Abstract
Sedimentary rocks are the archives of environmental conditions and ancient planetary surface processes that led to their formation. Reconstructions of Earth's past surface behaviour from the physical sedimentary record remain controversial, however, in part because we lack a quantitative framework to deconvolve internal dynamics of sediment-transport systems from environmental signal preservation. Internal dynamics of landscapes--a consequence of the coupling between bed topography, sediment transport and flow dynamics (morphodynamics)--result in regular and quasiperiodic landforms that abound on the Earth and other planets. Here, using theory and a data compilation of morphodynamic landforms that span a wide range of terrestrial, marine and planetary depositional systems, we show that the advection length for settling sediment sets bounds on the scales over which internal landscape dynamics operate. These bounds provide a universal palaeohydraulic reconstruction tool on planetary surfaces and allow for quantitative identification of depositional systems that may preserve tectonic, climatic and anthropogenic signals.
Highlights
Sedimentary rocks are the archives of environmental conditions and ancient planetary surface processes that led to their formation
Detangling autogenic dynamics from allogenic forcing in the sedimentary record is difficult, because we lack quantitative metrics to assess where environmental conditions may be preserved in depositional archives
To deduce the scales over which morphodynamics operate, we consider mass balance of dilute sediment transport above an evolving sediment bed that is not limited by sediment supply (Supplementary Note 1)
Summary
Sedimentary rocks are the archives of environmental conditions and ancient planetary surface processes that led to their formation. Using theory and a data compilation of morphodynamic landforms that span a wide range of terrestrial, marine and planetary depositional systems, we show that the advection length for settling sediment sets bounds on the scales over which internal landscape dynamics operate. These bounds provide a universal palaeohydraulic reconstruction tool on planetary surfaces and allow for quantitative identification of depositional systems that may preserve tectonic, climatic and anthropogenic signals. Three cases are shown for different values of the parameter r0 1⁄4 cb=c, which partially determines the advection length scale
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