Load cast

Load casts are a pene-contemporaneous deformation structure and form during soft sediment deformation. These interfacial sole markings are very common and represent an expression of a Rayleigh-Taylor instability developing in gravitationally unstable profiles with a denser layer overlying a less-dense hydroplastic layer.

Terminology

The expression "load cast", sometimes also called load structure, is self-evident, referring to a load (the denser layer) sinking into its underlying (less dense) cast (mold). Related to load casts are flame structures, load waves, and anticrests. Extreme developments of load casts are pseudo-nodules and ball-and-pillow structures.

History

Load casts were scientifically reported for the first time by the sedimentologist T. Fuchs in 1895 who called them in German Fließwülste (flow crests, flow warts).^[1] He also reproduced the structure experimentally. Later studies were conducted by H C Sorby in 1908, by P. Kukuk in 1920, and by R R Shrock in 1948.

Description

Wartlike load casts in Hettangian arkoses from the northern Aquitaine Basin

Load casts form on the underside of the overlying denser layer (sands, coarse sands, or gravels), which is superimposed on a less-dense hydroplastic layer (muds, silts or finer sands). The casts take on the form of slight bulges, swellings, deep or rounded sacks, knobby excrescences or highly irregular protuberances. In profile, they appear as a row of flattened, lobe-shaped masses of similar size, shape, and spacing bulging into the lower layer. Between the lobes penetrate flame-like fingers or diaper-like shapes from the underlying less-dense layer. In 3-D, the lobes reveal equant to elongated pillow shapes separated from each other by narrow clefts. In profile, the succession of lobes and fingers can be modelled as a row of semi-circular lobes touching each other at the finger tips; a characteristic wavelength L can consequently be attributed to the lobes. According to the contrast in density and viscosity of the specific layers, the wavelength produced by the instability varies considerably with values generally between a few millimeters and 10 centimeters. Extreme examples have been reported with wavelengths up to 10 meters.

Normally the lobes/pockets and the fingers/diapers are relatively symmetrical about the vertical, but can become asymmetrical in some places. They lean then into a consistent direction, usually interpreted as the direction of the paleocurrent. Asymmetrical load casts are called squamiform or flow casts. It is important to note that in load casts the flame-like fingers never completely pierce the upper layer, whereas in flame structures they do.

Occurrence

Load casts appear in very different depositional environments. They are most common in turbidites, but can also occur in fluvial and shallow-marine settings. Occasionally they appear in lake sediments. They have even been found in layered igneous and pyroclastic successions.^[2] Good examples come from the Borrowdale Volcanic Series in the English Lake District and from the Carboniferous Bude Formation of southwestern England.

Formation

Essential for the formation of load casts is an inverted density layering, which is unstable under gravity, i.e. the potential energy of the layered system is not a minimum. Load casts are an example of the instability of an interface in a gravitationally unstable arrangement of layered sediments.^[3] The instability involved is called a Rayleigh-Taylor instability, whose driving forces are due to buoyancy.

The instability is, however, only latent because it is dependent on liquefaction to become real. The process of liquefaction implies a considerable to almost complete loss of yield strength of the layer involved. This important prerequisite has been appreciated since Sorby in 1908 (and later on by Shrock in 1948), who recognized the hydroplastic condition of the lower layer. On the basis that liquefaction is linked to shock(s), Sims was able in 1975 to correlate the formation of load casts in modern lake deposits with historical earthquakes which had liquefied the sediments.^[4]

References

^ Fuchs T. (1895). In Denkschrift Akademischer Wissenschaften, Wien, 62:369–448
^ Thy P & Wilson JR. (1980). Primary igneous load-cast deformation structures in the Fongen-Hyllingen layered basic intrusion, Trondheim region, Norway. Geol. Mag., 117:363–371.
^ Anketell JM, et al. (1970). On the deformational structures in systems with reversed density gradients. Roczn. Pol. Tow. Geol., 40:3–30.
^ Sims JD. (1975). Determining earthquake recurrence interval from deformational structures in young lacustrine sediments. Tectonophysics, 29:141–152.

Literature

Allen JRL (1984). Sedimentary structures. Their character and physical basis. Elsevier. ISBN 0-444-42232-3
Allen JRL (1985). Principles of Physical Sedimentology. Chapman & Hall. ISBN 0-412-53090-2
Reineck HE & Singh IB (1980). Depositional Sedimentary Environments. Springer-Verlag. ISBN 0-387-10189-6

[1] Fuchs T. (1895). In Denkschrift Akademischer Wissenschaften, Wien, 62:369–448

[2] Thy P & Wilson JR. (1980). Primary igneous load-cast deformation structures in the Fongen-Hyllingen layered basic intrusion, Trondheim region, Norway. Geol. Mag., 117:363–371.

[3] Anketell JM, et al. (1970). On the deformational structures in systems with reversed density gradients. Roczn. Pol. Tow. Geol., 40:3–30.

[4] Sims JD. (1975). Determining earthquake recurrence interval from deformational structures in young lacustrine sediments. Tectonophysics, 29:141–152.

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