Surviving rapid climate change in the deep sea during the Paleogene hyperthermals

Foster, Laura C.; Schmidt, Daniela N.; Thomas, Ellen; Arndt, Sandra; Ridgwell, Andy

doi:10.1073/pnas.1300579110

Cited by 64 publications

(60 citation statements)

References 38 publications

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“…6b). Our models similarly reveal a strong size dependency in volumenormalised approaches, such as that used by Foster et al (2013) across the PETM. All model runs predict that the foraminiferal calcite volume / total volume ratio exhibits a strong dependence on test size (Fig.…”

Section: Implications For Size-normalised Weight (Snw) In Foraminifermentioning

confidence: 62%

“…While there are as yet few data from smaller species of planktonic foraminifera and early ontogenetic stage individuals of larger planktonic foraminiferal species, there are some lines of evidence from small benthic foraminifera that could support the inverse calcification response that we propose. Foster et al (2013) found that small benthic foraminifera became more heavily calcified during the PETM, when ocean pH was lower (Penman et al, 2014). By contrast, during the high pH "carbonate overshoot" in the aftermath of the event (Penman et al, 2016), these foraminifera displayed thinner walls .…”

Section: Towards Understanding the Differential Response Of Foraminifmentioning

confidence: 95%

“…Aldridge et al, 2012;Weinkauf et al, 2016). Furthermore, other studies have observed an inverse response of SNW to carbonate system change in some species (Beer et al, 2010b;Foster et al, 2013) -that is, a greater test thickness at lower pH and/or ]. It is possible that at least some of the discrepancies described above may stem from methodological differences, since foraminiferal SNW has been quantified in a number of different ways (see Beer et al, 2010a;Aldridge et al, 2012;Marshall et al, 2013, for further discussion).…”

Section: Introductionmentioning

confidence: 93%

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Size-dependent response of foraminiferal calcification to seawater carbonate chemistry

et al. 2017

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Abstract. The response of the marine carbon cycle to changes in atmospheric CO 2 concentrations will be determined, in part, by the relative response of calcifying and non-calcifying organisms to global change. Planktonic foraminifera are responsible for a quarter or more of global carbonate production, therefore understanding the sensitivity of calcification in these organisms to environmental change is critical. Despite this, there remains little consensus as to whether, or to what extent, chemical and physical factors affect foraminiferal calcification. To address this, we directly test the effect of multiple controls on calcification in culture experiments and core-top measurements of Globigerinoides ruber. We find that two factors, body size and the carbonate system, strongly influence calcification intensity in life, but that exposure to corrosive bottom waters can overprint this signal post mortem. Using a simple model for the addition of calcite through ontogeny, we show that variable body size between and within datasets could complicate studies that examine environmental controls on foraminiferal shell weight. In addition, we suggest that size could ultimately play a role in determining whether calcification will increase or decrease with acidification. Our models highlight that knowledge of the specific morphological and physiological mechanisms driving ontogenetic change in calcification in different species will be critical in predicting the response of foraminiferal calcification to future change in atmospheric pCO 2 .

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Section: Implications For Size-normalised Weight (Snw) In Foraminifermentioning

confidence: 62%

Section: Towards Understanding the Differential Response Of Foraminifmentioning

confidence: 95%

Section: Introductionmentioning

confidence: 93%

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Size-dependent response of foraminiferal calcification to seawater carbonate chemistry

et al. 2017

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“…Those benthic foraminiferal species surviving the PETM had the ability to enhance their calcification relative to body volume (Foster et al . ). Intriguingly, deep sea ostracods show highly variable responses, some of which suggest that the climate change impacted the assemblages negatively (Steineck & Thomas ) while others suggest little change (Webb et al .…”

Section: Rapid Climate Change: Palaeogene Hyperthermalsmentioning

confidence: 97%

“…; PETM: (Foster et al . ). While there was extinction during the PETM (Thomas ), there is currently no evidence for climate‐related extinction in the marine record.…”

mentioning

confidence: 97%

Determining climate change impacts on ecosystems: the role of palaeontology

Schmidt

2017

Palaeontology

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Climate change is projected to change the ecosystems on land and in the sea at rates that are unprecedented for millions of years. The most commonly used approach to derive projections of how ecosystems will look in the future are experiments on living organisms. By their nature, experiments are unlike the real world and cannot capture the ability of organisms to migrate, select and evolve. They are often limited to a select few species and drivers of environmental change and hence cannot represent the complexity of interactions in 'real' ecosystems. The fossil record is an archive of responses to climate change at a global ecosystem scale. If, and only if, fossil assemblage variation is combined with independent information of environmental changes, sensitives of species or higher taxa to a specific magnitude of change of an environmental driver can be determined and used to inform future vulnerabilities of this species to the same driver. While records are often fragmented, there are time intervals which, when thoroughly analysed with quantitative data, can provide valuable insights into the future of biodiversity on this planet. This review provides an overview of projected impacts on marine ecosystems including: (1) the range of neontological methods, observations and their challenges; and (2) the complementary information that palaeontologists can contribution to this global challenge. I advocate that, in collaborations with other disciplines, we should aim for a strong visibility of our field and the knowledge it can provide for policy relevant assessments of the future.

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The dynamics of global change at the Paleocene-Eocene thermal maximum: A data-model comparison

Bralower

Meißner

Alexander

et al. 2014

Geochem. Geophys. Geosyst.

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We integrate published stable isotopic, chemical, mineralogical, and biotic data from the onset of the Paleocene-Eocene thermal maximum (PETM) at Site 690, Maud Rise in the Southern Ocean. The integrated data set documents a sequence of environmental steps including warming of the ocean from the surface downward, and modification of its thermal and nutrient structure, acidification of the deep ocean, and the onset of continental weathering. The age of the events with respect to the onset of the PETM is calibrated with three different age models. The relative and absolute timing of the steps are compared with simulated temperature, salinity, calcite saturation, and dissolved PO 4 and O 2 , at different depths in the ocean, generated with the UVic Earth System Climate Model of intermediate complexity. The simulation supports the top to bottom transfer of heat and carbon, and generally agrees with age models in terms of the durations of leads and lags in temperature, C-isotope, and biotic responses. Moreover, the simulation shows that stratification increased and the nutricline strengthened at the onset of the PETM. These environmental changes explain the abundance of deep-dwelling nannoplankton and foraminifera during the early part of the event. The modeled calcite saturation is consistent with a harsh deep-sea habitat at the time of the benthic foraminiferal extinction.

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Surviving rapid climate change in the deep sea during the Paleogene hyperthermals

Cited by 64 publications

References 38 publications

Size-dependent response of foraminiferal calcification to seawater carbonate chemistry

Size-dependent response of foraminiferal calcification to seawater carbonate chemistry

Determining climate change impacts on ecosystems: the role of palaeontology

The dynamics of global change at the Paleocene-Eocene thermal maximum: A data-model comparison

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