Abstract:
Precession and atmospheric CO₂ modulated
variability of sea ice in the central Okhotsk Sea since 130,000 years ago
Recent reduction in high-latitude sea ice extent demonstrates that sea ice is highly sensitive to external
and internal radiative forcings. In order to better understand sea ice system responses to external orbital
forcing and internal oscillations on orbital timescales, here we reconstruct changes in sea ice extent and
summer sea surface temperature (SSST) over the past 130,000 yrs in the central Okhotsk Sea. We applied
novel organic geochemical proxies of sea ice (IP25 ), SSST (TEX
L₈₆) and open water marine productivity
(a tri-unsaturated highly branched isoprenoid and biogenic opal) to marine sediment core MD01-2414
(53° 11.77´ N, 149° 34.80´ E, water depth 1123 m). To complement the proxy data, we also carried out
transient Earth system model simulations and sensitivity tests to identify contributions of different
climatic forcing factors. Our results show that the central Okhotsk Sea was ice-free during Marine Isotope
Stage (MIS) 5e and the early-mid Holocene, but experienced variable sea ice cover during MIS 2-4,
consistent with intervals of relatively high and low SSST, respectively. Our data also show that the sea
ice extent was governed by precession-dominated insolation changes during intervals of atmospheric
CO₂ concentrations ranging from 190 to 260 ppm. However, the proxy record and the model simulation
data show that the central Okhotsk Sea was near ice-free regardless of insolation forcing throughout the
penultimate interglacial, and during the Holocene, when atmospheric CO₂ was above ∼260 ppm. Past sea ice conditions in the central Okhotsk Sea were therefore strongly modulated by both orbital-driven
insolation and CO₂-induced radiative forcing during the past glacial/interglacial cycle.
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