicate SSTs were cooler on average by ~5–5.5°C at Noggin Pass (~17°S) and ~7–8°C at Hydrographer's Passage (~20°S) (Sr/Ca‐derived) during the LGM, in line with previous estimates (Felis et al., 2014, https://doi.org/10.1038/ncomms5102). We focus on contextualizing the Younger Dryas Chronozone (YDC, ~12.9–11.7 kyr BP), whose Southern Hemisphere expression, in particular in Australia, is elusive and poorly constrained. Our record does not indicate cooling during the YDC with near‐modern temperatures reached during this interval on the GBR, supporting an asymmetric hemispheric presentation of this climate event. Building on a previous study (Felis et al., 2014, https://doi.org10.1038/ncomms5102), these fossil Isopora SSTA data from the GBR provide new insights into the deglacial reef response, with near‐modern warming during the YDC, since the LGM.

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Section: Discussionsupporting

confidence: 88%

Coral Record of Younger Dryas Chronozone Warmth on the Great Barrier Reef

Brenner

Linsley

Webster

et al. 2020

Paleoceanog and Paleoclimatol

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“…Such oscillations may have occurred during the late-Holocene, associated with cooling of the tropical Pacific Ocean coupled with a slowdown of water exchange between the western Pacific and the South China Sea (e.g. Moffa-Sanchez et al, 2019; Partin et al, 2007). However more data is needed to decipher the possible local explanations for RSL lowstands.…”

Section: Discussionmentioning

confidence: 99%

A new Holocene sea-level record for Singapore

Chua

Switzer

et al. 2021

The Holocene

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Relative sea-level (RSL) records from far-field regions distal from ice sheets remain poorly understood, particularly in the early Holocene. Here, we extended the Holocene RSL data from Singapore by producing early Holocene sea-level index points (SLIPs) and limiting dates from a new ~40 m sediment core. We merged new and published RSL data to construct a standardized Singapore RSL database consisting of 88 SLIPs and limiting data. In the early Holocene, RSL rose rapidly from −21.0 to −0.7 m from ~9500 to 7000 cal. yrs. BP. Thereafter, the rate of RSL rise decelerated, reaching a mid-Holocene highstand of 4.0 ± 4.5 m at 5100 cal. yrs. BP, before falling to its present level. There is no evidence of any inflections in RSL when the full uncertainty of SLIPs is considered. When combined with other standardized data from the Malay-Thai Peninsula, our results also show substantial misfits between regional RSL reconstructions and glacial isostatic adjustment (GIA) model predictions in the rate of early Holocene RSL rise, the timing of the mid-Holocene highstand and the nature of late-Holocene RSL fall towards the present. It is presently unknown whether these misfits are caused by regional processes, such as subsidence of the continental shelf, or inaccurate parameters used in the GIA model.

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“…Within low latitudes, most available Holocene temperature records, including SSTs and terrestrial temperatures, derive from locations outside of the Indian monsoon-influenced southern Asia [11]. These data usually show contrasting annual temperature trends at different areas, including both warming and cooling in the Indo-Pacific Warm Pool [70][71], the Indian Ocean [72][73], and tropical Africa [74]. This indicates the existence of major spatial heterogeneity in low-latitude Holocene annual temperature trend.…”

Section: Reconstructed Maat Variations In Southwestern Chinamentioning

confidence: 99%

“…Notably, some local factors could override the effect of annual insolation, and induce substantial spatial heterogeneity in Holocene annual temperature trends. For instance, Holocene SST discrepancies in the Indo-Pacific Warm Pool and Indian Ocean may be attributed to monsoon-induced ocean circulation patterns [71][72], influences of northern high-latitude climates [70] and/or seasonal bias in SST proxies [73,77], while Holocene temperature changes in tropical and southern Africa have been linked to a complex interplay of local annual maximum insolation [78], tropical hydrology [79], southwestern Indian Ocean SST [80], and northern high-latitude climates [81][82]. Fortunately, model simulations suggest that our study site is in the less-complicated region where local annual insolation influences are dominant (Fig.…”

Section: Driving Force Of Holocene Temperature Changes In Southern Asiamentioning

confidence: 99%