Architecture of Eolian Successions under Icehouse and Greenhouse
Conditions
Boulder, Colo., USA: Anthropogenic climate change is one of the foremost
scientific and societal challenges. In part, our response to this global
challenge requires an enhanced understanding of how the Earth’s surface
responds to episodes of climatic heating and cooling. As historical records
extend back only a few hundred years, we must look back into the ancient
rock record to see how the surface of the Earth has responded to shifts
between icehouse (presence of ice at the Earth’s poles) and greenhouse (no
substantial ice at Earth’s poles) climates in the past.
In their study published last week in GSA Bulletin, Grace
Cosgrove, Luca Colombera, and Nigel Mountney use a novel relational
database (the Database of Aeolian Sedimentary Architecture) to quantify the
response of ancient eolian systems (i.e., wind-dominated environments, such
as sand dune fields) to global climatic shifts between icehouse and
greenhouse climates, as registered in the rock record. They analyzed data
on thousands of geological features that preserved a record of eolian
processes and landforms, from 34 different eolian systems spanning over two
billion years of Earth’s history.
Their results demonstrate statistically that preserved sedimentary
architectures developed under icehouse and greenhouse conditions are
fundamentally different. These differences can be tied to contrasting
environmental conditions existing on Earth’s surface. During icehouse
climates, alternations between glacial and interglacial episodes (caused by
changes in the Earth’s orbit—the so-called Milankovitch cyclicity) resulted
in cycles of glacial-episode accumulation and interglacial deflation.
Greenhouse conditions instead promoted the preservation of eolian elements
in the geological record due to elevated water tables and the widespread
action of biogenic and chemical stabilizing agents, which protected
deposits from wind-driven deflation.
In the context of a rapidly changing climate, the results presented in this
work can help predict the potential long-term impact of climate change on
Earth surface processes.
FEATURED ARTICLE
Quantitative analysis of the sedimentary architecture of eolian
successions developed under icehouse and greenhouse climatic conditions
Grace I.E. Cosgrove; Luca Colombera; Nigel P. Mountney
Contact: Grace Cosgrove, g.i.e.cosgrove@leeds.ac.uk, University of Leeds,
IAG, Leeds, UK
View article:
https://pubs.geoscienceworld.org/gsa/gsabulletin/article-abstract/doi/10.1130/B35918.1/595649/Quantitative-analysis-of-the-sedimentary
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