Mary E. Edwards
Duane Froese
Lesleigh Anderson
Benjamin V. Gaglioti
Scott L. Cocker
Julie Brigham-Grette
Matthew J. Wooller
Bruce P. Finney
Mark B. Abbott
Alistair J. Monteath
2025
<div id="abspara0010" class="u-margin-s-bottom">Eastern Beringia (Alaska and western Yukon) is an extensive, high-latitude region of North America that remained largely unglaciated throughout the Quaternary. Consequently, its sedimentary deposits preserve long-term environmental records that have intrigued scientists for nearly a century. Recent advances in palaeoecological proxies and dating methods have proved critical in addressing long-standing questions about regional late Quaternary environmental change. At the same time, they have led to new and sometimes controversial hypotheses. This review covers recent discoveries and unresolved questions focused on the period 57,000–10,000 calendar years before C.E. 1950 (cal yr BP).</div><div id="abspara0015" class="u-margin-s-bottom">The middle Wisconsin interstadial (57,000–30,000 cal yr BP) was a period of relative warmth in eastern Beringia, compared with the late Wisconsin (30,000–14,000 cal yr BP). Early in the interstadial occasional<span> </span><i>Picea</i><span> </span>woodland was present amongst widespread shrub tundra. Palaeoecological, sedimentary and isotopic data indicate that climate was cooler and drier than the Holocene, with high rates of aeolian activity. Megafauna typically associated with the ‘mammoth steppe’ ecosystem (woolly mammoth [<i>Mammuthus primigenius</i>], horse [<i>Equus</i>] and steppe-bison [<i>Bison priscus</i>]) were present in some abundance.</div><div id="abspara0020" class="u-margin-s-bottom">The transition towards late Wisconsin cold-stage conditions (35,000–30,000 cal yr BP) coincided with the establishment of the Bering Land Bridge and featured expansion of spatially varied, herbaceous vegetation, sometimes associated with deep active layers. Sedimentary DNA (<i>seda</i>DNA) and macrofossil evidence show vegetation was not a prairie-like grassland, and the term “steppe-tundra” is a better descriptor. Permafrost pore-ice isotopic (δ<sup>18</sup>O) records suggest a step change in one or more climate drivers ca. 30,000 cal yr BP, by which time steppe-tundra was established across eastern Beringia. It remains uncertain whether<span> </span><i>Picea</i><span> </span>survived cold-stage conditions within isolated refugia, or whether it recolonized from south of the Laurentide-Cordilleran ice sheets. Genetic data suggest that<span> </span><i>Picea</i><span> </span>probably survived<span> </span><i>in situ</i>; however, there is no definitive fossil evidence to support this.</div><div id="abspara0025" class="u-margin-s-bottom">The end-Pleistocene transition from steppe-tundra to shrub tundra began ca. 15,000 cal yr BP and took place within decades at local scales. The expansion of woody taxa coincided with rising sea levels, reduced sea-ice extent and an abrupt shift in atmospheric circulation that enhanced precipitation. During this time, Earth's orbital configuration caused high early-summer temperatures and strong seasonality, creating growing conditions very different from today. The vegetation consisted of<span> </span><i>Salix</i><span> </span>and<span> </span><i>Betula</i><span> </span>shrub tundra with open areas of herbs and graminoids. During the deglacial warming trend, the Younger Dryas oscillation (12,800–11,700 cal yr BP) was variably expressed. It is generally evident in records affected by adjacent oceans but can be absent at sites in continental areas.</div><div id="abspara0030" class="u-margin-s-bottom">These past conditions and paleoenvironmental changes have implications for contemporary issues: hypotheses about Pleistocene mammalian extinction; sensitivity of eastern Beringia to major oceanic reorganizations and high-frequency climate variability; the nature of woody plant expansion with climate warming; grazing, hydroclimate and fire as controls over ecosystems; the efficacy of “Pleistocene rewilding” for carbon capture.</div>
application/pdf
10.1016/j.quascirev.2025.109527
en
Elsevier
Late Quaternary environmental change in eastern Beringia
article