A model-data comparison for a multi-model ensemble of early Eocene atmosphere-ocean    simulations: EoMIP

Lunt, Daniel J.; Jones, Tom Dunkley; Heinemann, Malte; Huber, M.; LeGrande, Allegra N.; Winguth, Arne; Loptson, Claire; Marotzke, Jochem; Tindall, Julia; Valdes, Paul J.; Winguth, Cornelia

doi:10.5194/cpd-8-1229-2012

Cited by 88 publications

(162 citation statements)

References 53 publications

(18 reference statements)

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“…The ocean has a mean temperature of 14.7 • C (preindustrial: 5.6 • C) and a global annual mean SST of 24.8 • C, which is in agreement with results of other climate models (Lunt et al, 2012). The northern high latitudes reach maximum SST of 12.8 • Cin Northern Hemisphere summer (JJA), but the sea surface of the central Arctic Ocean does not get warmer than 4 • C. The southern high latitudes show maximum SST of 17.8 • C in austral summer (DJF).…”

Section: Late Paleocene Climate Statesupporting

confidence: 77%

“…Based on Heinemann et al (2009), we use a 560 ppm CO 2 late Paleocene atmospheric forcing to achieve a plausible background climate for the PETM. The applied atmospheric CO 2 concentrations and late Paleocene boundary conditions cause a new equilibrium climate state, which fits the proxy-record-based SST quite well (Lunt et al, 2012). However, the pre-PETM ocean biogeochemistry is not only affected by modifications in temperature and atmospheric conditions at the oceanatmosphere boundary (Archer et al, 2004), but also by alterations in the general ocean physical state.…”

Section: Introductionmentioning

confidence: 90%

“…The pole-to-equator temperature gradient was smaller, displayed in sea surface temperatures (SST) of more than 30 • in the tropics (Pearson et al, 2001) and up to 20 • at high latitudes (Sluijs et al, 2006;Lunt et al, 2012). Deep ocean water masses were up to 10 • warmer compared to modern values (Kennett and Stott, 1991;Zachos et al, 2008;Tripati and Elderfield, 2005).…”

Section: Introductionmentioning

confidence: 94%

“…The late Paleocene climate state in our simulation is characterized by a global annual mean temperature of 23.6 • C (at 2 m in height), using the atmospheric forcing described above (for a comparison, see Lunt et al, 2012). Maximum annual average temperatures are reached along the Equator over Africa, Asia and South America, with temperatures close to 40 • C (Fig.…”

Section: Late Paleocene Climate Statementioning

confidence: 99%

“…Studies of the PETM background climate show a wide range of intermodel variability, using prescribed atmospheric CO 2 concentrations ranging from 2× to 16× pre-industrial CO 2 (Lunt et al, 2012). In previous studies, the late Paleocene ocean biogeochemistry has been addressed exclusively with earth system models of intermediate complexity (EMIC) or box models (e.g., Panchuk et al, 2008;Zeebe et al, 2009;Ridgwell and Schmidt, 2010;Winguth et al, 2012).…”

Section: Introductionmentioning

confidence: 99%

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Ocean biogeochemistry in the warm climate of the late Paleocene

Heinze

Ilyina

2015

Clim. Past

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Abstract. The late Paleocene is characterized by warm and stable climatic conditions that served as the background climate for the Paleocene-Eocene Thermal Maximum (PETM, ∼ 55 million years ago). With respect to feedback processes in the carbon cycle, the ocean biogeochemical background state is of major importance for projecting the climatic response to a carbon perturbation related to the PETM. Therefore, we use the Hamburg Ocean Carbon Cycle model (HAMOCC), embedded in the ocean general circulation model of the Max Planck Institute for Meteorology, MPIOM, to constrain the ocean biogeochemistry of the late Paleocene. We focus on the evaluation of modeled spatial and vertical distributions of the ocean carbon cycle parameters in a longterm warm steady-state ocean, based on a 560 ppm CO 2 atmosphere. Model results are discussed in the context of available proxy data and simulations of pre-industrial conditions. Our results illustrate that ocean biogeochemistry is shaped by the warm and sluggish ocean state of the late Paleocene. Primary production is slightly reduced in comparison to the present day; it is intensified along the Equator, especially in the Atlantic. This enhances remineralization of organic matter, resulting in strong oxygen minimum zones and CaCO 3 dissolution in intermediate waters. We show that an equilibrium CO 2 exchange without increasing total alkalinity concentrations above today's values is achieved. However, consistent with the higher atmospheric CO 2 , the surface ocean pH and the saturation state with respect to CaCO 3 are lower than today. Our results indicate that, under such conditions, the surface ocean carbonate chemistry is expected to be more sensitive to a carbon perturbation (i.e., the PETM) due to lower CO 2− 3 concentration, whereas the deep ocean calcite sediments would be less vulnerable to dissolution due to the vertically stratified ocean.

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Section: Late Paleocene Climate Statesupporting

confidence: 77%

Section: Introductionmentioning

confidence: 90%

Section: Introductionmentioning

confidence: 94%

Section: Late Paleocene Climate Statementioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

Ocean biogeochemistry in the warm climate of the late Paleocene

Heinze

Ilyina

2015

Clim. Past

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Early Paleogene evolution of terrestrial climate in the SW Pacific, Southern New Zealand

Pancost

Taylor

Inglis

et al. 2013

Geochem Geophys Geosyst

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[1] We present a long-term record of terrestrial climate change for the Early Paleogene of the Southern Hemisphere that complements previously reported marine temperature records. Using the MBT 0 -CBT proxy, based on the distribution of soil bacterial glycerol dialkyl glycerol tetraether lipids, we reconstructed mean annual air temperature (MAT) from the Middle Paleocene to Middle Eocene (62-42 Ma) for southern New Zealand. This record is consistent with temperature estimates derived from leaf fossils and palynology, as well as previously published MBT 0 -CBT records, which provides confidence in absolute temperature estimates. Our record indicates that through this interval, temperatures were typically 5 C warmer than those of today at such latitudes, with more pronounced warming during the Early Eocene Climate Optimum (EECO; 50 Ma) when MAT was 20 C. Moreover, the EECO MATs are similar to those determined for Antarctica, with a weak high-latitude terrestrial temperature gradient ( 5 C) developing by the Middle Eocene. We also document a short-lived cooling episode in the early Late Paleocene when MAT was comparable to present. This record corroborates the trends documented by sea surface temperature (SST) proxies, although absolute SSTs are up to 6 C warmer than MATs. Although the high-calibration error of the MBT 0 -CBT proxy dictates caution, the good match between our MAT results and modeled temperatures supports the suggestion that SST records suffer from a warm (summer?) bias, particularly during times of peak warming.

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The impact of climate‐vegetation interactions on the onset of the Antarctic ice sheet

Liakka

Colleoni

Ahrens

et al. 2014

Geophysical Research Letters

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A global coupled atmosphere/vegetation model and a dynamic ice sheet model were employed to study the impact of climate‐vegetation interactions on the onset of the Antarctic ice sheet during the Eocene‐Oligocene transition. We found that the CO2 threshold for Antarctic glaciation is highly sensitive to the prevailing vegetation. In our experiments, the CO2 threshold is less than 280 ppm if the Antarctic vegetation is dominated by forests and between 560 and 1120 ppm for tundra and bare ground conditions. The large impact of vegetation on inception is attributed to the ability of canopies to shade the snow‐covered ground, which leads to a weaker snow albedo feedback and higher summer temperatures. However, the overall effect of canopy shading on the Antarctic climate also depends on features like local cloudiness and atmospheric meridional heat transport. Our results suggest that vegetation feedbacks on climate are crucial for the timing of the Antarctic glaciation.

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A model-data comparison for a multi-model ensemble of early Eocene atmosphere-ocean simulations: EoMIP

Cited by 88 publications

References 53 publications

Ocean biogeochemistry in the warm climate of the late Paleocene

Ocean biogeochemistry in the warm climate of the late Paleocene

Early Paleogene evolution of terrestrial climate in the SW Pacific, Southern New Zealand

The impact of climate‐vegetation interactions on the onset of the Antarctic ice sheet

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