Your search keyword '"Pälike, Heiko"' showing total 9 results

1. Very large release of mostly volcanic carbon during the Palaeocene-Eocene Thermal Maximum.

Author

Gutjahr, Marcus, Ridgwell, Andy, Sexton, Philip F., Anagnostou, Eleni, Pearson, Paul N., Pälike, Heiko, Norris, Richard D., Thomas, Ellen, and Foster, Gavin L.

Abstract

The Palaeocene-Eocene Thermal Maximum (PETM) was a global warming event that occurred about 56 million years ago, and is commonly thought to have been driven primarily by the destabilization of carbon from surface sedimentary reservoirs such as methane hydrates. However, it remains controversial whether such reservoirs were indeed the source of the carbon that drove the warming. Resolving this issue is key to understanding the proximal cause of the warming, and to quantifying the roles of triggers versus feedbacks. Here we present boron isotope data-a proxy for seawater pH-that show that the ocean surface pH was persistently low during the PETM. We combine our pH data with a paired carbon isotope record in an Earth system model in order to reconstruct the unfolding carbon-cycle dynamics during the event. We find strong evidence for a much larger (more than 10,000 petagrams)-and, on average, isotopically heavier-carbon source than considered previously. This leads us to identify volcanism associated with the North Atlantic Igneous Province, rather than carbon from a surface reservoir, as the main driver of the PETM. This finding implies that climate-driven amplification of organic carbon feedbacks probably played only a minor part in driving the event. However, we find that enhanced burial of organic matter seems to have been important in eventually sequestering the released carbon and accelerating the recovery of the Earth system. [ABSTRACT FROM AUTHOR]

Published

2017

2. A New Low- to Middle-Latitude Biozonation and Revised Biochronology of Palaeogene Calcareous Nannofossils.

Author

Raffi, Isabella, Agnini, Claudia, Backman, Jan, Fornaciari, Eliana, Rio, Domenico, and Pälike, Heiko

Published

2014

3. The Alano Section: The Candidate GSSP for the Priabonian Stage.

Author

Agnini, Claudia, Backman, Jan, Fornaciari, Eliana, Galeotti, Simone, Giusberti, Luca, Grandesso, Paolo, Lanci, Luca, Monechi, Simonetta, Muttoni, Giovanni, Pälike, Heiko, Pampaloni, Maria Letizia, Pignatti, Johannes, Silva, Isabella Premoli, Raffi, Isabella, Rio, Domenico, Rook, Lorenzo, and Stefani, Cristina

Published

2014

4. A Cenozoic record of the equatorial Pacific carbonate compensation depth.

Author

Pälike, Heiko, Lyle, Mitchell W., Nishi, Hiroshi, Raffi, Isabella, Ridgwell, Andy, Gamage, Kusali, Klaus, Adam, Acton, Gary, Anderson, Louise, Backman, Jan, Baldauf, Jack, Beltran, Catherine, Bohaty, Steven M., Bown, Paul, Busch, William, Channell, Jim E. T., Chun, Cecily O. J., Delaney, Margaret, Dewangan, Pawan, and Dunkley Jones, Tom

Subjects

*ATMOSPHERIC carbon dioxide, *CARBONATES, *CENOZOIC Era, *WEATHERING

Abstract

Atmospheric carbon dioxide concentrations and climate are regulated on geological timescales by the balance between carbon input from volcanic and metamorphic outgassing and its removal by weathering feedbacks; these feedbacks involve the erosion of silicate rocks and organic-carbon-bearing rocks. The integrated effect of these processes is reflected in the calcium carbonate compensation depth, which is the oceanic depth at which calcium carbonate is dissolved. Here we present a carbonate accumulation record that covers the past 53 million years from a depth transect in the equatorial Pacific Ocean. The carbonate compensation depth tracks long-term ocean cooling, deepening from 3.0-3.5?kilometres during the early Cenozoic (approximately 55?million years ago) to 4.6 kilometres at present, consistent with an overall Cenozoic increase in weathering. We find large superimposed fluctuations in carbonate compensation depth during the middle and late Eocene. Using Earth system models, we identify changes in weathering and the mode of organic-carbon delivery as two key processes to explain these large-scale Eocene fluctuations of the carbonate compensation depth. [ABSTRACT FROM AUTHOR]

Published

2012

5. Eocene global warming events driven by ventilation of oceanic dissolved organic carbon.

Author

Sexton, Philip F., Norris, Richard D., Wilson, Paul A., Pälike, Heiko, Westerhold, Thomas, Röhl, Ursula, Bolton, Clara T., and Gibbs, Samantha

Subjects

GLOBAL warming, GREENHOUSE gases, CARBON cycle, GASES, GLOBAL temperature changes, OCEANOGRAPHIC research

Abstract

'Hyperthermals' are intervals of rapid, pronounced global warming known from six episodes within the Palaeocene and Eocene epochs (∼65-34 million years (Myr) ago). The most extreme hyperthermal was the ∼170 thousand year (kyr) interval of 5-7 °C global warming during the Palaeocene-Eocene Thermal Maximum (PETM, 56 Myr ago). The PETM is widely attributed to massive release of greenhouse gases from buried sedimentary carbon reservoirs, and other, comparatively modest, hyperthermals have also been linked to the release of sedimentary carbon. Here we show, using new 2.4-Myr-long Eocene deep ocean records, that the comparatively modest hyperthermals are much more numerous than previously documented, paced by the eccentricity of Earth's orbit and have shorter durations (∼40 kyr) and more rapid recovery phases than the PETM. These findings point to the operation of fundamentally different forcing and feedback mechanisms than for the PETM, involving redistribution of carbon among Earth's readily exchangeable surface reservoirs rather than carbon exhumation from, and subsequent burial back into, the sedimentary reservoir. Specifically, we interpret our records to indicate repeated, large-scale releases of dissolved organic carbon (at least 1,600 gigatonnes) from the ocean by ventilation (strengthened oxidation) of the ocean interior. The rapid recovery of the carbon cycle following each Eocene hyperthermal strongly suggests that carbon was re-sequestered by the ocean, rather than the much slower process of silicate rock weathering proposed for the PETM. Our findings suggest that these pronounced climate warming events were driven not by repeated releases of carbon from buried sedimentary sources, but, rather, by patterns of surficial carbon redistribution familiar from younger intervals of Earth history. [ABSTRACT FROM AUTHOR]

Published

2011

6. Thresholds for Cenozoic bipolar glaciation.

Author

DeConto, Robert M., Pollard, David, Wilson, Paul A., Pälike, Heiko, Lear, Caroline H., and Pagani, Mark

Subjects

GLACIERS, ICE sheets, OLIGOCENE stratigraphic geology, PLIOCENE stratigraphic geology

Abstract

The long-standing view of Earth’s Cenozoic glacial history calls for the first continental-scale glaciation of Antarctica in the earliest Oligocene epoch (∼33.6 million years ago), followed by the onset of northern-hemispheric glacial cycles in the late Pliocene epoch, about 31 million years later. The pivotal early Oligocene event is characterized by a rapid shift of 1.5 parts per thousand in deep-sea benthic oxygen-isotope values (Oi-1) within a few hundred thousand years, reflecting a combination of terrestrial ice growth and deep-sea cooling. The apparent absence of contemporaneous cooling in deep-sea Mg/Ca records, however, has been argued to reflect the growth of more ice than can be accommodated on Antarctica; this, combined with new evidence of continental cooling and ice-rafted debris in the Northern Hemisphere during this period, raises the possibility that Oi-1 represents a precursory bipolar glaciation. Here we test this hypothesis using an isotope-capable global climate/ice-sheet model that accommodates both the long-term decline of Cenozoic atmospheric CO2 levels and the effects of orbital forcing. We show that the CO2 threshold below which glaciation occurs in the Northern Hemisphere (∼280 p.p.m.v.) is much lower than that for Antarctica (∼750 p.p.m.v.). Therefore, the growth of ice sheets in the Northern Hemisphere immediately following Antarctic glaciation would have required rapid CO2 drawdown within the Oi-1 timeframe, to levels lower than those estimated by geochemical proxies and carbon-cycle models. Instead of bipolar glaciation, we find that Oi-1 is best explained by Antarctic glaciation alone, combined with deep-sea cooling of up to 4 °C and Antarctic ice that is less isotopically depleted (-30 to -35‰) than previously suggested. Proxy CO2 estimates remain above our model’s northern-hemispheric glaciation threshold of ∼280 p.p.m.v. until ∼25 Myr ago, but have been near or below that level ever since. This implies that episodic northern-hemispheric ice sheets have been possible some 20 million years earlier than currently assumed (although still much later than Oi-1) and could explain some of the variability in Miocene sea-level records. [ABSTRACT FROM AUTHOR]

Published

2008

7. Centennial-scale climate cooling with a sudden cold event around 8,200 years ago.

Author

Rohling, Eelco J. and Pälike, Heiko

Subjects

*CLIMATOLOGY, *TEMPERATURE, *HOLOCENE paleoceanography, *GEOGRAPHY

Abstract

The extent of climate variability during the current interglacial period, the Holocene, is still debated. Temperature records derived from central Greenland ice cores show one significant temperature anomaly between 8,200 and 8,100?years ago, which is often attributed to a meltwater outflow into the North Atlantic Ocean and a slowdown of North Atlantic Deep Water formation-this anomaly provides an opportunity to study such processes with relevance to present-day freshening of the North Atlantic. Anomalies in climate proxy records from locations around the globe are often correlated with this sharp event in Greenland. But the anomalies in many of these records span 400 to 600?years, start from about 8,600?years ago and form part of a repeating pattern within the Holocene. More sudden climate changes around 8,200?years ago appear superimposed on this longer-term cooling. The compounded nature of the signals implies that far-field climate anomalies around 8,200?years ago cannot be used in a straightforward manner to assess the impact of a slowdown of North Atlantic Deep Water formation, and the geographical extent of the rapid cooling event 8,200?years ago remains to be determined. [ABSTRACT FROM AUTHOR]

Published

2005

8. Author Correction: High-latitude biomes and rock weathering mediate climate–carbon cycle feedbacks on eccentricity timescales.

Author

De Vleeschouwer, David, Drury, Anna Joy, Vahlenkamp, Maximilian, Rochholz, Fiona, Liebrand, Diederik, and Pälike, Heiko

Subjects

WEATHERING, BIOMES

Abstract

A Correction to this paper has been published: https://doi.org/10.1038/s41467-021-21827-8 [ABSTRACT FROM AUTHOR]

Published

2021

9. High-latitude biomes and rock weathering mediate climate–carbon cycle feedbacks on eccentricity timescales.

Author

De Vleeschouwer, David, Drury, Anna Joy, Vahlenkamp, Maximilian, Rochholz, Fiona, Liebrand, Diederik, and Pälike, Heiko

Subjects

CARBON cycle, WEATHERING, TUNDRAS, BIOMES, CARBON isotopes, RESERVOIRS

Abstract

The International Ocean Discovery Programme (IODP) and its predecessors generated a treasure trove of Cenozoic climate and carbon cycle dynamics. Yet, it remains unclear how climate and carbon cycle interacted under changing geologic boundary conditions. Here, we present the carbon isotope (δ13C) megasplice, documenting deep-ocean δ13C evolution since 35 million years ago (Ma). We juxtapose the δ13C megasplice with its δ18O counterpart and determine their phase-difference on ~100-kyr eccentricity timescales. This analysis reveals that 2.4-Myr eccentricity cycles modulate the δ13C-δ18O phase relationship throughout the Oligo-Miocene (34-6 Ma), potentially through changes in continental weathering. At 6 Ma, a striking switch from in-phase to anti-phase behaviour occurs, signalling a reorganization of the climate-carbon cycle system. We hypothesize that this transition is consistent with Arctic cooling: Prior to 6 Ma, low-latitude continental carbon reservoirs expanded during astronomically-forced cool spells. After 6 Ma, however, continental carbon reservoirs contract rather than expand during cold periods due to competing effects between Arctic biomes (ice, tundra, taiga). We conclude that, on geologic timescales, System Earth experienced state-dependent modes of climate–carbon cycle interaction. Climate and carbon cycle interactions during major Earth system changes through the Cenozoic remain unclear. Here, the authors present a combined δ13C-δ18O megasplice for the last 35 Ma which allows them to identify three marked intervals of distinct climate–carbon cycle interactions. [ABSTRACT FROM AUTHOR]

Published

2020