A 120 000-year record of sea ice in the North Atlantic?

Maffezzoli, Niccoló; Vallelonga, Paul; Edwards, Ross; Saiz‐Lopez, Alfonso; Turetta, Clara; Kjær, Helle Astrid; Barbante, Carlo; Vinther, Bo M.; Spolaor, Andrea

doi:10.5194/cp-15-2031-2019

Cited by 18 publications

(28 citation statements)

References 80 publications

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“…Sea Ice Proxy Evidence from the RECAP Ice Core. To assist the interpretation of our marine sea ice records, we enhanced the temporal resolution of the RECAP Br enr -based sea ice record between 32 and 41 ka, previously presented at a lower resolution for the last 120 ky (32). The Br enr proxy is based on the bromineto-sodium mass ratio of ice normalized to that of seawater, and is considered as reflecting first-year (i.e., seasonal) sea ice conditions in the marine aerosol source area (32, 44, 45) (SI Appendix, Materials and Methods).…”

Section: Resultsmentioning

confidence: 99%

“…Bromine recycling processes occurring over seasonal (first year) sea ice formation add photochemically derived bromine to the sea salt-derived aerosol inventory of the overlying atmosphere, consequently leading to increased Br enr values in snow and ice precipitating nearby (46). Processes associated with aerosol transport and deposition might additionally influence the Br enr signals in ice cores (32,47). Nevertheless, an enhanced Br enr (>1) in Greenland ice cores is considered to reflect extensive seasonal sea ice in the marine aerosol source area (32,45).…”

Section: Resultsmentioning

confidence: 99%

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Rapid reductions and millennial-scale variability in Nordic Seas sea ice cover during abrupt glacial climate changes

Sadatzki

Maffezzoli

Dokken

et al. 2020

Proc. Natl. Acad. Sci. U.S.A.

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Constraining the past sea ice variability in the Nordic Seas is critical for a comprehensive understanding of the abrupt Dansgaard-Oeschger (D-O) climate changes during the last glacial. Here we present unprecedentedly detailed sea ice proxy evidence from two Norwegian Sea sediment cores and an East Greenland ice core to resolve and constrain sea ice variations during four D-O events between 32 and 41 ka. Our independent sea ice records consistently reveal a millennial-scale variability and threshold response between an extensive seasonal sea ice cover in the Nordic Seas during cold stadials and reduced seasonal sea ice conditions during warmer interstadials. They document substantial and rapid sea ice reductions that may have happened within 250 y or less, concomitant with reinvigoration of deep convection in the Nordic Seas and the abrupt warming transitions in Greenland. Our empirical evidence thus underpins the cardinal role of rapid sea ice decline and related feedbacks to trigger abrupt and large-amplitude climate change of the glacial D-O events.

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Rapid reductions and millennial-scale variability in Nordic Seas sea ice cover during abrupt glacial climate changes

Sadatzki

Maffezzoli

Dokken

et al. 2020

Proc. Natl. Acad. Sci. U.S.A.

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“…2). Polar ice core water isotope records are correlated to condensation temperature at the time of precipitation (Dansgaard, 1964;Dansgaard et al, 1973;Craig and Gordon, 1965;Merlivat and Jouzel, 1979;Jouzel and Merlivat, 1984;Jouzel et al, 1997) and integrate across regional ocean and atmospheric circulation patterns and sea surface conditions along the moisture transport pathway (Johnsen et al, 2001;Holme et al, 2019).…”

Section: Introductionmentioning

confidence: 99%

High-frequency climate variability in the Holocene from a coastal-dome ice core in east-central Greenland

et al. 2020

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Abstract. An ice core drilled on the Renland ice cap in east-central Greenland contains a continuous climate record dating through the last glacial period. The Renland record is valuable because the coastal environment is more likely to reflect regional sea surface conditions compared to inland Greenland ice cores that capture synoptic variability. Here we present the δ18O water isotope record for the Holocene, in which decadal-scale climate information is retained for the last 8 kyr, while the annual water isotope signal is preserved throughout the last 2.6 kyr. To investigate regional climate information preserved in the water isotope record, we apply spectral analysis techniques to a 300-year moving window to determine the mean strength of varying frequency bands through time. We find that the strength of 15–20-year δ18O variability exhibits a millennial-scale signal in line with the well-known Bond events. Comparison to other North Atlantic proxy records suggests that the 15–20-year variability may reflect fluctuating sea surface conditions throughout the Holocene, driven by changes in the strength of the Atlantic Meridional Overturning Circulation. Additional analysis of the seasonal signal over the last 2.6 kyr reveals that the winter δ18O signal has experienced a decreasing trend, while the summer signal has predominantly remained stable. The winter trend may correspond to an increase in Arctic sea ice cover, which is driven by a decrease in total annual insolation, and is also likely influenced by regional climate variables such as atmospheric and oceanic circulation. In the context of anthropogenic climate change, the winter trend may have important implications for feedback processes as sea ice retreats in the Arctic.

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“…Seven day long back trajectories calculated with HYSPLIT model over the period 2006-2019 suggest that the higher frequency of trajectories come from the nearby areas with respect to the Renland site ( Figure 1), as also evidenced by Simonsen et al (2019) and Maffezzoli et al (2019) studying insoluble dust and sea ice respectively. In addition to the Renland ice cap surrounding area, the coastal area immediately on the North of the Renland site appears to be the most probable source region.…”

Section: Results From Back-trajectory Analysismentioning

confidence: 85%

“…The core was stored frozen and shipped to Europe, where it was cut at AWI (Alfred-Wegener Institute, Bremerhaven, Germany) and processed at the Centre for Ice and Climate (Niels Bohr Institute, University of Copenhagen, Denmark). The samples analyzed for levoglucosan were collected discretely every 55 cm from a continuous ice core melting system (Bigler et al, 2011) as part of the Continuous Flow Analysis (CFA) campaign conducted at the University of Copenhagen in autumn 2015 (Maffezzoli et al, 2019;Simonsen et al, 2019), while BC and NH 4 + were measured continuously. After collection, the discrete samples were immediately frozen at -20°C and kept in the dark until analysis.…”

Section: Methodsmentioning

confidence: 99%

5 kyr of ﬁre history in the High North Atlantic Region: natural variability and ancient human forcing

Segato

Hidalgo

Edwards

et al. 2021

Preprint

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Abstract. Biomass burning influences global atmospheric chemistry by releasing greenhouse gases and climate-forcing aerosols. There is controversy about the magnitude and timing of Holocene changes in biomass burning emissions from millennial to centennial time scales and, in particular, on the possible impact of ancient civilizations. Here we present a 5 kyr record of fire activity proxies levoglucosan, black carbon and ammonium measured in the RECAP ice core, drilled in the coastal East Greenland and therefore affected by processes occurring in the High North Atlantic Region. Levoglucosan and ammonium fluxes show high levels from 5 to 4.5 kyr followed by an abrupt decline, possibly due to monotonic decline in Northern Hemisphere summer insolation. Levoglucosan and black carbon show an abrupt decline at 1.1 kyr BP (before 2000 AD), suggesting a decline in wildfire regime in the Icelandic territory due to the extensive land clearing caused by Viking colonizers. A minimum is reached at 0.5 kyr BP for all fire proxies, after which levoglucosan and ammonium fluxes increase again, in particular over the last 200 years. We find that the fire regime reconstructed from RECAP fluxes seems mainly related to climatic changes, however over the last millennium human activities might have had a substantial influence controlling the occurrence of fire.

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A 120 000-year record of sea ice in the North Atlantic?

Cited by 18 publications

References 80 publications

Rapid reductions and millennial-scale variability in Nordic Seas sea ice cover during abrupt glacial climate changes

Rapid reductions and millennial-scale variability in Nordic Seas sea ice cover during abrupt glacial climate changes

High-frequency climate variability in the Holocene from a coastal-dome ice core in east-central Greenland

5 kyr of ﬁre history in the High North Atlantic Region: natural variability and ancient human forcing

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