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Bonini 2001
Bonini, M. (2001). Passive roof thrusting and forelandward fold propagation in scaled brittle-ductile physical models of thrust wedges. Journal of Geophysical Research 106: doi: 10.1029/2000JB900310. issn: 0148-0227.

A set of scaled analogue models was performed to investigate the role of a d¿collement layer in the structural style of fold-and-thrust belts. Silicone putty (SGM 36) has been employed to represent the ductile d¿collement, while frictional material (quartz sand) has been used to simulate the brittle behavior of roof and floor sequences, situated above and below the d¿collement, respectively. In order to explore a wide combination of strength profiles, models have been deformed under five distinct rates of compression (0.15, 0.3, 0.45, 0.6, and 1.5 cm h-1) employing four different thicknesses for the silicone layer (0.1, 0.2, 0.4, and 0.8 cm). Experimental results indicate that roof sequences exhibit two distinct styles of deformation: (1) passive roof duplex (PRD) geometry Banks and Warburton, 1986> and (2) outward propagation of folding (OFP) along the d¿collement Davis and Engelder, 1985>. In PRD geometry the roof sequence remains relatively stationary being underthrust by a wedge-shaped floor duplex, while in OFP, displacement along the floor thrusts is transferred horizontally along the d¿collement layer. Experiments suggest the occurrence of a genetic relationship between shear stresses (at the base of the roof sequence &tgr;b and within the ductile layer &tgr;d) and the development of PRD or OFP geometry. For a given strain rate the deformation pattern of roof sequences depends upon the &tgr;b/&tgr;d ratio as well as the absolute &tgr;b and &tgr;d values. The transition field between OFP and PRD styles has been approximated by curvilinear regression of transition-style experimental data points, with a minimum value of &tgr;b, varying between about 112 and 160 Pa, to enter the PRD field. Syntectonic sedimentation in the molasse basin is found to inhibit development of folding into the foreland but to promote PRD style. Experiments simulate many of the principal characteristics of fold-and-thrust belts developed above a basal evaporite d¿collement, as well as the development of passive roof duplexes at mountain fronts. Shear stress values inferred for many fold-and-thrust belts correlate well the deformation fields predicted by the present experimental study, allowing to propose a simple model describing the mechanical behavior of natural roof sequences underlain by a d¿collement layer. ¿ 2001 American Geophysical Union

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Abstract

Keywords
Structural Geology, Folds and folding, Structural Geology, Mechanics, Structural Geology, Role of fluids, Tectonophysics, Continental contractional orogenic belts
Journal
Journal of Geophysical Research
http://www.agu.org/journals/jb/
Publisher
American Geophysical Union
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