LAUSR

Abstract Sediment gravity flows comprise gravity-driven underflows with a large concentration of suspended load. Along the downslope transport, flow transformations from laminar to turbulent conditions or vice-versa can take place due to several factors, including the incorporation and segregation of clay into, or from the flow. These flow changes may produce hybrid behavior and resulting hybrid event beds. Flow transformation and hybrid events are widely discussed in marine settings, but studies on lacustrine environments are rare. The Ediacaran Western Santa Barbara Rift represents one stage of the development of the Camaqua Basin and includes both cohesive (debrites) and non-cohesive (turbidites) gravity flow deposits associated with braidplain deltas deposited in shallow lake. A range of cohesive and non-cohesive density flow facies is here discussed in terms of triggering mechanism, genetic processes and related flow transformations. The analysis of aerial images combined with outcrop descriptions allowed the identification and mapping of key stratigraphic surfaces and therefore associated systems tracts. Sedimentological and gamma-ray logs, sampling and laboratory analyses (optical microscopy, X-ray diffraction –XRD - and Scanning Electron Microscopy – SEM) were performed to define facies and facies associations. Microscopy was useful to identify vermiculite as an important matrix component. The position of distinct facies within the genetic stratigraphic framework allowed the construction of a generalized facies tract model. The basinward shift of facies indicates three flow transformations, in addition to hybrid flows. Substrate erosion, and ensuing incorporation and fragmentation of mud clasts into turbulent flows caused changes from fluidal to plastic flow rheology. Generalized facies tracts suggest fluvial floods (and resulting hyperpycnal flows) as the triggering mechanism for the subaqueous density flows herein described.