Mg/Ca thermometry in planktic foraminifera: Improving paleotemperature estimations for <i>G. bulloides</i> and <i>N. pachyderma</i> left

Riveiros, Natalia Vázquez; Govin, Aline; Waelbroeck, C.; Mackensen, Andreas; Michel, Élisabeth; Moreira, Santiago; Bouinot, Thomas; Caillon, Nicolas; Orgun, Ayche; Brandon, Margaux

doi:10.1002/2015gc006234

Cited by 34 publications

(26 citation statements)

References 65 publications

(128 reference statements)

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“…Our ontogenetic calcite‐specific Mg/Ca:temperature relationship yields temperatures indistinguishable from those at the presumed calcification depth for both Bering Sea intervals (6°C at 14.5 ka and 5°C at 17.8 ka). By contrast, while several previously published Mg/Ca:temperature relationships produce temperatures within 2°C of assumed 50 m temperature at 14.5 ka (6°C) (Jonkers et al, ; Nürnberg, ; von Langen et al, ), all result in lower temperatures at 17.8 ka (5°C) by 1–11°C (Figure ) (Jonkers et al, ; Kozdon, Eisenhauer, et al, ; Nürnberg, ; Vázquez Riveiros et al, ; von Langen et al, ). This could be partly the result of a 10% increase in crust calcite in this interval, as described above.…”

Section: Discussionsupporting

confidence: 93%

“…In the Mg/Ca:temperature relationship derived from N. pachyderma cultured at 6, 9, and 12 ° C, Mg/Ca ratios were higher than those estimated from previously published N. pachyderma Mg/Ca:temperature relationships from core tops and sediment traps (Hendry et al, ; Jonkers et al, ; Kozdon, Eisenhauer, et al, ; Nürnberg, ; Vázquez Riveiros et al, ), and different from those in N. incompta (Figure S1 in the supporting information). Our results, using individual shell LA‐ICP‐MS profiles, yield the following relationship (Figure ) where T is temperature:

Mg / Ca ((), mmol / mol) = 0.71 {(\pm 0.2)}^{*} T - 2.49 ((), \pm 1.5)

…”

Section: Resultsmentioning

confidence: 82%

“…The resulting Mg/Ca:temperature relationship cannot be constrained beyond linear, as has been published for other limited temperature ranges studied in N. pachyderma (Hendry et al, ; Kozdon, Eisenhauer, et al, ). However, an exponential fit, as reported elsewhere (Jonkers et al, ; Mashiotta et al, ; Nürnberg, ; Vázquez Riveiros et al, ), may be more appropriate over a larger range of temperature.…”

Section: Resultsmentioning

confidence: 99%

“…1, Nürnberg et al (); Ref. 2, Vázquez Riveiros et al (). Error on temperatures calculated using equation are ±1.6°C, based upon standard error around mean Mg/Ca at each treatment, averaging ±0.2 Mg/Ca mmol/mol.…”

Section: Resultsmentioning

confidence: 99%

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Relationships Between Temperature, pH, and Crusting on Mg/Ca Ratios in Laboratory‐Grown Neogloboquadrina Foraminifera

et al. 2017

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Mg/Ca ratio paleothermometry in foraminifera is an important tool for the reconstruction and interpretation of past environments. However, existing Mg/Ca:temperature relationships for planktic species inhabiting middle‐ and high‐latitude environments are limited by a lack of information about the development and impact of low‐Mg/Ca ratio “crusts” and the influence of the carbonate system on Mg/Ca ratios in these groups. To address this, we cultured individual specimens of Neogloboquadrina incompta and Neogloboquadrina pachyderma in seawater across a range of temperature (6°–12°C) and pH (7.4–8.2). We found by laser ablation inductively couple mass spectrometry analyses of shells that culture‐grown crust calcite in N. incompta had a lower Mg/Ca ratio than ontogenetic calcite formed at the same temperature, suggesting that temperature is not responsible for the low‐Mg/Ca ratio of neogloboquadrinid crusts. The Mg/Ca:temperature relationship for ontogenetic calcite in N. incompta was consistent with the previously published culture‐based relationship, and no significant relationship was found between Mg/Ca ratios and pH in this species. However, the Mg/Ca ratio in laboratory‐cultured N. pachyderma was much higher than that reported in previous core top and sediment trap samples, due to lack of crust formation in culture. Application of our ontogenetic calcite‐specific Mg/Ca:temperature relationships to fossil N. pachyderma and N. incompta from five intervals in cores from the Santa Barbara Basin and the Bering Sea shows that excluding crust calcite in fossil specimens may improve Mg/Ca‐based temperature estimates.

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Section: Discussionsupporting

confidence: 93%

Mg / Ca ((), mmol / mol) = 0.71 {(\pm 0.2)}^{*} T - 2.49 ((), \pm 1.5)

…”

Section: Resultsmentioning

confidence: 82%

Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

See 2 more Smart Citations

Relationships Between Temperature, pH, and Crusting on Mg/Ca Ratios in Laboratory‐Grown Neogloboquadrina Foraminifera

et al. 2017

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“…Thus, it is a good predictor of changes in drainage basin area, but is somewhat less effective at predicting past river discharge, especially when that discharge is strongly influenced by ice-sheet melt. Discharge inferences continue to be aided by the growing database of paleoceanographic proxy records (e.g., Keigwin et al, 2006;Obbink et al, 2010;Williams et al, 2012;HillaireMarcel et al, 2013;Taylor et al, 2014;Gibb et al, 2014;Gil et al, 2015), improved geochemical techniques to produce richer records that also reduce or quantify uncertainties (e.g., Vetter, 2013;Spero et al, 2015;Khider et al, 2015;Vázquez Riveiros et al, 2016), and continuing work to provide quantitative freshwater discharge estimates based on these data (Carlson et al, 2007a;Carlson, 2009;Obbink et al, 2010;Wickert et al, 2013). Particularly important are records of past water isotopes, past water temperatures, and geochemical signatures of provenance.…”

Section: Drainage Histories By Rivermentioning

confidence: 99%

Reconstruction of North American drainage basins and river discharge since the Last Glacial Maximum

Wickert

2016

Earth Surf. Dynam.

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Abstract. Over the last glacial cycle, ice sheets and the resultant glacial isostatic adjustment (GIA) rearranged river systems. As these riverine threads that tied the ice sheets to the sea were stretched, severed, and restructured, they also shrank and swelled with the pulse of meltwater inputs and time-varying drainage basin areas, and sometimes delivered enough meltwater to the oceans in the right places to influence global climate. Here I present a general method to compute past river flow paths, drainage basin geometries, and river discharges, by combining models of past ice sheets, glacial isostatic adjustment, and climate. The result is a time series of synthetic paleohydrographs and drainage basin maps from the Last Glacial Maximum to present for nine major drainage basins -the Mississippi, Rio Grande, Colorado, Columbia, Mackenzie, Hudson Bay, Saint Lawrence, Hudson, and Susquehanna/Chesapeake Bay. These are based on five published reconstructions of the North American ice sheets. I compare these maps with drainage reconstructions and discharge histories based on a review of observational evidence, including river deposits and terraces, isotopic records, mineral provenance markers, glacial moraine histories, and evidence of ice stream and tunnel valley flow directions. The sharp boundaries of the reconstructed past drainage basins complement the flexurally smoothed GIA signal that is more often used to validate ice-sheet reconstructions, and provide a complementary framework to reduce nonuniqueness in model reconstructions of the North American ice-sheet complex.

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Climate and the Evolution of the Ocean: The Paleoceanographic Data

Caley¹,

Riveiros²,

Labeyrie³

et al. 2020

Frontiers in Earth Sciences

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Mg/Ca thermometry in planktic foraminifera: Improving paleotemperature estimations for G. bulloides and N. pachyderma left

Cited by 34 publications

References 65 publications

Relationships Between Temperature, pH, and Crusting on Mg/Ca Ratios in Laboratory‐Grown Neogloboquadrina Foraminifera

Relationships Between Temperature, pH, and Crusting on Mg/Ca Ratios in Laboratory‐Grown Neogloboquadrina Foraminifera

Reconstruction of North American drainage basins and river discharge since the Last Glacial Maximum

Climate and the Evolution of the Ocean: The Paleoceanographic Data

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