Datapages, Inc.Print this page

Click to view article in PDF format.

 

Syndepositional Lateral Migration of Hyperpycnal Lobes in Submarine Ramp Systems. Early Miocene, Austral Basin, Argentina*

By

Juan José Ponce1, Eduardo B. Olivero1, and Daniel R. Martinioni1

 

Search and Discovery Article #50074 (2008)

Posted May 8, 2008

 

*Adapted from extended abstract prepared for AAPG Hedberg Conference, “Sediment Transfer from Shelf to Deepwater – Revisiting the Delivery Mechanisms,” March 3-7, 2008 – Ushuaia-Patagonia, Argentina Note: This is the first of two articles by Ponce et al. concerning Miocene siliciclastics in the Austral Basin (Search and Discovery Article #50073 (2008) and #50074 (2008)).

 

1 Laboratorio de Geología Andina - Centro Austral de Investigaciones Científicas (CADIC-CONICET). Bernardo Houssay 200. (V9410CAB) Ushuaia, Tierra del Fuego, Argentina

 

Introduction

During the Cenozoic the foredeep of the Austral Basin in Tierra del Fuego evolved as a ramp system until the middle Miocene. This ramp system controlled in several ways the hyperpycnal lobe accumulation features in the Upper Cabo Ladrillero Beds (Figure 1; Ponce et al., in review). If compared to more restricted slope breaks; e. g. in some deltaic systems, the larger length of the slope in ramp systems promotes the sustained acceleration of hyperpycnal flows, allowing for the transfer of a large volume of sediments to the deep sea and favoring the deposition of thick sedimentary successions in internal areas of the basin. The main objective of this study is to document the internal arrangement of these hyperpycnal lobe systems - which are the dominant depositional elements within this unit - and to discuss the variability in geometry and sedimentary facies produced by the lateral migration of lobes during one hyperpycnal discharge.

 

uIntroduction

uFigure captions

uUpper Cabo Ladrillero Beds

uReferences

uAcknowledgment

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

uIntroduction

uFigure captions

uUpper Cabo Ladrillero Beds

uReferences

uAcknowledgment

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

uIntroduction

uFigure captions

uUpper Cabo Ladrillero Beds

uReferences

uAcknowledgment

 

Figure Captions

Figure 1. Idealized representation of hyperpycnal lobe arrangements in a submarine ramp (plan view). Note that the different time slices (t1-t3) indicate the lateral migration of lobes during the same hyperpycnal event.

Figure 2. A. “Anomalous” hyperpycnal arrangements. Transition between massive sandstones (Sm), parallel laminated sandstones (Sl), and sandstones with climbing dunes (Scd), and thin heterolithic beds (he). Note the latter truncated by vanishing erosion surfaces (ves), produced in poorly consolidated sediments. B. Outcrop view of the lobes system represented as cross-section a-a’ in Figure 1 showing a typical, complete hyperpycnal succession (hyperpycnite), and the variation in body geometry generated by the lateral migration of the lobes during the same hyperpycnal event (t2 and t3 in Figure 1).

 

Upper Cabo Ladrillero Beds

The lobe deposits of the Upper Cabo Ladrillero Beds consist dominantly of thick sedimentary packages characterized by an initial coarsening-thickening trend, followed by a fining-thinning trend. These packages show transitional and recurrent passages of sedimentary structures - without sharp rheological boundaries - and high concentration of Nothofagus leaves and phytodetritus. Sedimentary successions with similar internal trends were assigned to “typical hyperpycnites” by Mulder et al. (2003). Minor channel systems and slide blocks have been recognized also at the toe of the depositional slope of these lobes at Cabo Ladrillero.

Individual hyperpycnal lobe packages are up to 3-m thick, with sharp base and coarsening-thickening trends followed by fining-thinning trends. The initial coarsening-thickening deposits, accumulated during the waxing stage of the hyperpycnal flow, consist of rhythmical successions of heterolithic, thinly bedded fine-grained sandstones with ripple cross-lamination, wavy and lenticular bedding, and massive mudstones. Dewatering structures and high phytodetrital concentration are commonly observed. The following fine-grained sandstones record transitional passage between horizons with climbing ripples, parallel lamination, and climbing dunes. The deposition of thick massive sandstone beds, with well-preserved Nothofagus leaves occurs when hyperpycnal flows in continuous acceleration were at or above maximum capacity. When maximum flow velocity was attained numerous erosive surfaces are produced. The following fining-thinning succession, originated during the waning stage of the hyperpycnal flow, is characterized by a transitional passage between fine-grained, massive sandstones and sandstones with climbing dunes, parallel lamination, and climbing ripples. Bioturbated mudstones are usually at the uppermost part of this package.

In addition to these coarsening-thickening and then fining-thinning successions, which are interpreted to reflect the waxing-waning stages of the flow, there are other seemingly "anomalous" arrangements that cannot be interpreted as the "normal" succession between the waxing-waning stages of hyperpycnal flows. These "anomalous" arrangements are characterized by thinly bedded, usually convoluted heterolithic horizons that are often truncated by vanishing erosive surfaces. The common transition between these heterolithic horizons with thick, massive sandstones or sandstones with upper-flow regime sedimentary structures; e.g., climbing dunes and parallel lamination, is striking. Transitions between these contrasting lithologies and sedimentary structures are interpreted as the results of the lateral migration of depositional lobes (Figure 2A, B). The overall geometry of the lobe deposits is similar to that resulting from compensation cycles. The latter, however, are generated by different sedimentation events while the lateral migrations of depositional lobes with the described "anomalous" sedimentary arrangements are thought to have formed during one hyperpycnal event. (Figures 1 and 2B).

 

References

Mulder, T., J.P.M. Syvitski, S. Migeon, J.C. Faugères, and B. Savoye, 2003. Marine hyperpycnal flows: initiation, behavior and related deposits. A review: Marine and Petroleum Geology v. 20, p. 861-882.

Ponce J.J., E.B. Olivero, and D.R. Martinioni, in review, Upper Oligocene-Miocene clinoforms of the foreland Austral Basin of Tierra del Fuego, Argentina: Stratigraphy, depositional sequences and architecture of the foredeep deposits. Journal of South American Earth Sciences.

 

Acknowledgment

Financial support provided by CONICET-PIP 5100.

 

Return to top.