Climate control on banded iron formations linked to orbital eccentricity

Climate control on banded iron formations linked to orbital eccentricity

Astronomical forcing associated with Earth's orbital and inclination parameters ("Milankovitch" forcing) exerts a major control on climate as recorded in the sedimentary rock record, but its influence in deep time is largely unknown. Banded iron formations, iron-rich marine sediments...

Full description

Saved in:
Bibliographic Details
Published in:Nature geoscience 2019-05, Vol.12 (5), p.369-374
Main Authors: Lantink, Margriet L, Davies, Joshua H F L, Mason, Paul R D, Schaltegger, Urs, Hilgen, Frederik J
Format: Article
Language:eng
Subjects:
Climate
Climate control
Control
Cycles
Diagenesis
Earth
Eccentric orbits
Evolution
Formations
Hydrothermal plumes
Inclination
Iron
Marine sediments
Microorganisms
Oceans
Oscillations
Oxidoreductions
Sea level
Sea level fluctuations
Sedimentary rocks
Sedimentation
Sediments
Uranium
Weathering
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Astronomical forcing associated with Earth's orbital and inclination parameters ("Milankovitch" forcing) exerts a major control on climate as recorded in the sedimentary rock record, but its influence in deep time is largely unknown. Banded iron formations, iron-rich marine sediments older than 1.8 billion years, offer unique insight into the early Earth's environment. Their origin and distinctive layering have been explained by various mechanisms, including hydrothermal plume activity, the redox evolution of the oceans, microbial and diagenetic processes, sea level fluctuations, and seasonal or tidal forcing. However, their potential link to past climate oscillations remains unexplored. Here we use cyclostratigraphic analysis combined with high-precision uranium-lead dating to investigate the potential influence of Milankovitch forcing on their deposition. Field exposures of the 2.48-billion-year-old Kuruman Banded Iron Formation reveal a well-defined hierarchical cycle pattern in weathering profile that is laterally continuous over at least 250 kilometres. The isotopic ages constrain the sedimentation rate at 10 m/Myr and link the observed cycles to known eccentricity oscillations with periods of 405 thousand and about 1.4 to 1.6 million years. We conclude that long-period, Milankovitch-forced climate cycles exerted a primary control on large-scale compositional variations in banded iron formations.
ISSN:1752-0894
1752-0908