Reduced North Atlantic Central Water formation in response to early Holocene ice‐sheet melting

Bamberg, Audrey; Rosenthal, Yair; Paul, André; Heslop, David; Mulitza, Stefan; Rühlemann, Carsten; Schulz, Michael

doi:10.1029/2010gl043878

Cited by 23 publications

(12 citation statements)

References 40 publications

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“…On the T ‐ S plot, we show that the reconstructed densities from samples overlain by ENACW, AAIW and MOW water masses yield significantly different values that within the 0.2 σ θ errors are consistent with the densities of the respective water masses. Indeed, this method has already been used to study the interaction between climate change in the northern North Atlantic and changes in meridional ocean circulation [ Bamberg et al , 2010]. It is noteworthy that in down‐core reconstruction, the errors can be further reduced by using either smoothed or binned data, which is often done in high‐resolution records.…”

Section: Resultsmentioning

confidence: 99%

Temperature calibration of Mg/Ca ratios in the intermediate water benthic foraminifer Hyalinea balthica

Rosenthal

Morley

Barras

et al. 2011

Geochem Geophys Geosyst

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[1] Core top samples from Indonesian and northeast Atlantic depth transects were used to calibrate Mg/Ca and d18 O in tests of the calcitic benthic foraminifer Hyalinea balthica to bottom water temperature between 4°C and 13°C. This shallow infaunal species is primarily abundant in neritic to upper bathyal sediments (<600 m). Both linear and exponential calibrations suggest a temperature sensitivity of ∼12% per°C that is ∼4 times higher than observed in other species of deep-sea benthic foraminifera. Culture experiments support the core top calibration. We find no discernible effect of salinity and saturation on Mg/Ca. 18 O sw and salinity, we apply this calibration to another depth transect from Cape Ghir off NW Africa, which was not included in the calibration. Based on error analysis of the calibration data and this validation test, we show that the uncertainty of reconstructing bottom water temperature and salinity from paired Mg/Ca and d 18 O measurements of H. balthica is better than ±0.7°C and ±0.69 practical salinity scale, respectively. The small uncertainties allow for the reconstruction of seawater density to better than 0.3s units, which is precise enough for the identification of specific water masses and reconstruction of changes in their properties. We propose that the relatively high Mg content and temperature sensitivity of H. balthica might be due to minor, biologically mediated contribution of high-Mg calcite to the primarily low Mg calcite test, which is influenced by the ambient temperature. This hypothesis, if correct, suggests that benthic species with relatively high Mg/Ca may be better suited for deepwater temperature reconstructions than species that have thus far been more commonly used.

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Section: Resultsmentioning

confidence: 99%

Temperature calibration of Mg/Ca ratios in the intermediate water benthic foraminifer Hyalinea balthica

Rosenthal

Morley

Barras

et al. 2011

Geochem Geophys Geosyst

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“…Additionally, two 150-year cooling events [(8.54 ± 0.2) ka BP and (8.24 ± 0.1) ka BP] provide evidence for an abrupt central water response to the drainage of Lake Agassiz (8.54 ka BP) in addition to the maximum AMOC slowdown at 8.2 ka BP (Fig. 2) (Bamberg et al 2010). These observations provide a possible analogue for future effects on meridional heat transfer at central water depth from enhanced Greenland Ice Sheet melting and increases in Arctic freshwater export.…”

Section: Key Findingsmentioning

confidence: 93%

“…During the winter, NAO modulated wind-stress favors the subduction of Subpolar Mode Water, which in turn comprises a large fraction of Eastern North Atlantic Central Water (ENACW) (Poole and Tomczak 1999). Flowing south along the eastern margin of the North Atlantic basin at densities between σ θ = 27.3 and 27.6 kg/m 3 , ENACW circulation thus contributes to the ventilation of the thermocline and provides an 'oceanic tunnel', transmitting subpolar ocean-atmospheric climate signals to lower latitudes between 300 and 900 m water depth throughout the Holocene (Bamberg et al 2010;Morley et al 2011Morley et al , 2014.…”

Section: Introductionmentioning

confidence: 99%

Detecting Holocene Changes in the Atlantic Meridional Overturning Circulation: Integration of Proxy Data and Climate Simulations

Morley

Heslop

Rühlemann

et al. 2014

Integrated Analysis of Interglacial Climate Dynamics (INTERDYNAMIC)

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The contribution of central water circulation to the Atlantic Meridional Overturning Circulation (AMOC) and its role in natural climate variability remain poorly understood. Limits in our knowledge are due to the scarcity of high resolution records from central water depth and the limited abilities of proxy parameters to reconstruct small changes in Holocene central water properties. We addressed these issues by combining paleoclimate modeling of 'fingerprints' (UVic ESCM version 2.8) that identify suitable locations and parameters to reconstruct past central water variability with the development and application of a new Mg/Capaleotemperature calibration for the benthic foraminifera Hyalinea balthica. The presented records demonstrate the important role of central water circulation in communicating regional climate signatures of various forcings (freshwater flux, solar variability, orbital parameters) onto a hemispheric or global scale via crossgyre meridional heat transfer from high to low latitudes.

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“…Determined standard errors for candidate proxies suggest that subsurface temperature variations resulting from the AMO could only be reconstructed with relatively low SNR values. For example, benthic foraminiferal Mg/Ca based temperature estimates have quoted s values of 1.7 K (Lear et al, 2002), 2.4 K (Marchitto et al, 2007) and 0.7 K (Bamberg et al, 2010), suggesting that only the latter case would be capable of producing reconstructions with SNR > 1.…”

Section: Statistical Frameworkmentioning

confidence: 99%

“…It is common for the quality of temperature proxy calibration studies to be assessed using the standard error of estimation (for examples see Saenger et al, 2009;Lear et al, 2002;Marchitto et al, 2007;Bamberg et al, 2010). If T is the observed temperature,T is the temperature predicted by the estimated calibration relationship and N is the number of samples employed in the calibration, the standard error of estimation, s, is given by (Taylor, 1997):…”

Section: Statistical Frameworkmentioning

confidence: 99%

Can oceanic paleothermometers reconstruct the Atlantic Multidecadal Oscillation?

Heslop

Paul

2011

Clim. Past

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Abstract. Instrumental records of the North Atlantic sea surface temperature reveal a large-scale low frequency mode of variability that has become known as the Atlantic Multidecadal Oscillation (AMO). Proxy and modelling studies have demonstrated the important consequences of the AMO on other components of the climate system both within and outside the Atlantic region. Over longer time scales, the past behavior of the AMO is predominantly constrained by terrestrial proxies and only a limited number of records are available from the marine realm itself. Here we use an Earth System-Climate Model of intermediate complexity to simulate AMO-type behavior in the Atlantic with a specific focus placed on the ability of ocean paleothermometers to capture the associated surface and subsurface temperature variability. Given their lower prediction errors and annual resolution, coral-based proxies of sea surface temperature appear to be capable of reconstructing the temperature variations associated with the past AMO with an adequate signal-to-noise ratio. In contrast, the relatively high prediction error and low temporal resolution of sediment-based proxies, such as the composition of foraminiferal calcite, limits their ability to produce interpretable records of past temperature anomalies corresponding to AMO activity. Whilst the presented results will inevitably be model-dependent to some degree, the statistical framework is model-independent and can be applied to a wide variety of scenarios.

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Reduced North Atlantic Central Water formation in response to early Holocene ice‐sheet melting

Cited by 23 publications

References 40 publications

Temperature calibration of Mg/Ca ratios in the intermediate water benthic foraminifer Hyalinea balthica

Temperature calibration of Mg/Ca ratios in the intermediate water benthic foraminifer Hyalinea balthica

Detecting Holocene Changes in the Atlantic Meridional Overturning Circulation: Integration of Proxy Data and Climate Simulations

Can oceanic paleothermometers reconstruct the Atlantic Multidecadal Oscillation?

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