Eolian stratigraphic record of environmental change through geological time

The terrestrial sedimentary record provides a valuable archive of how ancient depositional systems responded to and recorded changes in Earth's atmosphere, biosphere, and geosphere. However, the record of these environmental changes in eolian sedimentary successions is poorly constrained and la...

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Bibliographic Details
Published in:Geology (Boulder) 2022-03, Vol.50 (3), p.289-294
Main Authors: Cosgrove, Grace Isabel Emma, Colombera, Luca, Mountney, Nigel P
Format: Article
Language:English
Subjects:
Accumulation
bedding plane irregularities
Biosphere
clastic rocks
Climate change
climate forcing
deflation
depositional environment
Deposits
dune structures
Dunes
Earth
Earth history
Environmental changes
Eolian deposits
eolian features
eolianite
erosion
Fluvial deposits
fluvial environment
Geological time
Geology
Geosphere
Grasses
greenhouse effect
Greenhouses
Groundwater table
Mesozoic
paleoclimatology
paleoenvironment
Pangea
Plant roots
Plants
Precambrian
Proterozoic
reworking
Rifting
sand sheets
sed rocks, sediments
Sediment
Sediment deposits
Sedimentary petrology
sedimentary rocks
sedimentary structures
Stabilizing
statistical analysis
Stratigraphy
subsidence
succession
supercontinents
Tectonics
terrestrial environment
Terrestrial environments
thickness
transport
upper Precambrian
Vegetation
Water table
wind erosion
wind transport
winds
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Summary:The terrestrial sedimentary record provides a valuable archive of how ancient depositional systems responded to and recorded changes in Earth's atmosphere, biosphere, and geosphere. However, the record of these environmental changes in eolian sedimentary successions is poorly constrained and largely unquantified. Our study presents the first global-scale, quantitative investigation of the architecture of eolian systems through geological time via analysis of 55 case studies of eolian successions. Eolian deposits accumulating (1) under greenhouse conditions, (2) in the presence of vascular plants and grasses, and (3) in rapidly subsiding basins associated with the rifting of supercontinents are represented by significantly thicker eolian dune-set, sand-sheet, and interdune architectural elements. Pre-vegetation eolian systems are also associated with more frequent interactions with non-eolian environments. The interplay of these forcings has resulted in dune-set thicknesses that tend to be smallest and largest in Proterozoic and Mesozoic successions, respectively. In the Proterozoic, the absence of sediment-binding plant roots rendered eolian deposits susceptible to post-depositional wind deflation and reworking by fluvial systems, whereby highly mobile channels reworked contiguous eolian deposits. During the Mesozoic, humid greenhouse conditions (associated with relatively elevated water tables) and high rates of basin subsidence (associated with the breakup of Pangea) favored the rapid transfer of eolian sediment beneath the erosional baseline. The common presence of vegetation promoted accumulation of stabilizing eolian systems. These factors acted to limit post-depositional reworking. Eolian sedimentary deposits record a fingerprint of major environmental changes in Earth history: climate, continental configuration, tectonics, and land-plant evolution.
ISSN:0091-7613
1943-2682
DOI:10.1130/G49474.1