Orbital Signals in Carbon Isotopes: Phase Distortion as a Signature of the Carbon Cycle

Laurin, Jiří; Růžek, Bohuslav; Giorgioni, M.

doi:10.1002/2017pa003143

Cited by 15 publications

(9 citation statements)

References 99 publications

(154 reference statements)

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“…lithological) tuning signals can produce more accurate age models in comparison with age models based on globally integrated isotope records. The latter data are known to produce significant lags relative to eccentricity as a result of highly non-linear feedback mechanisms (Laurin et al, 2017;Pälike et al, 2006b;Zeebe et al, 2017), a result that is confirmed by this study (Table 2). The independent evidence that we provide for using a lithological (proxy) record for the astronomical age calibration of marine sediments yields further support for similar astronomical tuning methods.…”

Section: Evaluation Of Tuning Signalssupporting

confidence: 86%

“…7b; Laurin et al, 2017). On both the initial magnetostratigraphic age model and on the CaCO 3 tuned age model, the phase lag, as visually identified in the filtered records, between the 405 kyr eccentricity cycle and the 405 kyr cycle in δ 13 C increases during the early Miocene (Figs.…”

Section: Astronomical Tuning Using the Benthic Foraminiferal δ 13 C Rmentioning

confidence: 87%

“…Astronomical forcing of organic carbon burial is typically expected in the precessional band because organic carbon burial, notably in the marine realm, depends on clay fluxes and thus hydrology (Berner et al, 1983). However, the residence time of carbon (∼ 100 kyr) is so long (Broecker and Peng, 1982) that this energy is transferred into eccentricity bands (Pälike et al, 2006b;Ma et al, 2011;Laurin et al, 2017). Importantly, while the total marine carbon inventory is driven by ocean chemistry, the phase lag between eccentricity forcing and δ 13 C should primarily be a function of the residence time of carbon in the global exogenic carbon pool (Zeebe et al, 2017).…”

Section: Implications For the Carbon Cyclementioning

confidence: 99%

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Astronomical tunings of the Oligocene–Miocene transition from Pacific Ocean Site U1334 and implications for the carbon cycle

et al. 2018

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Abstract. Astronomical tuning of sediment sequences requires both unambiguous cycle pattern recognition in climate proxy records and astronomical solutions, as well as independent information about the phase relationship between these two. Here we present two different astronomically tuned age models for the Oligocene-Miocene transition (OMT) from Integrated Ocean Drilling Program Site U1334 (equatorial Pacific Ocean) to assess the effect tuning has on astronomically calibrated ages and the geologic timescale. These alternative age models (roughly from ∼ 22 to ∼ 24 Ma) are based on different tunings between proxy records and eccentricity: the first age model is based on an aligning CaCO 3 weight (wt%) to Earth's orbital eccentricity, and the second age model is based on a direct age calibration of benthic foraminiferal stable carbon isotope ratios (δ 13 C) to eccentricity. To independently test which tuned age model and associated tuning assumptions are in best agreement with independent ages based on tectonic plate-pair spreading rates, we assign the tuned ages to magnetostratigraphic reversals identified in deep-marine magnetic anomaly profiles. Subsequently, we compute tectonic plate-pair spreading rates based on the tuned ages. The resultant alternative spreading-rate histories indicate that the CaCO 3 tuned age model is most consistent with a conservative assumption of constant, or linearly changing, spreading rates. The CaCO 3 tuned age model thus provides robust ages and durations for polarity chrons C6Bn.1n-C7n.1r, which are not based on astronomical tuning in the latest iteration of the geologic timescale. Furthermore, it provides independent evidence that the relatively large (several 10 000 years) time lags documented in the benthic foraminiferal isotope records relative to orbital eccentricity constitute a real feature of the OligoceneMiocene climate system and carbon cycle. The age constraints from Site U1334 thus indicate that the delayed responses of the Oligocene-Miocene climate-cryosphere system and (marine) carbon cycle resulted from highly nonlinear feedbacks to astronomical forcing.

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Section: Evaluation Of Tuning Signalssupporting

confidence: 86%

Section: Astronomical Tuning Using the Benthic Foraminiferal δ 13 C Rmentioning

confidence: 87%

Section: Implications For the Carbon Cyclementioning

confidence: 99%

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Astronomical tunings of the Oligocene–Miocene transition from Pacific Ocean Site U1334 and implications for the carbon cycle

et al. 2018

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“…8A, C, D). The difference between the direct filter and the filter of the AM is explained by the residence time of carbon in the ocean, which creates a delay in the response of the  13 C to the orbital forcing (Laurin et al, 2017). In this context of hemipelagic sediments, with the limestone beds originating from exports from neritic environments, the difference may also be due to the change of the carbonate source.…”

Section: Astrochronology Of the The Polymorphum Zonementioning

confidence: 99%

Synchronization of the astronomical time scales in the Early Toarcian: A link between anoxia, carbon-cycle perturbation, mass extinction and volcanism

Ait-Itto

Martínez²,

Price³

et al. 2018

Earth and Planetary Science Letters

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The Late Pliensbachian-Early Toarcian is a pivotal time in the Mesozoic era, marked by pronounced carbon-isotope excursions, biotic crises and major climatic and oceanographic changes. Here we present new high-resolution carbon-isotope and magnetic-susceptibility measurements from an expanded hemipelagic Late Pliensbachian-Early Toarcian section from the Middle Atlas Basin (Morocco). Our new astronomical calibration allows the construction of an orbital time scale based on the 100-kyr eccentricity cycle. The Early Toarcian Polymorphum Zone contains 10 to 10.5 repetitions of the 100-kyr eccentricity both in the carbon-isotope and the magnetic-susceptibility data, leading to an average duration of 1.00 ± 0.08 myr. We also show that the Late Pliensbachian-Early Toarcian global carbon-cycle perturbation has an average duration of 0.24 ± 0.02 myr. These durations are comparable to previous astrochronological time scales provided for this time interval in the most complete 2 sections of the Tethyan area, and longer than what has been provided in condensed sections. Anchoring this framework on published radiometric ages and astrochronological time scales, we estimate that the carbon-cycle perturbation of the Late Pliensbachian-Early Toarcian corresponds with the early phase of the Karoo and Chonke Aike large igneous provinces. Likewise, our new age constraints confirm that the Toarcian oceanic anoxic event is synchronous to the main phase of the Ferrar volcanic activity. Thus, these successive and short phases of the volcanic activity may have been at the origin of the successive phases of the mass extinctions observed in marine biotas in the Pliensbachian and Toarcian times.

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“…The duration of this interval in the El Portón section is calculated at 2.15 myr, in good agreement with the Tethyan area ( Figures 10-12). The difference of 0.04 myr between the two areas may be due to the uncertainties of the correlations between the Andean and the Tethyan areas, and to the fact that the early-late Hauterivian boundary may be located within the non-marine Avilé (Laurin et al, 2017) and from the change in the source of carbonate, which change the phasing of carbonate δ 13 C relative to the insolation (Martinez, 2018). Thus, the reliable…”

Section: Implications For the Next Geological Time Scale In The Earlymentioning

confidence: 99%

Interhemispheric radio-astrochronological calibration of the time scales from the Andean and the Tethyan areas in the Valanginian–Hauterivian (Early Cretaceous)

et al. 2019

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Orbital Signals in Carbon Isotopes: Phase Distortion as a Signature of the Carbon Cycle

Cited by 15 publications

References 99 publications

Astronomical tunings of the Oligocene–Miocene transition from Pacific Ocean Site U1334 and implications for the carbon cycle

Astronomical tunings of the Oligocene–Miocene transition from Pacific Ocean Site U1334 and implications for the carbon cycle

Synchronization of the astronomical time scales in the Early Toarcian: A link between anoxia, carbon-cycle perturbation, mass extinction and volcanism

Interhemispheric radio-astrochronological calibration of the time scales from the Andean and the Tethyan areas in the Valanginian–Hauterivian (Early Cretaceous)

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