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Intraplate brittle deformation and states of paleostress constrained by fault kinematics in the central German platform
Intraplate brittle deformation and states of paleostress constrained by fault kinematics in central German platform Payman Navabpour, Alexander Malz, Jonas Kley, Melanie Siegburg, Norbert Kasch, Kamil Ustaszewski PII: DOI: Reference:
S0040-1951(16)30557-1 doi:10.1016/j.tecto.2016.11.033 TECTO 127335
To appear in:
Tectonophysics
Received date: Revised date: Accepted date:
9 June 2016 12 October 2016 21 November 2016
Please cite this article as: Navabpour, Payman, Malz, Alexander, Kley, Jonas, Siegburg, Melanie, Kasch, Norbert, Ustaszewski, Kamil, Intraplate brittle deformation and states of paleostress constrained by fault kinematics in central German platform, Tectonophysics (2016), doi:10.1016/j.tecto.2016.11.033
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Intraplate brittle deformation and states of paleostress constrained by fault kinematics in central German platform
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Payman Navabpoura*, Alexander Malzb, Jonas Kleyc, Melanie Siegburgd, Norbert Kascha,
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Kamil Ustaszewskia
University of Jena, Institute of Geosciences, Burgweg 11, 07749 Jena, Germany.
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Geological Survey of Saxony-Anhalt, Köthenerstraße 38, 06118 Halle, Germany.
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University of Göttingen, Geoscience Center, Goldschmidtstraße 1-3, 37077 Göttingen,
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Germany.
University of Southampton, Ocean and Earth Science Department, Southampton
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d
SO14 3ZH, England.
Corresponding author, e-mail: [email protected]
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*
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Abstract
The structural evolution of Central Europe reflects contrasting tectonic regimes after the Variscan orogeny during Mesozoic – Cenozoic time. The brittle deformation related to each
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tectonic regime is localized mainly along major fault zones, creating complex fracture patterns and kinematics through time with diverging interpretations on the number and succession of the causing events. By contrast, fracture patterns in less deformed domains often provide a pristine structural inventory. We investigate the brittle deformation of a relatively stable, wide area of the central German platform using fault-slip data to identify the regional stress fields required to satisfy the data. In a non-classical approach, and in order to avoid local stress variations and misinterpretations, the fault-slip data are scaled up throughout the study area into subsets of consistent kinematics and chronology for sedimentary cover and crystalline basement rocks. Direct stress tensor inversion was 1
ACCEPTED MANUSCRIPT performed through an iterative refining process, and the computed stress tensors were verified using field-based observations. Criteria on relative tilt geometry and indicators of
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kinematic change suggest a succession of events, which begins with a post-Triassic normal
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faulting regime with σ3 axis trending NE-SW. The deformation then follows by strike-slip
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and thrust faulting regimes with a change of σ1 axis from N-S to NE-SW, supposedly in the Late Cretaceous. Two younger events are characterized by Cenozoic normal and oblique thrust faulting regimes with NW-SE-trending σ3 and σ1 axes, respectively. The fracture
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patterns of both the cover and basement rocks appear to record the same states of stress.
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Keywords: Brittle tectonics; Fault kinematics; Intraplate deformation; Paleostress
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Introduction
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It is a fundamental tenet of plate tectonics that deformation of the Earth’s lithosphere is
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strongly localized along plate margins. Still so, weaker deformation also affects plate interiors. Central Europe has been located within a plate interior since the Variscan orogeny, and its tectonic evolution is commonly interpreted to be related to events at distant plate
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margins (e.g., Sissingh, 2006; Ziegler, 1987). During the Mesozoic and Cenozoic, a distant
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northwestern plate margin evolved from rifting to the fully developed North Atlantic midocean ridge. At the same time, a southern plate margin evolved from rifting over the formation of Alpine Tethys Ocean to subduction and collision (Handy et al., 2010;
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Rosenbaum et al., 2002; Stampfli and Borel, 2002). Both the Atlantic divergent and Tethyan convergent margins are active today, but neither is closer than 1400 km to our study area
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(Fig. 1a).
There is a broad consensus about the general post-Variscan tectonic evolution of Central
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Europe, as reviewed in recent books. A long Permian – Early Cretaceous period of weak extension is followed by contraction in the Late Cretaceous and then again by extension related to the European Cenozoic Rift System (Doornenbal and Stevenson, 2010; Littke et al., 2008; McCann, 2008). However, diverging opinions persist about the number and timing, the kinematics and the causes of tectonic events. Detailed paleostress reconstructions in other regions of the world have revealed links between local deformation and far-field stress in different extensional and contractional settings (e.g., Angelier et al., 1990; Bergerat and Angelier, 2000; Gudmundsson et al., 1996; Navabpour, 2009; Navabpour and Barrier, 2012; Navabpour et al., 2014). A couple of brittle tectonics studies were conducted in Central 3
ACCEPTED MANUSCRIPT Europe, but results often disagree. Some studies find many discrete events, e.g. ten distinct stress fields from Late Variscan to Cenozoic time (Peterek et al., 1997) and six (Vandycke,
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2002) or eight (Coubal et al., 2015) successive stress fields since the Late Cretaceous. Other
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studies interpret only a few tectonic regimes, e.g. two (Lamarche et al., 2003) or three
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(Franzke et al., 2007) events throughout the Mesozoic to Cenozoic time. Possible reasons for these divergent interpretations include different completeness of stratigraphy, temporal and spatial variations in actual stress fields, over interpretation of limited data or poor
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preservation. For instance, Sippel et al. (2009) did not find evidence of Mesozoic extension
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along the southern rim of the Central European Basin and concluded that much evidence must have been lost to overprinting by younger events.
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Furthermore, there is still no consensus on the kinematics of intraplate deformation. Large-
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scale structural and basin geometries were interpreted to indicate bulk dextral transtension
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with an E-W stretching axis during the Mesozoic extension, and bulk dextral transpression with a N-S shortening axis during the following contraction(s) (e.g., Betz et al., 1987; Doornenbal and Stevenson, 2010; McCann, 2008). By contrast, brittle tectonics studies have
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repeatedly found evidence for extension and contraction approximately perpendicular to the main NW-SE-striking faults. The question of kinematics has important implications for the causes of intraplate deformation. The European intraplate shortening has been commonly interpreted to be foreland deformation resulting from a N-directed push exerted by the Alpine collision (e.g., Ziegler and Dèzes, 2006; Ziegler, 1987; Ziegler et al., 1995). Even with dextral transpressive deformation, intraplate kinematics in this scenario only loosely matches plate boundary kinematics. Kley and Voigt (2008) instead proposed that this event has a regionally uniform NNE-SSW shortening direction that closely reflects the convergence of Africa, Iberia and Europe in Late Cretaceous time. 4
ACCEPTED MANUSCRIPT In the present paper, we address the issues listed above by analyzing fault-slip data from a relatively stable, wide area of the central German platform. We stayed away from major fault
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zones to avoid stress variations related to differential fault block rotations. A systematic
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attempt was made to identify the minimum number of regional stress fields required to satisfy
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the data by inverting consistent fault kinematics of the entire area together rather than analyzing individual outcrops separately. Finally, we discuss age constraints for the identified
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stress fields and correlate them with deformation sequences from surrounding areas (Fig. 1b).
Geological setting
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After the end of the Variscan orogeny, a Basin-and-Range type wide rift created the fault-
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bounded Latest Carboniferous to Early Permian ―Rotliegend‖ basins filled with volcanic and clastic rocks (Lützner, 1988). Following the demise of the rift, the Latest Permian Zechstein
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transgression overstepped the Rotliegend basins. The Mesozoic – Cenozoic structural evolution of Central Europe comprises contrasting tectonic regimes (Littke et al., 2008;
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McCann, 2008). A protracted phase of thermal subsidence with intermittent, low-magnitude extension and transtension from the Latest Permian to the early Late Cretaceous was punctuated by more pronounced extension with graben and salt diapir formation in the Late Triassic and Late Jurassic to Early Cretaceous (Betz et al., 1987; Ernst, 1989; Franzke et al., 2007; Kockel, 2002; Tröger and Schubert, 1993). This long period of subsidence was terminated by a phase of contraction, which began and peaked in the Late Cretaceous and persisted into the Early Cenozoic involving inversion of many extensional faults (Clausen and Pedersen, 1999; Danišík et al., 2012; Kley and Voigt, 2008; Kockel, 2002; Malz and Kley, 2012; Otto, 2003; Scheck et al., 2002; Ziegler, 1987). The end of intraplate contraction 5
ACCEPTED MANUSCRIPT was followed by the formation of the European Cenozoic Rift System, which was coeval with Alpine orogeny farther south (Dèzes et al., 2004; Ziegler and Dèzes, 2006; Ziegler, 1992).
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The present-day deformation across large areas of Central Europe is characterized by a NW-
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SE maximum horizontal shortening (Fig. 1a) (Gölke and Coblentz, 1996; Grünthal and
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Stromeyer, 1992; Heidbach et al., 2007; Hinzen, 2003). This requires a substantial change in the state of stress, as documented for segments of the Cenozoic Rift System such as the Upper Rhine Graben (Schumacher, 2002), but poorly constrained in less deformed areas of
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the European plate interior such as the central German platform.
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The study area is located between the Rhenish Massif to the west and the Bohemian Massif to the southeast (Fig. 1b) and mainly covers the Thuringian domain of the central German
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platform (Fig. 2). Over much of its history, this domain was located on the southern rim of
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the Central European Basin (Fig. 1b). During the Late Cretaceous shortening event it became
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separated from surrounding basins through uplift of the Harz Mountains and Thuringian Forest (Thomson and Zeh, 2000; Voigt et al., 2004). These mountains expose low- to highgrade metamorphic rocks of the Variscan orogeny and the associated late- to post-orogenic
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Carboniferous – Permian granite intrusions (Toloczyki et al., 2006). Both the granites and the country rocks are intruded by NW-SE-striking Permian rhyolitic dykes in the Thuringian Forest and discontinuously overlain by locally thick Rotliegend volcanic and clastic rocks (e.g., Franzke and Rauche, 1991; Lützner, 1988; Rieke et al., 2001; Schröder, 1987; Zeh and Brätz, 2004; Zeh et al., 2000). The continuous sedimentary cover of the study area begins with as much as 700 m of Upper Permian Zechstein (Karnin et al., 1996). The Zechstein succession consists of evaporite and carbonate cycles of laterally variable thickness across the central German Platform (Doornenbal and Stevenson, 2010; Reinhardt, 1993). These strata mark the transition to a relatively uniform subsidence that continues into the Mesozoic. The 6
ACCEPTED MANUSCRIPT Mesozoic rocks of the study area consist of an about 1000 m thick succession of limnic, eolian and fluvial sandstone, shale and evaporite of the Lower Triassic Buntsandstein,
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shallow marine carbonate and evaporite of the Middle Triassic Muschelkalk, and shale, marl,
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sandstone and evaporite of the Upper Triassic Keuper (Beutler and Schubert, 1987; Feist-
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Burkhardt et al., 2008). The youngest Mesozoic strata preserved are small remnants of Lower Jurassic open marine shale and sandstone. The Mesozoic stratigraphic succession is locally intruded by NNE-SSW-striking basaltic dykes of Late Oligocene – Early Miocene age
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(Abratis et al., 2007; Lippolt, 1983; Rauche and Franzke, 1990) to the south and west of the
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Thuringian Forest (Fig. 2).
The entire association of pre-Zechstein rocks defines a mechanically competent basement, the
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structures of which are traceable up into the cover rocks in the Thuringian Basin (Malz, 2014;
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Malz and Kley, 2012). However, where thick evaporites are present, the Zechstein strata form
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a potential detachment layer on top of the basement rocks (Holländer, 2000; Nachsel and Franz, 1983). The dominant structures in the Mesozoic cover rocks of the study area are a few map-scale narrow NW-SE-striking faults separated by less deformed, essentially flat-
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lying terrains with horizontal strata (Fig. 2) (Ellenberg, 1992; von Bubnoff, 1953). The NW-SE-striking faults exhibit graben-like down faulted strips of Middle to Upper Triassic strata, suggesting NE-SW extension (Betz et al., 1987; Ernst, 1989; Franzke et al., 2007; Kockel, 2002; Malz, 2014; Malz and Kley, 2012; Tröger and Schubert, 1993). Some of these faults are locally associated with outcrop-scale tight and inclined drag folds, indicating tectonic inversion and contraction superimposed along the same NE-SW direction (Bankwitz et al., 1993; Franzke et al., 1986; Malz, 2014; Malz and Kley, 2012). No map-scale fold structures are associated with the NW-SE-striking faults. The faulted Mesozoic cover rocks are disrupted by the basement uplifts of the Harz Mountains, Thuringian Forest and Slate 7
ACCEPTED MANUSCRIPT Mountains to the north, south and southeast of the Thuringian Basin, respectively (Fig. 2). Minor NNE-SSW-striking faults including those of the Leinetal Graben delimit our study
Inventory of brittle structures
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area to the west.
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For a comprehensive paleostress reconstruction, fault-slip data including spatial orientation of fault planes and associated striae were collected from 93 sites across the study area (Fig. 2).
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Owing to the widespread vegetation cover, data acquisition sites were mainly located in
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active and abandoned quarries and along road cuts. Most of the fault-slip data were collected from sub-horizontal micritic to bioclastic limestone of the Middle Triassic Muschelkalk in the
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cover rocks. Fault-slip data from natural rock exposures are particularly rare. A small number of fault-slip data could be collected from the granitic rocks to evaluate the response of pre-
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existing fracture patterns to the events that postdate the Carboniferous – Permian time, hence approximating the states of stress that affected the Triassic rocks. The criteria used for the sense of slip mostly include calcite slickenfibers and slickolites in the cover rocks, and Riedel shear fractures in the basement rocks. An average magnetic north correction of N002° is applied to the orientation data collected by compass, according to the International Geomagnetic Reference Field (Finlay et al., 2010) for the center of the study area during the data acquisition period. Stereoplots of the fault-slip data are given as supplementary material in the online repository to this article.
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ACCEPTED MANUSCRIPT A common difficulty in interpreting the measurements within the framework of polyphase brittle deformation is related to the heterogeneity of fault-slip data, in terms of their diversity
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in type, spatial orientation and temporal reactivation. This heterogeneity demands appropriate
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means for classification of data into both kinematically and chronologically consistent
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subsets (e.g., Angelier, 1984; Hippolyte et al., 2012; Madritsch, 2015; Navabpour et al., 2007, 2008, 2010, 2011; Saintot and Angelier, 2002; Ustaszewski and Schmid, 2006). The criteria that could help in data separation were relative geometry of fault planes with respect
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to tilted strata and kinematic change indicators on the same fault slickensides. Because the
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study area comprises mostly flat-lying horizontal strata, the relative tilt geometries could be only verified at a limited number of sites where outcrop-scale folded strata were visible.
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Measurement of the bedding planes at these sites yields an azimuth of N121° as the average
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fold axis for the entire study area (Fig. 2, inset). This axis suggests an azimuth of N031° for the orientation of first-order shortening, which we refer to as folding event (fl) hereinafter.
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The kinematic changes were evidenced by several instances of successive striae at many sites. We describe some of the key examples observed in the study area in the following
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paragraphs.
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Relative tilt geometries
At some outcrops, where the strata were locally folded, it was possible to determine the relative pre-, syn- and post-tilt geometries between the faults and bedding planes, based on the Anderson’s theory of faulting (Anderson, 1951). The pre-tilt geometry mainly includes normal and strike-slip faults that have specific angular relationships with respect to tilted strata. The syn-tilt geometry includes bedding-parallel reverse kinematics that form in 9
ACCEPTED MANUSCRIPT flexural slip folding. The post-tilt geometry mostly includes normal and strike-slip faults that have no specific angular relationship with respect to the previously folded strata.
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Examples of pre-tilt geometry can be given for sites 40 and 76. Site 40 provides data of tilted
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normal faults along the Eichenberg-Gotha-Saalfeld Fault Zone (Fig. 2). In the present-day
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orientation, the faults appear as a system of crosscutting low-angle normal and high-angle reverse faults (Fig. 3a). The intersection line of the faults is sub-parallel to the bedding plane,
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suggesting that they are tilted conjugate-like normal faults. The stress field obtained from these fault-slip data indicates inclined σ1 and σ3 axes deviated from vertical and horizontal
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orientations, respectively. Back tilting the fault-slip data around the strike of tilted strata reconstructs the initial geometry and yields a normal faulting regime with vertical σ1 axis.
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Site 76 provides data of tilted strike-slip faults to the southeast of the Finne Fault Zone (Fig.
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2). At this site, there are folded strata containing sub-vertical oblique sinistral strike-slip
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faults with striae parallel to the tilted bedding planes (Fig. 3b). The stress field obtained from these fault-slip data indicates inclined stress axes with σ2 axis deviated from vertical in the present-day orientation. Back tilting the fault-slip data around the strike of the bedding plane
axis.
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reconstructs their initial geometry and yields a strike-slip faulting regime with vertical σ2
An example of syn-tilt geometry can be given for site 21. This site represents overturned flank of a local fold across the Finne Fault Zone (Fig. 2) with bedding-parallel slip planes indicating normal senses of motion (Fig. 3c). The stress field obtained from these fault-slip data is a normal faulting regime with vertical σ1 axis in the present-day orientation. Back tilting the fault-slip data around their strikes to a non-overturned, moderately tilted attitude of the strata reconstructs their typical syn-fold geometry. These back-tilted fault-slip data indicate a thrust faulting regime with vertical σ3 axis. 10
ACCEPTED MANUSCRIPT Examples of post-tilt geometry can be given for sites 40 and 42. At site 40, along the Eichenberg-Gotha-Saalfeld Fault Zone (Fig. 2), a separate set of conjugate-like normal faults
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cut through locally folded strata (Fig. 3d). These faults appear in their typical Andersonian
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geometry (Anderson, 1951) with a horizontal intersection line, regardless the inclination of
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bedding plane. The stress field obtained from these fault-slip data indicates a normal faulting regime with vertical σ1 axis. At site 42, along the northern rim of the Thuringian Forest (Fig. 2), sub-vertical sinistral strike-slip faults with sub-horizontal striae cut through locally folded,
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deeply tilted strata (Fig. 3e). The stress field obtained from these fault-slip data suggests a
Kinematic change indicators
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strike-slip faulting regime with vertical σ2 axis.
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Kinematic changes are evidenced by successive striae on the same fault planes at several sites. The successive striae are of different types in terms of relative chronology. The best instances of successive striae are those that clearly show relative binary chronologies. These
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striae either crosscut or overprint each other with different senses of slip. Some striae twist from one to another, evidencing continuous kinematic change between faulted blocks, which need cautious consideration in paleostress reconstructions. Other instances of striae exhibit disparate kinematics on different parts of the same fault plane with unclear relative chronology.
Instances of successive striae with relative binary chronology mostly include strike-slip and reverse reactivation of pre-existing NW-SE-striking normal faults. A kinematic change from normal to dextral sense of slip was observed at site 17 (Fig. 4a) through slickolites crosscutting calcite slickenfibers on a tilted normal fault plane. At site 52, a fault slickenside 11
ACCEPTED MANUSCRIPT indicates reverse reactivation of a normal fault by calcite slickenfibers crystallized over older slickolites (Fig. 4b). These sites suggest that a NE-SW extension was replaced by contraction.
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Sites 04 and 22 reveal successive striae on fault slickensides sub-parallel to the pre-existing
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normal faults. At site 04, calcite slickenfibers overprinting slickolites indicate sinistral
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reactivation of a thrust fault (Fig. 4c). At site 22, twisted slickolites indicate a kinematic change from dextral to reverse sense of slip (Fig. 4d). These successive striae suggest a reorientation of contraction from N-S to NE-SW, possibly in a continuum of events. This
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interpretation can be confirmed by observation of successive horizontal stylolites in sub-
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horizontal strata at site 73 (Fig. 4e), as well as site 77. These sites are spatially located far from each other to the north and south of the Finne Fault Zone (Fig. 2), respectively. The
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horizontal stylolites independently indicate similar clockwise change in the direction of
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contraction.
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Nevertheless, other instances of kinematic change suggest contrasting reorientation of contraction. At site 08, twisted striae on SW-dipping, steep bedding planes indicate a change from reverse to oblique dextral sense of slip (Fig. 4f). This kinematic change suggests
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counterclockwise reorientation of contraction towards NW-SE. If this interpretation is correct, the change should postdate the folding event because steeply tilted strata are affected by this kinematic change (see also Fig. 3e).
Instances of successive striae with unclear relative chronology exhibit contrasting normal and strike-slip fault slickensides. Site 31 indicates disjunctive normal and sinistral senses of slip on a NE-SW-striking high-angle fault plane (Fig. 4g). The relative chronology is not well understood between these two senses of slip. However, these fault-slip data seem to be geometrically consistent with the pre- and post-tilt orientation of sub-parallel faults observed elsewhere at sites 76 and 40 (Fig. 3b and d, respectively). Hence, the normal component 12
ACCEPTED MANUSCRIPT suggests a NW-SE extension that should postdate both the strike-slip component and the folding event. At site 75, opposite dextral and sinistral strike-slip motions are evidenced by
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slickolites on the same sub-vertical fault planes striking NNW-SSE (Fig. 4h). The stress
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fields obtained from the collected fault-slip data indicate orthogonal NE-SW and NW-SE
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directions of contraction. The relative chronology could not be reliably verified between these fault-slip data. The only observation was that the striae indicating sinistral sense of slip prevail and that sub-parallel sinistral faults appear in post-tilt geometry elsewhere at site 42
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(Fig. 3e). Hence, the sinistral sense of slip should postdate the dextral one.
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In the case of basement rocks, we could find two instances of successive striae. At site 34, there are calcite slickenfibers crystallized on incongruous steps of Riedel shear fractures on a
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SW-dipping fault plane cutting through the granites (Fig. 5a). The calcite slickenfibers
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indicate a reverse sense of slip opposite to that of the Riedel shear fractures. This observation
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suggests inversion of a normal fault under a NE-SW contraction. Another change in fault kinematics is evidenced by twisted striae on sub-vertical NNW-SSE-striking fault planes showing dextral senses of slip within the rhyolites at site 62 (Fig. 5b). The twisted striae
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could be interpreted either as a change of kinematics or as successive increments of strikeslip displacements associated with progressive fault block rotation towards south. The structural location of the outcrop along a map-scale NW-SE-striking fault in southwestern foothills of the Thuringian Forest is in favor of the latter.
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Distribution of deformation
As already explained, the study area widely consists of flat-lying strata (Fig. 2) away from surrounding major deformational zones of the Elbe Fault, Leinetal Graben and Franconian 13
ACCEPTED MANUSCRIPT Lineament (Fig. 1b). This structural configuration limited the possibility to use relative tilt geometries in data separation for every outcrop. The stratigraphy of the study area is such that
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almost all the fault-slip data of the cover rocks are collected from the Middle Triassic
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Muschelkalk (see supplementary material). This uniform lithology made it impossible to
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separate data based on the age of affected rock, except between the limestone of the cover and the granite of the basement. Furthermore, many outcrops provided us with few fault-slip data of different kinematics, which could not be used in stress tensor inversion individually.
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The interpretation of kinematic changes can also be ambiguous, because they might be
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related to either change in stress or differential fault block rotation. However, we should emphasize that most of the successive striae were collected from outcrops with horizontal
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strata where the rocks were not distorted by a local fault zone. While we avoided collecting
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ambiguous data from the narrow fault zones, it was indispensable to verify the relative tilt
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geometries close to these faults.
In order to evaluate the regional significance of the field-based observations and establish the links between the relative tilt geometries and kinematic changes, the fault-slip data are
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separated based on relative chronology and kinematic consistency. The stress axes are calculated for individual outcrops (Table 1) through the right dihedra method of Angelier and Mechler (1977). The orientations of maximum and minimum principal stress axes, σ1 and σ3 respectively, are plotted on separate paleostress maps (Fig. 6). On these maps, the data of the cover strata for which the relative tilt geometry is known are categorized into pre-, syn- and post-tilt geometries (Fig. 6a, b and c). The data obtained from horizontal cover strata, as well as the data from the basement granite, are plotted as ―not tilted‖ stress axes (Fig. 6d, e and f), and categorized based on consistent kinematics with the pre-, syn- and post-tilt geometries.
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ACCEPTED MANUSCRIPT Where available, the relative chronology between two stress axes is given based on the kinematic change indicators of the corresponding fault-slip data (Table 1).
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According to the paleostress maps (Fig. 6), the stress axes of pre- and syn-tilt geometries are
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approximately perpendicular to the map-scale NW-SE-striking faults (Fig. 6a and b) and
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most of the stress axes of post-tilt geometry are parallel to these faults (Fig. 6c). These stress axes have comparable orientations to those obtained from horizontal cover strata, as well as
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from the basement granite (Fig. 6d, e and f). The paleostress maps indicate a homogeneous distribution of the stress axes and do not characterize a specific stress axis to belong to a
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distinct location or lithology. The pre-tilt data (Fig. 6a) mostly include normal and strike-slip faults (Fig. 3a and b). A succession of first NE-SW σ3 then NNE-SSW σ1 is obvious at
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several sites (Fig. 6d), based on the successive striae on the same fault planes (Fig. 4a and b).
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The syn-tilt geometry (Fig. 6b) characterizes a NE-SW orientation for σ1, reconstructed based
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on the bedding-parallel reverse kinematics (Fig. 3c). A succession of first N-S then NE-SW σ1 is observed at several sites (Fig. 6e), based on the successive reactivations on the preexisting normal faults (Fig. 4c, and d). A clockwise change in the orientation of σ1 towards
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NE-SW may be inferred. However, the presence of twisted slickolites (Fig. 4d), as well as the successive horizontal stylolites (Fig. 4e), likely suggest a gradual kinematic change in a continuum of events. In the post-tilt geometry, horizontal σ1 and σ3 axes are mostly oriented NW-SE (Fig. 6c). The corresponding fault-slip data include normal and strike-slip faults, respectively, that cut through previously folded strata (Fig. 3d and e). The relative chronology between these two horizontal stress axes could not be constrained. However, successive striae (Fig. 4f, g and h) suggest that they should postdate the NE-SW-trending σ1 axis (Fig. 6f).
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States of paleostress
For accurate computation of the states of paleostress that might belong to distinct tectonic
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events, we adopted the direct stress tensor inversion method of Angelier (2002), using
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Angelier’s Tector 2000 software. Briefly, the stress tensor inversion is based on maximizing
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the sum of slip shear stress components, i.e. shear stress in the direction of actual slip, for the entire dataset. This sum is calculated as a function of four independent variables of the
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reduced stress tensor, i.e. three angular parameters for orientation of the principal axes of stress 1 2 3 , as well as the ratio of the principal stress magnitude differences
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calculated as 2 3 / 1 3 , giving the orientation and shape of the stress ellipsoid. Hence, to formulate the stress tensor inversion, at least four consistent fault-slip data
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belonging to the same stress field must be available. For a given dataset, the best fitting stress
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tensor is reached by retaining consistent and rejecting inconsistent data through an iterative
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refining process, which minimizes the misfit angle, , between the slip shear stress component and the maximum resolved shear stress on the fault planes (Angelier, 2002).
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A synoptic view of the stereoplots of fault-slip data (see supplementary material) points out that the consistent data for individual fault sets at many sites are very few and less than the minimum threshold needed for the inversion. The direct inversion based on the slip shear stress could not be performed for these individual data. Additionally, at many outcrops of the cover rocks, the data are collected from sub-horizontal Middle Triassic strata (Table 1) with no further evidence for separation based on either the relative geometry or the age of affected rock, but the kinematic consistency. This provides a situation similar to the outcrops of Carboniferous – Permian granite with comparable orientations of stress axes (Fig. 6d, e and f). Therefore, we arrived at scaling up the data to be able to proceed with stress tensor 16
ACCEPTED MANUSCRIPT inversion for the following reasons. First, in order to evaluate the states of stress between the cover and basement rocks, the entire study area is regarded as a single measuring site. The
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fault-slip data of the cover and basement rocks are categorized into separated datasets of
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consistent kinematics. Where applicable, a tilt correction was performed to reconstruct the
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initial orientation of data in the cover rocks before scaling up the data. Second, in order to compute regional stress tensors for the uniform brittle deformation distributed throughout the study area, the separated fault-slip data of the cover rocks are combined together into
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chronologically consistent subsets. In essence, this approach eliminates the effect of
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unsystematic variations of stress axes that may result from local fault block rotations, measurement errors and/or misinterpretations. The reason to this elimination is that
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unsystematic data would be rejected in the refining process, if they do not satisfy the criteria
4.1
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of a best fitting stress tensor (Angelier, 2002).
Kinematic consistency
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Examination of the entire data and separation into consistent kinematics reveals three general best-fitting stress tensors of normal, strike-slip and thrust faulting regimes for the basement and cover rocks, individually (Fig. 7, top box). Details of the computed stress tensors are given in Table 2.
For the basement rocks, the normal faulting regime includes dominant NW-SE-striking dipslip and oblique-slip components. The stress tensor indicates moderate value of ϕ and a horizontal σ3 axis trending N230° (Fig. 7a). The strike-slip faulting regime consists of NWSE- and NE-SW-striking high-angle fault planes with dextral and sinistral components, respectively. These faults yield a stress tensor with moderate value of ϕ and a horizontal σ1 17
ACCEPTED MANUSCRIPT axis trending N183° (Fig. 7b). The thrust faulting regime consists of mostly WNW-ESEstriking low-angle fault planes with dip-slip and oblique-slip components. These faults yield
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a stress tensor with moderate value of ϕ and a horizontal σ1 axis trending N042° (Fig. 7c).
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Unlike the cover rocks, there are no clear geometrical criteria to evaluate the succession of
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events in the basement rocks. However, we know that the thrust faulting postdates the normal faulting, based on our observation of relative chronologies at site 34 (Fig. 5a). Residual faultslip data, which could not fit with the best fitting stress tensors, result in computation of a
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stress tensor with horizontal σ1 axis trending N318° and low value of ϕ indicating
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permutation of σ2 and σ3 axes (Fig. 7d). The stereoplot of the corresponding data shows that the faults have mostly E-W-striking inclined planes with oblique thrust and strike-slip
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components.
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For the cover rocks, the stereoplots related to the best-fitting stress tensors reveal conjugate-
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like normal, strike-slip and thrust fault patterns. The normal faulting regime consists of dominant NW-SE-striking dip-slip faults. The stress tensor indicates moderate value of ϕ and a horizontal σ3 axis trending N036° (Fig. 7e). The strike-slip faulting regime consists of sub-
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vertical NNW-SSE- and ENE-WSW-striking fault planes with dextral and sinistral components, respectively. The stress tensor computed for these faults has a moderate value of ϕ and a horizontal σ1 axis trending N211° (Fig. 7f). The thrust faulting regime has dominant NW-SE-striking low-angle fault planes. These faults yield a stress tensor of moderate ϕ value and horizontal σ1 axis trending N029° (Fig. 7g). Residual fault-slip data, which could not fit with the best fitting stress tensors, result in computation of a stress tensor with horizontal σ1 axis trending N125° and low value of ϕ indicating permutation of σ2 and σ3 axes (Fig. 7h). The stereoplot of the fault-slip data indicates scattered distribution of the slickensides. There
18
ACCEPTED MANUSCRIPT is no obvious systematic pattern for the strike and dip direction of the fault planes and
Chronological consistency
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4.2
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associated striae. Most of the slickensides indicate strike-slip and oblique thrust kinematics.
Examination of the separated fault-slip data for the cover rocks and scaling up the consistent
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geometries and chronologies throughout the study area reveals six major subsets. These subsets include pre-tilt normal and strike-slip faults, dextral reactivation of normal faults,
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syn-tilt bedding-parallel reverse faults, and post-tilt normal faults and strike-slip reactivations
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(Fig. 7, bottom box).
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The pre-tilt normal faulting subset indicates NW-SE-striking conjugate-like faults. Inversion of the fault-slip data of this subset yields a stress tensor with moderate value of ϕ and a
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horizontal σ3 axis trending N214° (Fig. 7i). This stress tensor is very close to that of the entire normal faulting regime (Fig. 7e). The pre-tilt strike-slip faults consist of sub-vertical NW-SE-
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and NE-SW-striking conjugate-like fault planes with dextral and sinistral components, respectively. The stress tensor computed for this subset has a moderate value of ϕ and a horizontal σ1 axis trending N189° (Fig. 7j). This N-S orientation of σ1 is slightly different to that of the entire strike-slip faults of the cover rocks (Fig. 7f). The dextral reactivation of NW-SE-striking normal faults (Fig. 4a) reconstructs a consistent subset for the study area. Inversion of these fault-slip data yields a stress tensor with low value of ϕ and a horizontal σ1 axis trending N013° (Fig. 7k). This low value of ϕ indicates permutation of σ2 and σ3 axes between vertical and horizontal orientations and suggests an interchange between strike-slip and thrust faulting regimes. The syn-tilt fault-slip data reveal conjugate-like NW-SE-striking thrust faults. Inversion of the fault-slip data of this subset yields a stress tensor with moderate 19
ACCEPTED MANUSCRIPT value of ϕ and a horizontal σ1 axis trending N030° (Fig. 7l). This NE-SW orientation of σ1 is parallel to that of the entire thrust faults of the cover rocks (Fig. 7g) and coherent with the
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first-order shortening (Fig. 2). The post-tilt normal faulting subset reveals conjugate-like NE-
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SW-striking fault planes. This subset yields a stress tensor with moderate value of ϕ and a
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horizontal σ3 axis trending N292° (Fig. 7m). The post-tilt fault reactivations constitute a subset of strike-slip faults. Most of these faults belong to the residual subset of the entire dataset (Fig. 7h) and yield a similar stress tensor with horizontal σ1 axis trending N129° (Fig.
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Succession of events
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4.3
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7n).
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Based on the relative chronologies obtained from the brittle structures of the cover rocks (Fig.
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3 and Fig. 4), we used a chronological matrix analysis to establish and illustrate the best possible succession of events (Fig. 8). Briefly, each cell of the matrix denotes a binary chronology between the first and second event for the corresponding row and column,
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respectively. The best solution could be reached when the numbers of binary chronologies accumulate in the compatible area at the upper right half of the matrix, through manual consecutive permutation of the events (Angelier, 1991). One advantage of this matrix analysis is that inconsistent binary chronologies will be filtered out in the incompatible area, statistically. Therefore, any misinterpretations of relative tilt geometry and/or random kinematic changes that may result from differential fault block rotations do not vitiate the prevailing succession. The matrix solution presented here is obtained based on 48 individual binary chronologies between the fault-slip data, as well as between the fault planes and the folded strata, identified at 33 sites and includes 5 incompatible binary chronologies. The 20
ACCEPTED MANUSCRIPT succession of events refers to the stress tensors reconstructed based on the chronologically consistent datasets of the cover rocks (Fig. 7i-n). It starts with the NE-SW extension then
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changes to the N-S and NE-SW contractions and follows by the NW-SE extension and NW-
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SE contraction. The incompatible chronologies of the solution possibly arose from our choice
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to plot the folding event separated from the N-S and NE-SW contractions in the matrix. The solution also shows that the succession of the NW-SE extension and NW-SE contraction is not constrained because of a lack of binary chronology between the corresponding fault-slip
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Discussion
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5
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data.
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The relative chronology of events found in our study area can now be compared to the
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tectonic history deduced from isotopic ages, and to the earlier paleostress studies from surrounding regions. We also discuss the relationships between the stress fields found in the
style.
5.1
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cover and basement rocks and the implications for mechanical stratigraphy and structural
Relative versus absolute chronology
The oldest brittle deformation recorded by the fault-slip data is the normal faulting regime with a NE-SW-trending σ3 axis that was in vigor after deposition and before folding of the Triassic strata (Fig. 7i). The normal faults are tilted wherever the strata are folded (Fig. 3a). We could not find any convincing outcrop-scale evidence for a possible Triassic syn-tectonic deposition associated with this brittle deformation. A lower age limit of extension for some 21
ACCEPTED MANUSCRIPT fault zones of the study area is given by normal faults affecting Lower Jurassic strata (Ernst, 1989). In one locality, an upper age limit is indicated by Upper Cretaceous (Cenomanian)
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strata sealing normal faults (Tröger and Schubert, 1993). A Late Jurassic – Early Cretaceous
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age is well established for the main phase of extension in the NW-SE-trending Lower Saxony
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Basin (Betz et al., 1987; Kockel, 2002), about 200 km northwest of our study area (Fig. 1b). Extensional regimes in the Harz Mountains are attributed to Late Triassic – Early Jurassic and Early Cretaceous at about 226-180 and 125-90 Ma, respectively (Franzke et al., 2007),
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based on K-Ar and Rb-Sr isotopic ages of authigenic hydrothermal vein and fault gouge
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mineralization (Franzke et al., 1996; Haack and Lauterjung, 1993; Hagedorn and Lippolt, 1993; Schneider et al., 2003). Taken together, these data suggest that the oldest extension
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event we observe is bracketed between the (Late Triassic to) Early Jurassic and Early
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Cretaceous.
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The next states of stress revealed by fault-slip data are the strike-slip and thrust faulting regimes (Fig. 7j and l, respectively). The strike-slip event occurred before the folding event with a N-S-trending σ1 axis (Fig. 3b) and reactivated the pre-existing NW-SE-striking normal
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faults with dextral components (Fig. 4a and Fig. 7k). Zulauf (1992, 1993) reconstructed a NS-trending σ1 axis at the western border of the Bohemian Massif to be of Early Cretaceous age, based on K-Ar dating of fault gouge. The state of stress then switched to the thrust faulting regime evidenced by kinematic change from dextral to reverse on the NW-SEstriking normal faults (Fig. 4b and d) and by bedding-parallel flexural slip (Fig. 3c). This change was associated with clockwise rotation of the σ1 axis to the NE-SW orientation during the folding event (Fig. 4e). Stratigraphic data constrain a Coniacian – Paleocene age for the tectonic inversion across the Lower Saxony and Subhercynian Cretaceous basins (Betz et al., 1987; Otto, 2003; Voigt et al., 2004; Voigt et al., 2006; von Eynatten et al., 2008). According 22
ACCEPTED MANUSCRIPT to fission track analyses (Danišík et al., 2010; Thomson et al., 1997; Thomson and Zeh, 2000; Vamvaka et al., 2014), a Late Cretaceous age (ca. 110-70 Ma) can be attributed to
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exhumation of the basement rocks and, by inference, to inversion resulting from the NE-SW
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contraction (Franzke et al., 2007; Kley and Voigt, 2008).
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The two younger states of stress that appear in post-fold geometry (Fig. 3d and e) are associated with reactivation of the earlier fracture patterns. A normal faulting regime with
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NW-SE-trending σ3 axis (Fig. 7m) is possibly characterized by reactivation of pre-existing tilted strike-slip faults (Fig. 4g). An oblique thrust faulting regime with NW-SE-trending σ1
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axis (Fig. 7n) is documented by strike-slip reactivation of pre-existing fault planes (Fig. 4f and h). Considering the Coniacian – Paleocene age for the folding event, these states of stress
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should represent brittle tectonic events of Cenozoic age. The NW-SE extension is
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perpendicular to the general strike of Tertiary basaltic dykes (Fig. 2) that are integral parts of
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the Cenozoic Rift System (Fig. 1b). According to K-Ar and Ar-Ar ages reported from southwest of the Thuringian Forest, the basaltic rocks belong to the Late Oligocene – Early Miocene, ca. 26-10 Ma (Abratis et al., 2007; Lippolt, 1983). NW-SE contraction is reported
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to have affected the Late Cretaceous strata (Sippel et al., 2009) to the northwest of our study area and has the same orientation of the maximum horizontal shortening as the present-day stress field (Fig. 1a). This youngest stress field should have been established after emplacement of the basaltic dykes described above. It is possibly coeval with successive basaltic dyke intrusion and syn-sedimentary tectonic activity within the Rhine Graben during the Miocene – Pliocene (Illies, 1975; Rauche and Franzke, 1990; Schumacher, 2002).
23
ACCEPTED MANUSCRIPT 5.2
Local versus regional paleostress
The NE-SW extension affecting the Triassic strata of Thuringia is regionally reported from
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surrounding areas such as the northern border of the Harz Mountains, southwest of the
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Thuringian Forest and the western border of the Bohemian Massif (Fig. 9a) (Franzke et al.,
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2007; Peterek et al., 1997; Rauche and Franzke, 1990). According to our paleostress reconstruction, this event is evidently characterized by the pre-fold normal faulting regime
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with moderate value of ϕ and vertical σ1 axis (Fig. 7i). Nevertheless, contrasting deformation and interpretation also exist. For example, Sippel et al. (2009) obtained a local normal
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faulting regime with NW-SE-trending σ3 axis and low value of ϕ that has affected only the Middle Triassic rocks along a major zone of deformation at the northern tip of the Leinetal
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Graben (Fig. 9a). Although the low value of ϕ indicates possible permutation between
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horizontal σ2 and σ3 axes, i.e. bidirectional extension here, but the authors did not document
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brittle structures that clearly indicate the NE-SW extension. The Late Cretaceous – Paleocene inversion and folding has been attributed to the NE-SW
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contraction, as recorded in fault-slip data from the Harz Mountains, southwest of the Thuringian Forest and the Bohemian Massif (Fig. 9b) (Coubal et al., 2015; Franzke et al., 2007; Peterek et al., 1997; Rauche and Franzke, 1990). This orientation is coherent with orientation of one generation of horizontal tectonic stylolites of presumably Late Cretaceous age (Kley, 2013; Kley and Voigt, 2008; Kurze and Necke, 1979). However, a distinct prefold N-S shortening of strike-slip and oblique thrust faulting was reported from the Lower Rhine Graben and the Osning Thrust bordering the Lower Saxony Basin in the south (Saintot et al., 2013; Vandycke, 2002). This pre-fold strike-slip faulting could not be reconstructed along the major thrust fault of the northern Harz Mountains. Sippel et al. (2009) obtained a general N-S- to NE-SW-trending horizontal σ1 axis for a state of stress with low value of ϕ, 24
ACCEPTED MANUSCRIPT denoting permutation of σ2 and σ3 axes along the Elbe Fault Zone (Fig. 9b). Our observations suggest reorientation of σ1 axis from N-S to NE-SW through a change from strike-slip to
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thrust faulting regime (Fig. 7j and l, respectively), possibly in a continuum of events through
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an intervening stress state characterized by low value of ϕ (Fig. 7k). We found little evidence
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of post-fold strike-slip faulting indicating NE-SW contraction. This corroborates the observation that the Late Cretaceous – Paleocene inversion occurred in a predominantly thrust faulting regime. A similar reorientation and sequential change in the state of stress is
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also reported from the Holy Cross Mountains in the Carpathian foreland of southeastern
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Poland (Lamarche et al., 2002). Hence, both the change in stress regime and reorientation of σ1 axis from N-S to NE-SW seem to be of regional scale, either due to clockwise rotation of
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the far-field stress or readjustment of shortening to an optimum orientation perpendicular to
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the strike of pre-existing structures.
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The stress fields attributed to the Cenozoic Rift System represent horizontal σ3 axes of various orientations (Fig. 9c). Post-inversion normal faulting regimes with N-S-trending σ3 axes are reported from the Osning Thrust of the Lower Saxony Basin and from the Lusatian
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Thrust of the Bohemian Massif (Coubal et al., 2015; Saintot et al., 2013). Our fault-slip data indicate a post-fold normal faulting regime with NW-SE-trending σ3 axis (Fig. 7m). This stress axis is close to the σ3 axis of Miocene normal faulting reported from southwest of the Thuringian Forest (Rauche and Franzke, 1990). By contrast, Vandycke (2002) obtained a normal faulting regime with NE-SW-trending σ3 axis along the Lower Rhine Graben, and Sippel et al. (2009) measured an oblique normal faulting regime with low value of ϕ at northern tip of the Leinetal Graben, indicating permutation between NE-SW- and NW-SEtrending σ3 and σ2 axes, respectively. Farther south, fault-slip data along the Upper Rhine Graben indicate a normal faulting regime with an E-W-trending σ3 axis (Bergerat, 1987; 25
ACCEPTED MANUSCRIPT Villemin and Bergerat, 1987). Apart from the relatively stable area of Thuringia, the various orientations of horizontal σ3 axis seem to be consistent with and approximately perpendicular
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to the local structural trends (Fig. 9c). Nevertheless, Lopes Cardozo and Behrmann (2006)
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argue for a transtensional opening of the Upper Rhine Graben under a NW-SE-trending
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horizontal σ1 axis, which is more likely coherent to the present-day states of stress (Fig. 1a and Fig. 9d).
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The structural setting of the Rhine Graben within the regional intraplate stress field is already interpreted as passive rifting in response to the build-up of Alpine collision associated with
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counterclockwise rotation of the horizontal σ1 axis from NE-SW to NW-SE (Ahorner, 1975; Dèzes et al., 2004; Illies, 1975; Peterek et al., 1997; Rauche and Franzke, 1990). Coubal et al.
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(2015) reconstructed the stress reorientation in oblique thrust and strike-slip faulting regimes
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along the Lusatian Thrust of the Bohemian Massif. Our post-fold NW-SE-trending horizontal
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σ1 axis belongs to a stress tensor with moderate to low value of ϕ (Fig. 7n), indicating a strike-slip to oblique thrust faulting regime (Fig. 9d). This state of stress is consistent with the results of Sippel et al. (2009) from the Lower Saxony Basin. According to in-situ stress
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measurements and earthquake focal mechanisms (Grünthal and Stromeyer, 1992; Heidbach et al., 2010), the present-day Central Europe is characterized by a NW-SE-trending horizontal σ1 axis (Fig. 1a), with deformation mainly localized along major fault zones (Ahorner, 1975; Illies, 1975). However, in contrast to our findings in the central German platform, inversion of earthquake fault plane solutions indicate that the state of stress is mainly strike-slip along the Upper Rhine Graben with permutation between σ1 and σ2 axes, i.e. oblique normal faulting, towards the Lower Rhine Graben (Fig. 9d) (Hinzen, 2003; Homuth et al., 2014).
26
ACCEPTED MANUSCRIPT 5.3
Cover versus basement deformation
Surveys on the inherited basement structures in the central German platform reveal two
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prominent orthogonal NW-SE- and NE-SW-striking fault sets that have been active in
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Carboniferous – Permian times (Fielitz, 1992; Matte, 1991; Rieke et al., 2001; Scheck et al.,
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2002; Schröder, 1987; Wilson et al., 2004). Our fault-slip data collected from a small number of granite outcrops in the Thuringian Forest indicate that fault sets parallel to these strikes
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have dextral and sinistral strike-slip components, respectively, with the NW-SE-striking fault set indicating additional normal and reverse components on inclined fault planes. We do not
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have any age criteria for the fault-slip data. However, correlation of the data between the basement and cover rocks (Fig. 7a-h) indicates similar fault patterns and kinematics. This
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similarity in brittle deformation implies that the fault patterns of the cover rocks could be
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induced by reactivation of pre-existing basement structures under the subsequent stress fields.
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This could be the case where the map-scale NW-SE-striking faults of the basement displace the Zechstein layer and the corresponding fault can be traced up into the cover rocks in the Thuringian Basin (Fig. 2) (Malz, 2014; Malz and Kley, 2012). Seismic profiles across the
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Lower Saxony Basin confirm the involvement of pre-Permian basement in both the extension and inversion of the Mesozoic structures (Baldschuhn et al., 2001; Betz et al., 1987).
The structural style observed in the Thuringian Basin differs from that described by Otto (2003) for the Elbe Fault Zone, across which a thick-skinned deformation with vertical basement displacements in the central part changes to a thin-skinned deformation where Zechstein detaches the cover from an unaffected basement farther north. Franzke et al. (2007) argue that the Zechstein evaporites act as a detachment layer and provide mechanical decoupling between the basement and cover rocks north of the Harz Mountains. The change from an exclusively thick-skinned structural style in Thuringia to a mixed thick- and thin27
ACCEPTED MANUSCRIPT skinned style farther north is very likely due to the northward increasing thickness of Zechstein evaporites. Local to regional observations suggest that the presence of salt-related
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structures strongly depends on distribution of different Zechstein cycles (e.g., Doornenbal
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and Stevenson, 2010; Reinhardt, 1993). The first cycle of Zechstein, the Werra cycle, is
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mostly flat-lying and thicker in our study area than to the north, with minor extent of salt structures that retrace the underlying basement structures (Hoppe, 1960). The second cycle of Zechstein, the Stassfurt cycle, which is extremely ductile (Nachsel and Franz, 1983) and
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acted as the main decoupling horizon for detached structures in northern central German
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platform (Holländer, 2000), roughly dwindles towards south across our study area. Hence, the contradictory results could be partly explained by the differences in mechanical stratigraphy.
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Nevertheless, we would rather interpret the similar fracture patterns of the basement and
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cover in terms of local versus regional aspects of deformation. Whereas the evolution of local
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structures strongly depends on the mechanical stratigraphy, the regional stress fields affect the entire stratigraphy regardless of lithological contrasts (Gunzburger and Magnenet, 2014). Hence, scaling up the consistent fault-slip data of the Triassic cover strata across a wide area
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fades out local variations in fracture patterns and results in computation of comparable stress tensors to that of the underlying Carboniferous – Permian basement (Fig. 7). The normal faulting stress tensors of the basement and cover (Fig. 7a and e) have very close orientations of stress axes and values of ϕ (Table 2). The strike-slip faults of the basement (Fig. 7b) yield a stress tensor close to that of the pre-tilt strike-slip faults of the cover (Fig. 7j), indicating a N-S-trending σ1 axis. The thrust faults of the basement and cover provide similar stress tensors with NE-SW-trending σ1 axes (Fig. 7c and g). We interpret that these observations likely reflect the reorientation of σ1 concomitant with the change from strike-slip to reverse kinematics rather than synchronous different shortening directions in the basement and cover 28
ACCEPTED MANUSCRIPT rocks (Hecht et al., 2003). The residual fault-slip data that did not fit with other best fitting stress tensors result in similar stress tensors for both the basement and cover (Fig. 7d and h).
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In the regional scale, these data characterize fault reactivations under the post-tilt NW-SE-
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trending σ1 axis (Fig. 7n). Although the states of stress of the basement could be attributed to
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the Late Variscan crustal deformation (Zulauf, 1993), we assume that the Mesozoic –
Conclusions
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6
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Cenozoic events may have overprinted the earlier brittle deformation.
In this study, we analyzed the post-Triassic brittle deformation of a relatively stable area of
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the central German platform to reconstruct the changes in far-field stress through time. In a
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non-classical approach, we scaled up the fault-slip data collected throughout the study area
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into large subsets of consistent kinematics and chronology. This approach minimized the role of local fault block rotations and misinterpretations, thus allowing us to deduce regional states of stress. Our results reveal a succession of events whose chronology is constrained by
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relative tilt geometries and kinematic change indicators obtained from the Triassic strata. The oldest event recorded represents a normal faulting regime with NE-SW-trending σ3 axis. This event was followed by strike-slip and thrust faulting regimes concomitant with reorientation of σ1 axis from N-S to NE-SW, supposedly during the Late Cretaceous inversion. Two younger events postdate the inversion and involve reactivation of pre-existing fractures by a normal faulting regime with NW-SE-trending σ3 axis and an oblique thrust faulting regime with NW-SE-trending σ1 axis. The succession of events is coherent with the general Mesozoic – Cenozoic tectonic evolution of Central Europe. The fracture patterns of the basement rocks appear to record the same states of stress as the cover strata. This observation 29
ACCEPTED MANUSCRIPT suggests uniform stress transmission throughout the brittle upper crust, despite the presence of rheologically ductile rocks of Zechstein, which have locally acted as detachment layer
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between the basement and cover. A correlation of the brittle deformation between the
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surrounding structural domains confirms that the state of stress is variable and/or overprinted
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by younger events in the vicinity of major zones of deformation. The numerous discrete states of stress reconstructed in some researches along major faults seem unlikely to evidence distinct tectonic events separated in time, unless dating of syn-kinematic fault minerals is
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provided.
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Acknowledgements
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This study was accomplished through financial support of the German Research Foundation
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(DFG) under the research grant no. NA1165/2-1 ―Stress Field Evolution in a Plate Interior‖. The fieldwork was partly covered by projects INFLUINS no. 03IS2091 and OPTIRISS no. 2012FE9080, funded by the German Federal Ministry of Education and Research (BMBF)
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and by the Thuringian Development Bank (TAB), respectively. We thank TLUG Weimar, especially A. Nestler, and LAGB Sachsen-Anhalt, K. Stedingk, for their kind and prompt support in accessing the visited quarries. J.-F. Groth, D. Turner and T. Knörrich assisted during the fieldwork. Detailed comments by D. Delvaux and an anonymous reviewer, as well as constructive remarks by the editor Ph. Agard, contributed towards improving this manuscript.
30
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Fig. 1. Location of the study area within the regional tectonic framework. (a) Plate kinematics affecting Western Eurasia. Nubia – Eurasia plate convergence in Eurasia-fixed reference frame after Nocquet and Calais (2004). North America – Eurasia plate divergence after DeMets et al. (1990). SHmax is average orientation of the present-day maximum horizontal shortening for central German platform (after Heidbach et al., 2010; Tesauro et al., 2006). Shaded relief map is based on digital elevation data of USGS-EROS Centre (http://eros.usgs.gov). (b) Main structural elements of Central Europe, simplified after Kley and Voigt (2008) and Dèzes et al. (2004). Abbreviations: CEB, Central European Basin; EFZ, Elbe Fault Zone; FL, Franconian Lineament; HM, Harz Mountains; LG, Leinetal Graben; LRG, Lower Rhine Graben; LSB, Lower Saxony Basin; LT, Lusatian Thrust; OT, Osning Thrust; TF, Thuringian Forest; URG, Upper Rhine Graben.
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Fig. 2. Geological map of the study area in central German platform, simplified after Toloczyki et al. (2006), illustrating distribution of measurement sites for fault-slip data collection. EGS, Eichenberg-Gotha-Saalfeld Fault Zone. Stereoplot indicates lower hemisphere equal area projection of best-fitting great circle (gray girdle) through the poles of bedding planes indicated by solid dots (n, number of data). Convergent black arrows indicate deduced first-order shortening perpendicular to b-axis of local folds. Orientations are given as dip/azimuth in degrees. Details on geographic coordinates, lithology and orientation of strata for the measurement sites, as well as stereoplots of the collected fault-slip data are given as supplementary material in the online repository to this article.
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Fig. 3. Tilt correction for the fault-slip data of cover rocks. (a) Tilted conjugate-like normal faults on a flank of folded strata. (b) Tilted strike-slip fault plane, characterized by striae parallel to the bedding plane. (c) Overturned limb of a local anticline, with marked bedding-parallel flexural slip. (d) Conjugate-like normal faults cutting through previously tilted strata. (e) Sub-vertical strike-slip fault plane cutting through steeply tilted, folded strata. Stereoplots indicate selected fault-slip data of each outcrop and are equal area projection of the lower hemisphere, including magnetic north (marked by small M). Numbers at top left corner of stereoplots refer to locality of measurement site indicated in Fig. 2. Faults are shown by great circles, including striae as solid dots and slip arrows with double arrows referring to relative strike-slip component and single arrows referring to relative motion of the hanging-wall. Dashed great circles are 41
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bedding planes. Isolated solid and open dots are poles to the bedding and fault planes, respectively. Back tilting is performed by rotation of the fault planes around a horizontal axis parallel to the strike of local bedding plane. Stress axes are determined based on right dihedra method of Angelier and Mechler (1977), and marked as 5-, 4and 3-tined stars for σ1, σ2 and σ3, respectively.
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Fig. 4. Fault kinematic change in the cover rocks. (a) Successive normal and dextral striae evidenced by slickolites overprinting calcite slickenfibers. (b) Successive normal and reverse striae characterized by calcite slickenfibers overprinting slickolites. (c) Successive reverse and sinistral striae indicated by calcite slickenfibers overprinting tectonic groove marks, possibly on a tilted normal fault (shown in gray). (d) Successive striae evidencing kinematic change from dextral to reverse, possibly on a 43
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pre-existing normal fault (shown in gray). (e) Successive horizontal stylolites indicating clockwise change in the direction of contraction. (f) Successive striae evidencing kinematic change from reverse to dextral on steeply tilted bedding plane. (g) Normal striae on a tilted sinistral fault slickenside. (h) Contrasting dextral and sinistral slickolites on a sub-vertical fault plane. Single white and black arrows on the pictures refer to the 1st and 2nd relative chronologies, respectively, indicated by the corresponding numbers on the stereoplots. Convergent and divergent double arrows refer to direction of contraction and extension, respectively, determined based on right dihedra method of Angelier and Mechler (1977). Other description of stereoplots as in Fig. 3.
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Fig. 5. Fault kinematic changes in the basement rocks. (a) Reverse reactivation of a normal fault evidenced by calcite slickenfibers crystallized on incongruous steps of Riedel shear fractures. Note that, in this case, the white and black arrows respectively refer to the 1st and 2nd chronology of slip of the footwall, as the picture is taken from underside of the hanging-wall. (b) Twisted striae on a sub-vertical fault plane suggest successive increments of dextral strike-slip motion and fault block rotation under the same contraction. The 1st and 2nd chronologies on the stereoplots refer to relative motion of the hanging-wall in both cases. Other descriptions of stereoplots as in Fig. 3 and Fig. 4.
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Fig. 6. Paleostress maps for the study area. Horizontal maximum and minimum principal stress axes, σ1 and σ3, are given based on right dihedra method of Angelier and Mechler (1977). The data for which a relative tilt geometry could be reconstructed 46
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(Fig. 3) are categorized as pre-, syn- and post-tilt geometries (a, b and c). The data obtained from horizontal strata, as well as the basement granite, are categorized into consistent kinematics with and presented in parallel to the relative tilt geometries as ―not tilted‖ stress axes (d, e and f). Numbers next to the stress axes indicate relative binary chronology based on successive striae of the corresponding fault-slip data (Fig. 4). Details of the stress tensors are given in Table 1. Background geology as in Fig. 2.
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Fig. 7. Stress tensors for consistent fault-slip datasets. The top box indicates stereoplots of the fault-slip data separated from the entire datasets of the basement and cover rocks based on kinematic consistency. The bottom box indicates stereoplots of the fault-slip data of the cover rocks separated based on consistent chronology and kinematics. Stress tensors are computed based on direct inversion method of Angelier (2002) and given as the orientation of σ1, σ2 and σ3 axes, with 60, 75 and 90% confidence ellipses, 48
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azimuthal confidences in gray curves and the ratio of stress magnitude differences ϕ. Other descriptions of stereoplots as in Fig. 3 and Fig. 4. Details of the stress tensors are given in Table 2.
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Fig. 8. Chronological matrix analysis of events, based on Angelier (1991). Rows and columns refer to the first and second binary chronology, respectively. Numbers are counts of each binary chronology observed throughout the study area. Compatible area characterizes the binary chronologies that are consistent with the given order of the events. Letters refer to the corresponding stress tensors of the cover rocks given in Fig. 7 (i, j, k, l, m, n); ―fl‖ refers to the folding event (Fig. 2). Simplified stereoplots are given for visual appraisal of the events.
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Fig. 9. Post-Triassic stress field evolution in Central Europe. (a) Early Jurassic – Early Cretaceous normal faulting prior to folding of strata. (b) Late Cretaceous – Paleocene strike-slip and thrust faulting before and during inversion of earlier normal faults. (c) Oligocene – Early Miocene normal faulting after folding. (d) Late Miocene – Quaternary stress fields. States of stress and approximate age of events are compiled after: Be, Bergerat (1987); Ra, Rauche and Franzke (1990); Pe, Peterek et al. (1997); Va, Vandycke (2002); Hi, Hinzen (2003); Lo, Lopes Cardozo and Behrmann (2006); Fr, Franzke et al. (2007); Si, Sippel et al. (2009); Sa, Saintot et al. (2013); Ho, Homuth et al. (2014); Co, Coubal et al. (2015); Pr, present study (bold arrows). Background structures as in Fig. 1b. 51
ACCEPTED MANUSCRIPT Table 1. Stress tensors for separated fault-slip data of individual sites. Stress tensors
Long. E
Lithology
Bedding
Fault-slip n
03
50.94192
11.54044
Muschelkalk
Bh
Nr
03
04
51.05900
11.70806
Muschelkalk
Bn 105/22N
Ss
13
Ss
04
Chronology σ1
Pre-tilt 1st
σ2
σ3
ϕ
005/76
184/14
274/00
0.55
195/09
053/79
286/07
0.54
2nd
035/19
206/70
304/03
0.46
10
51.11917
10.01889
Muschelkalk
Bn 139/24E
Ss
SC R
Site Lat. N
T
Geology
IP
Location
05
Pre-tilt
175/01
275/84
085/05
0.50
11
51.11667
10.02167
Muschelkalk
Bn 108/48N
Nr
05
Pre-tilt
011/75
121/05
213/14
0.49
14
51.11389
10.04250
Muschelkalk
Bi 106/80S
Ss
05
Syn-tilt
218/30
101/39
334/37
0.49
15
51.11306
10.05778
Muschelkalk
Bn 115/13S
Ss
05
252/18
038/68
158/11
0.50
16
51.05972
09.98806
Muschelkalk
Bn 119/28S
Nr
02
025/86
128/01
218/04
0.50
Ss
05
187/06
040/83
278/04
0.50
Nr
17
Pre-tilt 1st
121/85
302/05
212/00
0.48
Ss
04
Pre-tilt 2nd
203/02
304/78
112/12
0.50
Iv
03
Syn-tilt
208/05
117/11
323/78
0.50
196/14
051/73
288/09
0.50
05
50.83750
10.91472
Muschelkalk
Bn 030/36E
Ss
08
51.07750
09.95806
Muschelkalk
Bn 130/50S
Iv
09.95111
Muschelkalk
MA
D
51.06389
Bn 121/33S
TE
17
Syn-tilt
222/42
106/26
354/37
0.49
06
Syn-tilt 1st
212/01
122/11
308/79
0.52
298/24
043/31
177/49
0.55
06
2nd
NU
Ss
06
Pre-tilt
51.05667
11.71083
Muschelkalk
Bn 097/16S
Ss
03
21
51.22889
11.30000
Muschelkalk
Bi 117/64N
Ss
02
Pre-tilt
203/07
007/83
113/02
0.50
Iv
09
Syn-tilt 1st
015/12
284/07
164/76
0.50
Iv
02
057/06
324/31
157/59
0.50
Nr
02
091/82
297/07
207/03
0.50
Ss
07
1st
019/04
278/69
111/20
0.51
Iv
09
2nd
212/03
302/06
093/83
0.48
Ss
07
1st
203/03
300/65
112/25
0.58
Iv
04
2nd
218/05
308/05
081/83
0.50
215/22
359/64
119/14
0.49
026/57
173/29
272/15
0.51
23
51.01553
51.10911
AC
22
CE P
19
11.70011
11.70514
Muschelkalk
Muschelkalk
Bh
Bh
2nd
24
51.11128
11.71308
Muschelkalk
Bh
Ss
03
26
51.11194
09.86000
Muschelkalk
Bn 012/54E
Nr
03
Iv
21
035/05
302/33
134/57
0.58
012/76
129/07
221/13
0.50
Post-tilt
27
51.06111
10.00056
Muschelkalk
Bh
Nr
02
29
50.57194
10.51861
Muschelkalk
Bn 104/32S
Iv
08
Syn-tilt
023/29
119/11
229/58
0.50
31
50.45556
10.44806
Muschelkalk
Bn 117/22S
Ss
17
Pre-tilt 1st
018/02
115/79
287/11
0.50
Iv
05
Syn-tilt
226/03
135/08
338/82
0.50
52
ACCEPTED MANUSCRIPT
33
50.67139
50.62707
10.66306
10.71105
Lithology
Granite
Granite
Bedding
-
-
Fault-slip n
Chronology σ1
σ2
σ3
ϕ
Nr
03
Post-tilt 2nd
140/65
039/05
306/24
0.50
Ss
07
168/16
284/56
069/29
0.49
Iv
03
045/25
139/09
248/63
0.51
Ss
10
160/13
292/72
067/13
0.51
Nr
05
325/08
056/07
0.47
06
326/79
135/11
225/02
0.48
05
316/01
053/80
226/10
0.54
06
221/04
128/33
318/57
0.50
186/79
Ss
10
230/02
338/82
140/07
0.50
Iv
18
221/03
311/04
097/85
0.54
Nr
03
213/82
015/08
105/02
0.49
Nr
12
064/81
324/02
234/09
0.50
Ss
10
195/11
344/77
103/06
0.52
02
285/03
020/58
193/32
0.54
215/02
102/84
305/05
0.51
261/84
125/04
034/04
0.46
130/04
229/65
038/25
0.49
34
50.63037
10.71425
Granite
-
Nr
35
50.52792
10.67708
Granite
-
Ss
10.69840
Muschelkalk
Granite
Bh
-
MA
50.63215
10.45083
50.62028
10.43582
Muschelkalk
Bh
Ss
32
40
50.92972
10.73694
Muschelkalk
Bn 124/39N
Nr
08
Ss
08
Nr
10
Post-tilt
258/86
016/02
106/04
0.49
Iv
08
Syn-tilt
251/00
341/29
160/61
0.53
Ss
02
Post-tilt
121/10
013/60
217/27
0.50
Iv
04
032/23
302/00
211/67
0.49
Nr
07
130/84
303/06
033/01
0.51
Ss
06
040/03
267/85
129/03
0.50
Ss
04
331/05
208/80
062/08
0.50
174/04
287/79
084/10
0.50
50.79278
CE P
43
50.77000
10.77083
10.88472
AC
42
TE
Ss
39
D
37
50.58722
NU
Iv 36
T
32
Long. E
Stress tensors
IP
Site Lat. N
Geology
SC R
Location
Muschelkalk
Muschelkalk
Bn 139/67E
Bh
Pre-tilt 1st 2nd
44
50.49640
10.60185
Muschelkalk
Bh
Ss
03
46
50.55236
10.63193
Muschelkalk
Bf
Iv
07
Syn-tilt
242/05
152/01
051/85
0.45
47
50.55360
10.63305
Muschelkalk
Bf
Iv
15
Syn-tilt
208/04
117/19
309/71
0.53
48
50.66833
10.68452
Granite
-
Iv
06
034/23
300/10
187/64
0.52
Nr
03
089/60
334/14
237/26
0.50
001/04
222/84
091/04
0.49
50
50.64338
10.69451
Granite
-
Ss
04
52
51.18092
10.34109
Muschelkalk
Bh
Nr
04
1st
053/82
297/03
206/07
0.49
Iv
07
2nd
201/05
110/09
322/80
0.51
53
ACCEPTED MANUSCRIPT
51.34485
10.49187
Lithology
Muschelkalk
Bedding
Bh
Fault-slip n
230/73
128/04
0.48
Ss
02
126/11
279/78
035/05
0.49
Iv
09
1st
188/00
098/39
278/51
0.50
Ss
04
040/01
302/81
130/09
0.50
04
129/06
281/84
0.49
188/03
278/03
058/86
0.43
Muschelkalk
Bh
Iv
57
51.06704
10.27026
Muschelkalk
Bn 148/14E
Iv
58
50.91328
11.21780
Muschelkalk
Bh
Nr
Nr
05
Pre-tilt
063/87
268/02
178/01
0.52
Iv
04
Pre-tilt
001/11
093/10
224/75
0.50
03
Syn-tilt
209/12
300/07
056/75
0.50
03
50.31306
10.51856
Muschelkalk
Bh
1st
141/75
307/15
038/03
0.50
05
2nd
012/08
279/16
128/72
0.49
Nr
04
1st
192/75
291/02
021/15
0.50
Iv
12
2nd
003/04
272/05
134/84
0.49
07
217/03
353/86
127/03
0.49
51.49552
10.38614
Muschelkalk
Bn 018/29E
Ss
07
221/19
056/71
313/05
0.49
62
50.51756
10.68438
Rhyolite
-
Iv
02
038/07
308/01
212/82
0.49
Ss
03
215/09
316/53
118/36
0.50
Nr
03
101/43
279/47
010/01
0.57
Iv
06
170/15
079/02
341/75
0.50
Nr
05
340/83
091/03
182/07
0.51
Ss
18
024/05
283/64
116/26
0.46
Iv
05
206/09
296/04
048/80
0.49
Ss
03
211/05
013/84
121/02
0.50
Ss
03
272/03
026/82
182/07
0.50
213/18
119/11
359/69
0.50
66
51.12507
51.09367
CE P
65
50.64378
11.48074
11.70657
AC
63
TE
Ss
61
D
60
MA
Iv
02
NU
Bn 134/43N
2nd
039/03
Iv Muschelkalk
ϕ
037/16
10.31443
11.10458
σ3
07
51.20324
50.74185
σ2
Ss
55
59
Chronology σ1
T
53
Long. E
Stress tensors
IP
Site Lat. N
Geology
SC R
Location
11.64241
Zechstein
Muschelkalk
Muschelkalk
Bh
Bn 112/12S
Bn 112/20S
71
51.12100
11.55956
Muschelkalk
Bn 117/80S
Iv
02
72
51.20839
11.67153
Muschelkalk
Bn 072/12S
Ss
02
114/02
013/80
204/10
0.50
73
51.19906
11.59680
Muschelkalk
Bn 172/15E
Ss
06
210/05
011/85
120/02
0.50
74
50.99357
11.82502
Muschelkalk
Bh
Ss
14
014/02
278/70
105/19
0.53
Iv
03
238/04
328/02
080/86
0.47
Ss
03
1st
015/01
274/82
105/08
0.50
Ss
05
2nd
118/07
309/83
208/01
0.50
Ss
07
185/02
082/84
275/06
0.50
75
76
50.93801
50.95144
12.03288
11.97187
Zechstein
Bh
Buntsandstein Bf
Post-tilt
Pre-tilt
54
ACCEPTED MANUSCRIPT Location
Geology
Stress tensors
Long. E
Lithology
Bedding
Fault-slip n
Chronology σ1
σ2
σ3
ϕ
77
10.63671
Muschelkalk
Bn 137/20S
Nr
08
Pre-tilt 1st
287/81
154/06
063/07
0.51
Ss
03
2nd
172/10
072/43
273/45
0.50
Ss
10
1st
017/18
253/60
115/23
0.52
Iv
12
210/02
308/77
0.52
04
292/06
063/80
0.50
51.35243
10.57243
Muschelkalk
Bh
Iv
81
51.24872
10.23531
Muschelkalk
Bh
Nr
IP
78
120/13
05
1st
098/88
312/02
222/01
0.50
02
2nd
036/13
129/14
265/70
0.50
136/01
266/89
046/01
0.45
Syn-tilt 2nd
201/07
82
51.15563
10.28585
Muschelkalk
Bf
Ss
SC R
51.40684
T
Site Lat. N
85
50.70506
11.23834
Muschelkalk
Bh
Ss
04
027/01
133/84
297/05
0.50
87
50.79847
11.30925
Muschelkalk
Bh
Nr
08
073/80
328/02
238/09
0.50
Iv
02
222/02
312/05
108/84
0.48
Iv
03
208/12
298/00
029/78
0.50
Iv
03
186/10
089/30
293/58
0.50
02
Post-tilt
MA
NU
Iv
50.83196
11.22312
Muschelkalk
Bh
89
50.82264
11.46522
Muschelkalk
Bh
90
50.79982
11.60964
Muschelkalk
Bh
Ss
02
109/02
224/85
019/05
0.50
91
50.80273
11.60465
Muschelkalk
Bh
Nr
08
223/78
131/00
041/12
0.50
Iv
03
208/03
299/02
064/87
0.50
Bn 138/55W Iv
15
223/13
315/07
074/75
0.49
Nr
11
1st
126/81
295/09
025/02
0.50
Ss
04
2nd
007/11
266/44
107/44
0.49
Nr
04
099/62
290/28
198/05
0.50
Iv
07
214/09
305/04
057/80
0.50
50.88012
TE
11.51573
Muschelkalk
CE P
93
50.89175
11.53530
AC
92
D
88
Muschelkalk
Bh
Syn-tilt
Bedding is given as strike/dip: Bh, horizontal; Bn, tilted; Bf, folded; Bi, overturned. Fault-slip: Nr, normal; Iv, reverse; Ss, strikeslip. n, number of fault-slip data. Orientation of stress axes (σ1≥σ2≥σ3) is given as azimuth/plunge in degrees. ϕ, ratio of stress magnitude differences defined as ϕ=(σ2−σ3)/(σ1−σ3).
55
ACCEPTED MANUSCRIPT
n
σ1
σ2
σ3
ϕ
α
a
30
018/77
139/07
230/11
0.35
26±24
b
46
183/18
326/68
089/12
0.44
T
Table 2. Stress tensors for consistent fault-slip datasets.
c
22
042/12
133/06
250/77
0.36
d
12
318/03
215/74
049/15
0.13
e
138
126/85
306/05
036/00
0.38
16±13
f
251
211/04
348/85
121/04
0.48
12±13
g
261
029/03
299/01
194/87
0.49
17±16
h
69
125/01
221/77
035/13
0.20
24±24
i
115
117/85
304/05
214/01
0.48
15±11
j
61
189/05
023/85
279/01
0.49
09±09
k
30
013/04
281/26
112/63
0.18
23±17
l
163
030/01
300/00
209/89
0.53
13±10
m
23
158/76
024/10
292/10
0.47
16±10
n
47
233/85
038/05
0.34
23±24
Basement
MA
D
TE 129/01
NU
Cover Fig. 7
IP
23±14
SC R
Fig. 7
21±12 34±17
AC
CE P
n, number of fault-slip data. Orientation of stress axes (σ1≥σ2≥σ3) is given as azimuth/plunge in degree. ϕ, ratio of stress magnitude differences defined as ϕ=(σ2−σ3)/(σ1−σ3). α, average misfit angle between actual slip and maximum resolved shear stress in degrees (acceptable for α<25°).
56
ACCEPTED MANUSCRIPT Highlights
Fault kinematic changes are documented for the central German platform.
Structural binary chronologies unravel the succession of tectonic events.
Analysis of the entire fault-slip dataset reconstructs regional states of stress.
The basement rocks and cover strata indicate the same states of stress.
CE P
TE
D
MA
NU
SC R
IP
T
AC
7
57
S0040-1951(16)30557-1 doi:10.1016/j.tecto.2016.11.033 TECTO 127335
To appear in:
Tectonophysics
Received date: Revised date: Accepted date:
9 June 2016 12 October 2016 21 November 2016
Please cite this article as: Navabpour, Payman, Malz, Alexander, Kley, Jonas, Siegburg, Melanie, Kasch, Norbert, Ustaszewski, Kamil, Intraplate brittle deformation and states of paleostress constrained by fault kinematics in central German platform, Tectonophysics (2016), doi:10.1016/j.tecto.2016.11.033
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ACCEPTED MANUSCRIPT
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Intraplate brittle deformation and states of paleostress constrained by fault kinematics in central German platform
IP
Payman Navabpoura*, Alexander Malzb, Jonas Kleyc, Melanie Siegburgd, Norbert Kascha,
SC R
Kamil Ustaszewskia
University of Jena, Institute of Geosciences, Burgweg 11, 07749 Jena, Germany.
b
Geological Survey of Saxony-Anhalt, Köthenerstraße 38, 06118 Halle, Germany.
c
University of Göttingen, Geoscience Center, Goldschmidtstraße 1-3, 37077 Göttingen,
NU
a
Germany.
University of Southampton, Ocean and Earth Science Department, Southampton
MA
d
SO14 3ZH, England.
Corresponding author, e-mail: [email protected]
TE
D
*
CE P
Abstract
The structural evolution of Central Europe reflects contrasting tectonic regimes after the Variscan orogeny during Mesozoic – Cenozoic time. The brittle deformation related to each
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tectonic regime is localized mainly along major fault zones, creating complex fracture patterns and kinematics through time with diverging interpretations on the number and succession of the causing events. By contrast, fracture patterns in less deformed domains often provide a pristine structural inventory. We investigate the brittle deformation of a relatively stable, wide area of the central German platform using fault-slip data to identify the regional stress fields required to satisfy the data. In a non-classical approach, and in order to avoid local stress variations and misinterpretations, the fault-slip data are scaled up throughout the study area into subsets of consistent kinematics and chronology for sedimentary cover and crystalline basement rocks. Direct stress tensor inversion was 1
ACCEPTED MANUSCRIPT performed through an iterative refining process, and the computed stress tensors were verified using field-based observations. Criteria on relative tilt geometry and indicators of
T
kinematic change suggest a succession of events, which begins with a post-Triassic normal
IP
faulting regime with σ3 axis trending NE-SW. The deformation then follows by strike-slip
SC R
and thrust faulting regimes with a change of σ1 axis from N-S to NE-SW, supposedly in the Late Cretaceous. Two younger events are characterized by Cenozoic normal and oblique thrust faulting regimes with NW-SE-trending σ3 and σ1 axes, respectively. The fracture
MA
NU
patterns of both the cover and basement rocks appear to record the same states of stress.
AC
CE P
TE
D
Keywords: Brittle tectonics; Fault kinematics; Intraplate deformation; Paleostress
2
ACCEPTED MANUSCRIPT
Introduction
T
1
IP
It is a fundamental tenet of plate tectonics that deformation of the Earth’s lithosphere is
SC R
strongly localized along plate margins. Still so, weaker deformation also affects plate interiors. Central Europe has been located within a plate interior since the Variscan orogeny, and its tectonic evolution is commonly interpreted to be related to events at distant plate
NU
margins (e.g., Sissingh, 2006; Ziegler, 1987). During the Mesozoic and Cenozoic, a distant
MA
northwestern plate margin evolved from rifting to the fully developed North Atlantic midocean ridge. At the same time, a southern plate margin evolved from rifting over the formation of Alpine Tethys Ocean to subduction and collision (Handy et al., 2010;
TE
D
Rosenbaum et al., 2002; Stampfli and Borel, 2002). Both the Atlantic divergent and Tethyan convergent margins are active today, but neither is closer than 1400 km to our study area
CE P
(Fig. 1a).
There is a broad consensus about the general post-Variscan tectonic evolution of Central
AC
Europe, as reviewed in recent books. A long Permian – Early Cretaceous period of weak extension is followed by contraction in the Late Cretaceous and then again by extension related to the European Cenozoic Rift System (Doornenbal and Stevenson, 2010; Littke et al., 2008; McCann, 2008). However, diverging opinions persist about the number and timing, the kinematics and the causes of tectonic events. Detailed paleostress reconstructions in other regions of the world have revealed links between local deformation and far-field stress in different extensional and contractional settings (e.g., Angelier et al., 1990; Bergerat and Angelier, 2000; Gudmundsson et al., 1996; Navabpour, 2009; Navabpour and Barrier, 2012; Navabpour et al., 2014). A couple of brittle tectonics studies were conducted in Central 3
ACCEPTED MANUSCRIPT Europe, but results often disagree. Some studies find many discrete events, e.g. ten distinct stress fields from Late Variscan to Cenozoic time (Peterek et al., 1997) and six (Vandycke,
T
2002) or eight (Coubal et al., 2015) successive stress fields since the Late Cretaceous. Other
IP
studies interpret only a few tectonic regimes, e.g. two (Lamarche et al., 2003) or three
SC R
(Franzke et al., 2007) events throughout the Mesozoic to Cenozoic time. Possible reasons for these divergent interpretations include different completeness of stratigraphy, temporal and spatial variations in actual stress fields, over interpretation of limited data or poor
NU
preservation. For instance, Sippel et al. (2009) did not find evidence of Mesozoic extension
MA
along the southern rim of the Central European Basin and concluded that much evidence must have been lost to overprinting by younger events.
D
Furthermore, there is still no consensus on the kinematics of intraplate deformation. Large-
TE
scale structural and basin geometries were interpreted to indicate bulk dextral transtension
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with an E-W stretching axis during the Mesozoic extension, and bulk dextral transpression with a N-S shortening axis during the following contraction(s) (e.g., Betz et al., 1987; Doornenbal and Stevenson, 2010; McCann, 2008). By contrast, brittle tectonics studies have
AC
repeatedly found evidence for extension and contraction approximately perpendicular to the main NW-SE-striking faults. The question of kinematics has important implications for the causes of intraplate deformation. The European intraplate shortening has been commonly interpreted to be foreland deformation resulting from a N-directed push exerted by the Alpine collision (e.g., Ziegler and Dèzes, 2006; Ziegler, 1987; Ziegler et al., 1995). Even with dextral transpressive deformation, intraplate kinematics in this scenario only loosely matches plate boundary kinematics. Kley and Voigt (2008) instead proposed that this event has a regionally uniform NNE-SSW shortening direction that closely reflects the convergence of Africa, Iberia and Europe in Late Cretaceous time. 4
ACCEPTED MANUSCRIPT In the present paper, we address the issues listed above by analyzing fault-slip data from a relatively stable, wide area of the central German platform. We stayed away from major fault
T
zones to avoid stress variations related to differential fault block rotations. A systematic
IP
attempt was made to identify the minimum number of regional stress fields required to satisfy
SC R
the data by inverting consistent fault kinematics of the entire area together rather than analyzing individual outcrops separately. Finally, we discuss age constraints for the identified
2
MA
NU
stress fields and correlate them with deformation sequences from surrounding areas (Fig. 1b).
Geological setting
D
After the end of the Variscan orogeny, a Basin-and-Range type wide rift created the fault-
TE
bounded Latest Carboniferous to Early Permian ―Rotliegend‖ basins filled with volcanic and clastic rocks (Lützner, 1988). Following the demise of the rift, the Latest Permian Zechstein
CE P
transgression overstepped the Rotliegend basins. The Mesozoic – Cenozoic structural evolution of Central Europe comprises contrasting tectonic regimes (Littke et al., 2008;
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McCann, 2008). A protracted phase of thermal subsidence with intermittent, low-magnitude extension and transtension from the Latest Permian to the early Late Cretaceous was punctuated by more pronounced extension with graben and salt diapir formation in the Late Triassic and Late Jurassic to Early Cretaceous (Betz et al., 1987; Ernst, 1989; Franzke et al., 2007; Kockel, 2002; Tröger and Schubert, 1993). This long period of subsidence was terminated by a phase of contraction, which began and peaked in the Late Cretaceous and persisted into the Early Cenozoic involving inversion of many extensional faults (Clausen and Pedersen, 1999; Danišík et al., 2012; Kley and Voigt, 2008; Kockel, 2002; Malz and Kley, 2012; Otto, 2003; Scheck et al., 2002; Ziegler, 1987). The end of intraplate contraction 5
ACCEPTED MANUSCRIPT was followed by the formation of the European Cenozoic Rift System, which was coeval with Alpine orogeny farther south (Dèzes et al., 2004; Ziegler and Dèzes, 2006; Ziegler, 1992).
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The present-day deformation across large areas of Central Europe is characterized by a NW-
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SE maximum horizontal shortening (Fig. 1a) (Gölke and Coblentz, 1996; Grünthal and
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Stromeyer, 1992; Heidbach et al., 2007; Hinzen, 2003). This requires a substantial change in the state of stress, as documented for segments of the Cenozoic Rift System such as the Upper Rhine Graben (Schumacher, 2002), but poorly constrained in less deformed areas of
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the European plate interior such as the central German platform.
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The study area is located between the Rhenish Massif to the west and the Bohemian Massif to the southeast (Fig. 1b) and mainly covers the Thuringian domain of the central German
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platform (Fig. 2). Over much of its history, this domain was located on the southern rim of
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the Central European Basin (Fig. 1b). During the Late Cretaceous shortening event it became
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separated from surrounding basins through uplift of the Harz Mountains and Thuringian Forest (Thomson and Zeh, 2000; Voigt et al., 2004). These mountains expose low- to highgrade metamorphic rocks of the Variscan orogeny and the associated late- to post-orogenic
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Carboniferous – Permian granite intrusions (Toloczyki et al., 2006). Both the granites and the country rocks are intruded by NW-SE-striking Permian rhyolitic dykes in the Thuringian Forest and discontinuously overlain by locally thick Rotliegend volcanic and clastic rocks (e.g., Franzke and Rauche, 1991; Lützner, 1988; Rieke et al., 2001; Schröder, 1987; Zeh and Brätz, 2004; Zeh et al., 2000). The continuous sedimentary cover of the study area begins with as much as 700 m of Upper Permian Zechstein (Karnin et al., 1996). The Zechstein succession consists of evaporite and carbonate cycles of laterally variable thickness across the central German Platform (Doornenbal and Stevenson, 2010; Reinhardt, 1993). These strata mark the transition to a relatively uniform subsidence that continues into the Mesozoic. The 6
ACCEPTED MANUSCRIPT Mesozoic rocks of the study area consist of an about 1000 m thick succession of limnic, eolian and fluvial sandstone, shale and evaporite of the Lower Triassic Buntsandstein,
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shallow marine carbonate and evaporite of the Middle Triassic Muschelkalk, and shale, marl,
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sandstone and evaporite of the Upper Triassic Keuper (Beutler and Schubert, 1987; Feist-
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Burkhardt et al., 2008). The youngest Mesozoic strata preserved are small remnants of Lower Jurassic open marine shale and sandstone. The Mesozoic stratigraphic succession is locally intruded by NNE-SSW-striking basaltic dykes of Late Oligocene – Early Miocene age
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(Abratis et al., 2007; Lippolt, 1983; Rauche and Franzke, 1990) to the south and west of the
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Thuringian Forest (Fig. 2).
The entire association of pre-Zechstein rocks defines a mechanically competent basement, the
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structures of which are traceable up into the cover rocks in the Thuringian Basin (Malz, 2014;
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Malz and Kley, 2012). However, where thick evaporites are present, the Zechstein strata form
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a potential detachment layer on top of the basement rocks (Holländer, 2000; Nachsel and Franz, 1983). The dominant structures in the Mesozoic cover rocks of the study area are a few map-scale narrow NW-SE-striking faults separated by less deformed, essentially flat-
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lying terrains with horizontal strata (Fig. 2) (Ellenberg, 1992; von Bubnoff, 1953). The NW-SE-striking faults exhibit graben-like down faulted strips of Middle to Upper Triassic strata, suggesting NE-SW extension (Betz et al., 1987; Ernst, 1989; Franzke et al., 2007; Kockel, 2002; Malz, 2014; Malz and Kley, 2012; Tröger and Schubert, 1993). Some of these faults are locally associated with outcrop-scale tight and inclined drag folds, indicating tectonic inversion and contraction superimposed along the same NE-SW direction (Bankwitz et al., 1993; Franzke et al., 1986; Malz, 2014; Malz and Kley, 2012). No map-scale fold structures are associated with the NW-SE-striking faults. The faulted Mesozoic cover rocks are disrupted by the basement uplifts of the Harz Mountains, Thuringian Forest and Slate 7
ACCEPTED MANUSCRIPT Mountains to the north, south and southeast of the Thuringian Basin, respectively (Fig. 2). Minor NNE-SSW-striking faults including those of the Leinetal Graben delimit our study
Inventory of brittle structures
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3
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area to the west.
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For a comprehensive paleostress reconstruction, fault-slip data including spatial orientation of fault planes and associated striae were collected from 93 sites across the study area (Fig. 2).
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Owing to the widespread vegetation cover, data acquisition sites were mainly located in
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active and abandoned quarries and along road cuts. Most of the fault-slip data were collected from sub-horizontal micritic to bioclastic limestone of the Middle Triassic Muschelkalk in the
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cover rocks. Fault-slip data from natural rock exposures are particularly rare. A small number of fault-slip data could be collected from the granitic rocks to evaluate the response of pre-
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existing fracture patterns to the events that postdate the Carboniferous – Permian time, hence approximating the states of stress that affected the Triassic rocks. The criteria used for the sense of slip mostly include calcite slickenfibers and slickolites in the cover rocks, and Riedel shear fractures in the basement rocks. An average magnetic north correction of N002° is applied to the orientation data collected by compass, according to the International Geomagnetic Reference Field (Finlay et al., 2010) for the center of the study area during the data acquisition period. Stereoplots of the fault-slip data are given as supplementary material in the online repository to this article.
8
ACCEPTED MANUSCRIPT A common difficulty in interpreting the measurements within the framework of polyphase brittle deformation is related to the heterogeneity of fault-slip data, in terms of their diversity
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in type, spatial orientation and temporal reactivation. This heterogeneity demands appropriate
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means for classification of data into both kinematically and chronologically consistent
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subsets (e.g., Angelier, 1984; Hippolyte et al., 2012; Madritsch, 2015; Navabpour et al., 2007, 2008, 2010, 2011; Saintot and Angelier, 2002; Ustaszewski and Schmid, 2006). The criteria that could help in data separation were relative geometry of fault planes with respect
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to tilted strata and kinematic change indicators on the same fault slickensides. Because the
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study area comprises mostly flat-lying horizontal strata, the relative tilt geometries could be only verified at a limited number of sites where outcrop-scale folded strata were visible.
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Measurement of the bedding planes at these sites yields an azimuth of N121° as the average
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fold axis for the entire study area (Fig. 2, inset). This axis suggests an azimuth of N031° for the orientation of first-order shortening, which we refer to as folding event (fl) hereinafter.
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The kinematic changes were evidenced by several instances of successive striae at many sites. We describe some of the key examples observed in the study area in the following
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paragraphs.
3.1
Relative tilt geometries
At some outcrops, where the strata were locally folded, it was possible to determine the relative pre-, syn- and post-tilt geometries between the faults and bedding planes, based on the Anderson’s theory of faulting (Anderson, 1951). The pre-tilt geometry mainly includes normal and strike-slip faults that have specific angular relationships with respect to tilted strata. The syn-tilt geometry includes bedding-parallel reverse kinematics that form in 9
ACCEPTED MANUSCRIPT flexural slip folding. The post-tilt geometry mostly includes normal and strike-slip faults that have no specific angular relationship with respect to the previously folded strata.
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Examples of pre-tilt geometry can be given for sites 40 and 76. Site 40 provides data of tilted
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normal faults along the Eichenberg-Gotha-Saalfeld Fault Zone (Fig. 2). In the present-day
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orientation, the faults appear as a system of crosscutting low-angle normal and high-angle reverse faults (Fig. 3a). The intersection line of the faults is sub-parallel to the bedding plane,
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suggesting that they are tilted conjugate-like normal faults. The stress field obtained from these fault-slip data indicates inclined σ1 and σ3 axes deviated from vertical and horizontal
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orientations, respectively. Back tilting the fault-slip data around the strike of tilted strata reconstructs the initial geometry and yields a normal faulting regime with vertical σ1 axis.
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Site 76 provides data of tilted strike-slip faults to the southeast of the Finne Fault Zone (Fig.
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2). At this site, there are folded strata containing sub-vertical oblique sinistral strike-slip
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faults with striae parallel to the tilted bedding planes (Fig. 3b). The stress field obtained from these fault-slip data indicates inclined stress axes with σ2 axis deviated from vertical in the present-day orientation. Back tilting the fault-slip data around the strike of the bedding plane
axis.
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reconstructs their initial geometry and yields a strike-slip faulting regime with vertical σ2
An example of syn-tilt geometry can be given for site 21. This site represents overturned flank of a local fold across the Finne Fault Zone (Fig. 2) with bedding-parallel slip planes indicating normal senses of motion (Fig. 3c). The stress field obtained from these fault-slip data is a normal faulting regime with vertical σ1 axis in the present-day orientation. Back tilting the fault-slip data around their strikes to a non-overturned, moderately tilted attitude of the strata reconstructs their typical syn-fold geometry. These back-tilted fault-slip data indicate a thrust faulting regime with vertical σ3 axis. 10
ACCEPTED MANUSCRIPT Examples of post-tilt geometry can be given for sites 40 and 42. At site 40, along the Eichenberg-Gotha-Saalfeld Fault Zone (Fig. 2), a separate set of conjugate-like normal faults
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cut through locally folded strata (Fig. 3d). These faults appear in their typical Andersonian
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geometry (Anderson, 1951) with a horizontal intersection line, regardless the inclination of
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bedding plane. The stress field obtained from these fault-slip data indicates a normal faulting regime with vertical σ1 axis. At site 42, along the northern rim of the Thuringian Forest (Fig. 2), sub-vertical sinistral strike-slip faults with sub-horizontal striae cut through locally folded,
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deeply tilted strata (Fig. 3e). The stress field obtained from these fault-slip data suggests a
Kinematic change indicators
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3.2
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strike-slip faulting regime with vertical σ2 axis.
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Kinematic changes are evidenced by successive striae on the same fault planes at several sites. The successive striae are of different types in terms of relative chronology. The best instances of successive striae are those that clearly show relative binary chronologies. These
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striae either crosscut or overprint each other with different senses of slip. Some striae twist from one to another, evidencing continuous kinematic change between faulted blocks, which need cautious consideration in paleostress reconstructions. Other instances of striae exhibit disparate kinematics on different parts of the same fault plane with unclear relative chronology.
Instances of successive striae with relative binary chronology mostly include strike-slip and reverse reactivation of pre-existing NW-SE-striking normal faults. A kinematic change from normal to dextral sense of slip was observed at site 17 (Fig. 4a) through slickolites crosscutting calcite slickenfibers on a tilted normal fault plane. At site 52, a fault slickenside 11
ACCEPTED MANUSCRIPT indicates reverse reactivation of a normal fault by calcite slickenfibers crystallized over older slickolites (Fig. 4b). These sites suggest that a NE-SW extension was replaced by contraction.
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Sites 04 and 22 reveal successive striae on fault slickensides sub-parallel to the pre-existing
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normal faults. At site 04, calcite slickenfibers overprinting slickolites indicate sinistral
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reactivation of a thrust fault (Fig. 4c). At site 22, twisted slickolites indicate a kinematic change from dextral to reverse sense of slip (Fig. 4d). These successive striae suggest a reorientation of contraction from N-S to NE-SW, possibly in a continuum of events. This
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interpretation can be confirmed by observation of successive horizontal stylolites in sub-
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horizontal strata at site 73 (Fig. 4e), as well as site 77. These sites are spatially located far from each other to the north and south of the Finne Fault Zone (Fig. 2), respectively. The
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horizontal stylolites independently indicate similar clockwise change in the direction of
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contraction.
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Nevertheless, other instances of kinematic change suggest contrasting reorientation of contraction. At site 08, twisted striae on SW-dipping, steep bedding planes indicate a change from reverse to oblique dextral sense of slip (Fig. 4f). This kinematic change suggests
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counterclockwise reorientation of contraction towards NW-SE. If this interpretation is correct, the change should postdate the folding event because steeply tilted strata are affected by this kinematic change (see also Fig. 3e).
Instances of successive striae with unclear relative chronology exhibit contrasting normal and strike-slip fault slickensides. Site 31 indicates disjunctive normal and sinistral senses of slip on a NE-SW-striking high-angle fault plane (Fig. 4g). The relative chronology is not well understood between these two senses of slip. However, these fault-slip data seem to be geometrically consistent with the pre- and post-tilt orientation of sub-parallel faults observed elsewhere at sites 76 and 40 (Fig. 3b and d, respectively). Hence, the normal component 12
ACCEPTED MANUSCRIPT suggests a NW-SE extension that should postdate both the strike-slip component and the folding event. At site 75, opposite dextral and sinistral strike-slip motions are evidenced by
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slickolites on the same sub-vertical fault planes striking NNW-SSE (Fig. 4h). The stress
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fields obtained from the collected fault-slip data indicate orthogonal NE-SW and NW-SE
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directions of contraction. The relative chronology could not be reliably verified between these fault-slip data. The only observation was that the striae indicating sinistral sense of slip prevail and that sub-parallel sinistral faults appear in post-tilt geometry elsewhere at site 42
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(Fig. 3e). Hence, the sinistral sense of slip should postdate the dextral one.
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In the case of basement rocks, we could find two instances of successive striae. At site 34, there are calcite slickenfibers crystallized on incongruous steps of Riedel shear fractures on a
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SW-dipping fault plane cutting through the granites (Fig. 5a). The calcite slickenfibers
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indicate a reverse sense of slip opposite to that of the Riedel shear fractures. This observation
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suggests inversion of a normal fault under a NE-SW contraction. Another change in fault kinematics is evidenced by twisted striae on sub-vertical NNW-SSE-striking fault planes showing dextral senses of slip within the rhyolites at site 62 (Fig. 5b). The twisted striae
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could be interpreted either as a change of kinematics or as successive increments of strikeslip displacements associated with progressive fault block rotation towards south. The structural location of the outcrop along a map-scale NW-SE-striking fault in southwestern foothills of the Thuringian Forest is in favor of the latter.
3.3
Distribution of deformation
As already explained, the study area widely consists of flat-lying strata (Fig. 2) away from surrounding major deformational zones of the Elbe Fault, Leinetal Graben and Franconian 13
ACCEPTED MANUSCRIPT Lineament (Fig. 1b). This structural configuration limited the possibility to use relative tilt geometries in data separation for every outcrop. The stratigraphy of the study area is such that
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almost all the fault-slip data of the cover rocks are collected from the Middle Triassic
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Muschelkalk (see supplementary material). This uniform lithology made it impossible to
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separate data based on the age of affected rock, except between the limestone of the cover and the granite of the basement. Furthermore, many outcrops provided us with few fault-slip data of different kinematics, which could not be used in stress tensor inversion individually.
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The interpretation of kinematic changes can also be ambiguous, because they might be
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related to either change in stress or differential fault block rotation. However, we should emphasize that most of the successive striae were collected from outcrops with horizontal
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strata where the rocks were not distorted by a local fault zone. While we avoided collecting
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ambiguous data from the narrow fault zones, it was indispensable to verify the relative tilt
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geometries close to these faults.
In order to evaluate the regional significance of the field-based observations and establish the links between the relative tilt geometries and kinematic changes, the fault-slip data are
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separated based on relative chronology and kinematic consistency. The stress axes are calculated for individual outcrops (Table 1) through the right dihedra method of Angelier and Mechler (1977). The orientations of maximum and minimum principal stress axes, σ1 and σ3 respectively, are plotted on separate paleostress maps (Fig. 6). On these maps, the data of the cover strata for which the relative tilt geometry is known are categorized into pre-, syn- and post-tilt geometries (Fig. 6a, b and c). The data obtained from horizontal cover strata, as well as the data from the basement granite, are plotted as ―not tilted‖ stress axes (Fig. 6d, e and f), and categorized based on consistent kinematics with the pre-, syn- and post-tilt geometries.
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ACCEPTED MANUSCRIPT Where available, the relative chronology between two stress axes is given based on the kinematic change indicators of the corresponding fault-slip data (Table 1).
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According to the paleostress maps (Fig. 6), the stress axes of pre- and syn-tilt geometries are
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approximately perpendicular to the map-scale NW-SE-striking faults (Fig. 6a and b) and
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most of the stress axes of post-tilt geometry are parallel to these faults (Fig. 6c). These stress axes have comparable orientations to those obtained from horizontal cover strata, as well as
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from the basement granite (Fig. 6d, e and f). The paleostress maps indicate a homogeneous distribution of the stress axes and do not characterize a specific stress axis to belong to a
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distinct location or lithology. The pre-tilt data (Fig. 6a) mostly include normal and strike-slip faults (Fig. 3a and b). A succession of first NE-SW σ3 then NNE-SSW σ1 is obvious at
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several sites (Fig. 6d), based on the successive striae on the same fault planes (Fig. 4a and b).
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The syn-tilt geometry (Fig. 6b) characterizes a NE-SW orientation for σ1, reconstructed based
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on the bedding-parallel reverse kinematics (Fig. 3c). A succession of first N-S then NE-SW σ1 is observed at several sites (Fig. 6e), based on the successive reactivations on the preexisting normal faults (Fig. 4c, and d). A clockwise change in the orientation of σ1 towards
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NE-SW may be inferred. However, the presence of twisted slickolites (Fig. 4d), as well as the successive horizontal stylolites (Fig. 4e), likely suggest a gradual kinematic change in a continuum of events. In the post-tilt geometry, horizontal σ1 and σ3 axes are mostly oriented NW-SE (Fig. 6c). The corresponding fault-slip data include normal and strike-slip faults, respectively, that cut through previously folded strata (Fig. 3d and e). The relative chronology between these two horizontal stress axes could not be constrained. However, successive striae (Fig. 4f, g and h) suggest that they should postdate the NE-SW-trending σ1 axis (Fig. 6f).
15
ACCEPTED MANUSCRIPT 4
States of paleostress
For accurate computation of the states of paleostress that might belong to distinct tectonic
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events, we adopted the direct stress tensor inversion method of Angelier (2002), using
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Angelier’s Tector 2000 software. Briefly, the stress tensor inversion is based on maximizing
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the sum of slip shear stress components, i.e. shear stress in the direction of actual slip, for the entire dataset. This sum is calculated as a function of four independent variables of the
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reduced stress tensor, i.e. three angular parameters for orientation of the principal axes of stress 1 2 3 , as well as the ratio of the principal stress magnitude differences
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calculated as 2 3 / 1 3 , giving the orientation and shape of the stress ellipsoid. Hence, to formulate the stress tensor inversion, at least four consistent fault-slip data
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belonging to the same stress field must be available. For a given dataset, the best fitting stress
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tensor is reached by retaining consistent and rejecting inconsistent data through an iterative
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refining process, which minimizes the misfit angle, , between the slip shear stress component and the maximum resolved shear stress on the fault planes (Angelier, 2002).
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A synoptic view of the stereoplots of fault-slip data (see supplementary material) points out that the consistent data for individual fault sets at many sites are very few and less than the minimum threshold needed for the inversion. The direct inversion based on the slip shear stress could not be performed for these individual data. Additionally, at many outcrops of the cover rocks, the data are collected from sub-horizontal Middle Triassic strata (Table 1) with no further evidence for separation based on either the relative geometry or the age of affected rock, but the kinematic consistency. This provides a situation similar to the outcrops of Carboniferous – Permian granite with comparable orientations of stress axes (Fig. 6d, e and f). Therefore, we arrived at scaling up the data to be able to proceed with stress tensor 16
ACCEPTED MANUSCRIPT inversion for the following reasons. First, in order to evaluate the states of stress between the cover and basement rocks, the entire study area is regarded as a single measuring site. The
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fault-slip data of the cover and basement rocks are categorized into separated datasets of
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consistent kinematics. Where applicable, a tilt correction was performed to reconstruct the
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initial orientation of data in the cover rocks before scaling up the data. Second, in order to compute regional stress tensors for the uniform brittle deformation distributed throughout the study area, the separated fault-slip data of the cover rocks are combined together into
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chronologically consistent subsets. In essence, this approach eliminates the effect of
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unsystematic variations of stress axes that may result from local fault block rotations, measurement errors and/or misinterpretations. The reason to this elimination is that
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unsystematic data would be rejected in the refining process, if they do not satisfy the criteria
4.1
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of a best fitting stress tensor (Angelier, 2002).
Kinematic consistency
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Examination of the entire data and separation into consistent kinematics reveals three general best-fitting stress tensors of normal, strike-slip and thrust faulting regimes for the basement and cover rocks, individually (Fig. 7, top box). Details of the computed stress tensors are given in Table 2.
For the basement rocks, the normal faulting regime includes dominant NW-SE-striking dipslip and oblique-slip components. The stress tensor indicates moderate value of ϕ and a horizontal σ3 axis trending N230° (Fig. 7a). The strike-slip faulting regime consists of NWSE- and NE-SW-striking high-angle fault planes with dextral and sinistral components, respectively. These faults yield a stress tensor with moderate value of ϕ and a horizontal σ1 17
ACCEPTED MANUSCRIPT axis trending N183° (Fig. 7b). The thrust faulting regime consists of mostly WNW-ESEstriking low-angle fault planes with dip-slip and oblique-slip components. These faults yield
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a stress tensor with moderate value of ϕ and a horizontal σ1 axis trending N042° (Fig. 7c).
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Unlike the cover rocks, there are no clear geometrical criteria to evaluate the succession of
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events in the basement rocks. However, we know that the thrust faulting postdates the normal faulting, based on our observation of relative chronologies at site 34 (Fig. 5a). Residual faultslip data, which could not fit with the best fitting stress tensors, result in computation of a
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stress tensor with horizontal σ1 axis trending N318° and low value of ϕ indicating
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permutation of σ2 and σ3 axes (Fig. 7d). The stereoplot of the corresponding data shows that the faults have mostly E-W-striking inclined planes with oblique thrust and strike-slip
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components.
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For the cover rocks, the stereoplots related to the best-fitting stress tensors reveal conjugate-
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like normal, strike-slip and thrust fault patterns. The normal faulting regime consists of dominant NW-SE-striking dip-slip faults. The stress tensor indicates moderate value of ϕ and a horizontal σ3 axis trending N036° (Fig. 7e). The strike-slip faulting regime consists of sub-
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vertical NNW-SSE- and ENE-WSW-striking fault planes with dextral and sinistral components, respectively. The stress tensor computed for these faults has a moderate value of ϕ and a horizontal σ1 axis trending N211° (Fig. 7f). The thrust faulting regime has dominant NW-SE-striking low-angle fault planes. These faults yield a stress tensor of moderate ϕ value and horizontal σ1 axis trending N029° (Fig. 7g). Residual fault-slip data, which could not fit with the best fitting stress tensors, result in computation of a stress tensor with horizontal σ1 axis trending N125° and low value of ϕ indicating permutation of σ2 and σ3 axes (Fig. 7h). The stereoplot of the fault-slip data indicates scattered distribution of the slickensides. There
18
ACCEPTED MANUSCRIPT is no obvious systematic pattern for the strike and dip direction of the fault planes and
Chronological consistency
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4.2
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associated striae. Most of the slickensides indicate strike-slip and oblique thrust kinematics.
Examination of the separated fault-slip data for the cover rocks and scaling up the consistent
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geometries and chronologies throughout the study area reveals six major subsets. These subsets include pre-tilt normal and strike-slip faults, dextral reactivation of normal faults,
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syn-tilt bedding-parallel reverse faults, and post-tilt normal faults and strike-slip reactivations
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(Fig. 7, bottom box).
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The pre-tilt normal faulting subset indicates NW-SE-striking conjugate-like faults. Inversion of the fault-slip data of this subset yields a stress tensor with moderate value of ϕ and a
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horizontal σ3 axis trending N214° (Fig. 7i). This stress tensor is very close to that of the entire normal faulting regime (Fig. 7e). The pre-tilt strike-slip faults consist of sub-vertical NW-SE-
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and NE-SW-striking conjugate-like fault planes with dextral and sinistral components, respectively. The stress tensor computed for this subset has a moderate value of ϕ and a horizontal σ1 axis trending N189° (Fig. 7j). This N-S orientation of σ1 is slightly different to that of the entire strike-slip faults of the cover rocks (Fig. 7f). The dextral reactivation of NW-SE-striking normal faults (Fig. 4a) reconstructs a consistent subset for the study area. Inversion of these fault-slip data yields a stress tensor with low value of ϕ and a horizontal σ1 axis trending N013° (Fig. 7k). This low value of ϕ indicates permutation of σ2 and σ3 axes between vertical and horizontal orientations and suggests an interchange between strike-slip and thrust faulting regimes. The syn-tilt fault-slip data reveal conjugate-like NW-SE-striking thrust faults. Inversion of the fault-slip data of this subset yields a stress tensor with moderate 19
ACCEPTED MANUSCRIPT value of ϕ and a horizontal σ1 axis trending N030° (Fig. 7l). This NE-SW orientation of σ1 is parallel to that of the entire thrust faults of the cover rocks (Fig. 7g) and coherent with the
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first-order shortening (Fig. 2). The post-tilt normal faulting subset reveals conjugate-like NE-
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SW-striking fault planes. This subset yields a stress tensor with moderate value of ϕ and a
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horizontal σ3 axis trending N292° (Fig. 7m). The post-tilt fault reactivations constitute a subset of strike-slip faults. Most of these faults belong to the residual subset of the entire dataset (Fig. 7h) and yield a similar stress tensor with horizontal σ1 axis trending N129° (Fig.
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Succession of events
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4.3
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7n).
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Based on the relative chronologies obtained from the brittle structures of the cover rocks (Fig.
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3 and Fig. 4), we used a chronological matrix analysis to establish and illustrate the best possible succession of events (Fig. 8). Briefly, each cell of the matrix denotes a binary chronology between the first and second event for the corresponding row and column,
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respectively. The best solution could be reached when the numbers of binary chronologies accumulate in the compatible area at the upper right half of the matrix, through manual consecutive permutation of the events (Angelier, 1991). One advantage of this matrix analysis is that inconsistent binary chronologies will be filtered out in the incompatible area, statistically. Therefore, any misinterpretations of relative tilt geometry and/or random kinematic changes that may result from differential fault block rotations do not vitiate the prevailing succession. The matrix solution presented here is obtained based on 48 individual binary chronologies between the fault-slip data, as well as between the fault planes and the folded strata, identified at 33 sites and includes 5 incompatible binary chronologies. The 20
ACCEPTED MANUSCRIPT succession of events refers to the stress tensors reconstructed based on the chronologically consistent datasets of the cover rocks (Fig. 7i-n). It starts with the NE-SW extension then
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changes to the N-S and NE-SW contractions and follows by the NW-SE extension and NW-
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SE contraction. The incompatible chronologies of the solution possibly arose from our choice
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to plot the folding event separated from the N-S and NE-SW contractions in the matrix. The solution also shows that the succession of the NW-SE extension and NW-SE contraction is not constrained because of a lack of binary chronology between the corresponding fault-slip
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Discussion
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5
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data.
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The relative chronology of events found in our study area can now be compared to the
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tectonic history deduced from isotopic ages, and to the earlier paleostress studies from surrounding regions. We also discuss the relationships between the stress fields found in the
style.
5.1
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cover and basement rocks and the implications for mechanical stratigraphy and structural
Relative versus absolute chronology
The oldest brittle deformation recorded by the fault-slip data is the normal faulting regime with a NE-SW-trending σ3 axis that was in vigor after deposition and before folding of the Triassic strata (Fig. 7i). The normal faults are tilted wherever the strata are folded (Fig. 3a). We could not find any convincing outcrop-scale evidence for a possible Triassic syn-tectonic deposition associated with this brittle deformation. A lower age limit of extension for some 21
ACCEPTED MANUSCRIPT fault zones of the study area is given by normal faults affecting Lower Jurassic strata (Ernst, 1989). In one locality, an upper age limit is indicated by Upper Cretaceous (Cenomanian)
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strata sealing normal faults (Tröger and Schubert, 1993). A Late Jurassic – Early Cretaceous
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age is well established for the main phase of extension in the NW-SE-trending Lower Saxony
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Basin (Betz et al., 1987; Kockel, 2002), about 200 km northwest of our study area (Fig. 1b). Extensional regimes in the Harz Mountains are attributed to Late Triassic – Early Jurassic and Early Cretaceous at about 226-180 and 125-90 Ma, respectively (Franzke et al., 2007),
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based on K-Ar and Rb-Sr isotopic ages of authigenic hydrothermal vein and fault gouge
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mineralization (Franzke et al., 1996; Haack and Lauterjung, 1993; Hagedorn and Lippolt, 1993; Schneider et al., 2003). Taken together, these data suggest that the oldest extension
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event we observe is bracketed between the (Late Triassic to) Early Jurassic and Early
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Cretaceous.
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The next states of stress revealed by fault-slip data are the strike-slip and thrust faulting regimes (Fig. 7j and l, respectively). The strike-slip event occurred before the folding event with a N-S-trending σ1 axis (Fig. 3b) and reactivated the pre-existing NW-SE-striking normal
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faults with dextral components (Fig. 4a and Fig. 7k). Zulauf (1992, 1993) reconstructed a NS-trending σ1 axis at the western border of the Bohemian Massif to be of Early Cretaceous age, based on K-Ar dating of fault gouge. The state of stress then switched to the thrust faulting regime evidenced by kinematic change from dextral to reverse on the NW-SEstriking normal faults (Fig. 4b and d) and by bedding-parallel flexural slip (Fig. 3c). This change was associated with clockwise rotation of the σ1 axis to the NE-SW orientation during the folding event (Fig. 4e). Stratigraphic data constrain a Coniacian – Paleocene age for the tectonic inversion across the Lower Saxony and Subhercynian Cretaceous basins (Betz et al., 1987; Otto, 2003; Voigt et al., 2004; Voigt et al., 2006; von Eynatten et al., 2008). According 22
ACCEPTED MANUSCRIPT to fission track analyses (Danišík et al., 2010; Thomson et al., 1997; Thomson and Zeh, 2000; Vamvaka et al., 2014), a Late Cretaceous age (ca. 110-70 Ma) can be attributed to
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exhumation of the basement rocks and, by inference, to inversion resulting from the NE-SW
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contraction (Franzke et al., 2007; Kley and Voigt, 2008).
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The two younger states of stress that appear in post-fold geometry (Fig. 3d and e) are associated with reactivation of the earlier fracture patterns. A normal faulting regime with
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NW-SE-trending σ3 axis (Fig. 7m) is possibly characterized by reactivation of pre-existing tilted strike-slip faults (Fig. 4g). An oblique thrust faulting regime with NW-SE-trending σ1
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axis (Fig. 7n) is documented by strike-slip reactivation of pre-existing fault planes (Fig. 4f and h). Considering the Coniacian – Paleocene age for the folding event, these states of stress
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should represent brittle tectonic events of Cenozoic age. The NW-SE extension is
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perpendicular to the general strike of Tertiary basaltic dykes (Fig. 2) that are integral parts of
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the Cenozoic Rift System (Fig. 1b). According to K-Ar and Ar-Ar ages reported from southwest of the Thuringian Forest, the basaltic rocks belong to the Late Oligocene – Early Miocene, ca. 26-10 Ma (Abratis et al., 2007; Lippolt, 1983). NW-SE contraction is reported
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to have affected the Late Cretaceous strata (Sippel et al., 2009) to the northwest of our study area and has the same orientation of the maximum horizontal shortening as the present-day stress field (Fig. 1a). This youngest stress field should have been established after emplacement of the basaltic dykes described above. It is possibly coeval with successive basaltic dyke intrusion and syn-sedimentary tectonic activity within the Rhine Graben during the Miocene – Pliocene (Illies, 1975; Rauche and Franzke, 1990; Schumacher, 2002).
23
ACCEPTED MANUSCRIPT 5.2
Local versus regional paleostress
The NE-SW extension affecting the Triassic strata of Thuringia is regionally reported from
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surrounding areas such as the northern border of the Harz Mountains, southwest of the
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Thuringian Forest and the western border of the Bohemian Massif (Fig. 9a) (Franzke et al.,
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2007; Peterek et al., 1997; Rauche and Franzke, 1990). According to our paleostress reconstruction, this event is evidently characterized by the pre-fold normal faulting regime
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with moderate value of ϕ and vertical σ1 axis (Fig. 7i). Nevertheless, contrasting deformation and interpretation also exist. For example, Sippel et al. (2009) obtained a local normal
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faulting regime with NW-SE-trending σ3 axis and low value of ϕ that has affected only the Middle Triassic rocks along a major zone of deformation at the northern tip of the Leinetal
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Graben (Fig. 9a). Although the low value of ϕ indicates possible permutation between
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horizontal σ2 and σ3 axes, i.e. bidirectional extension here, but the authors did not document
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brittle structures that clearly indicate the NE-SW extension. The Late Cretaceous – Paleocene inversion and folding has been attributed to the NE-SW
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contraction, as recorded in fault-slip data from the Harz Mountains, southwest of the Thuringian Forest and the Bohemian Massif (Fig. 9b) (Coubal et al., 2015; Franzke et al., 2007; Peterek et al., 1997; Rauche and Franzke, 1990). This orientation is coherent with orientation of one generation of horizontal tectonic stylolites of presumably Late Cretaceous age (Kley, 2013; Kley and Voigt, 2008; Kurze and Necke, 1979). However, a distinct prefold N-S shortening of strike-slip and oblique thrust faulting was reported from the Lower Rhine Graben and the Osning Thrust bordering the Lower Saxony Basin in the south (Saintot et al., 2013; Vandycke, 2002). This pre-fold strike-slip faulting could not be reconstructed along the major thrust fault of the northern Harz Mountains. Sippel et al. (2009) obtained a general N-S- to NE-SW-trending horizontal σ1 axis for a state of stress with low value of ϕ, 24
ACCEPTED MANUSCRIPT denoting permutation of σ2 and σ3 axes along the Elbe Fault Zone (Fig. 9b). Our observations suggest reorientation of σ1 axis from N-S to NE-SW through a change from strike-slip to
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thrust faulting regime (Fig. 7j and l, respectively), possibly in a continuum of events through
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an intervening stress state characterized by low value of ϕ (Fig. 7k). We found little evidence
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of post-fold strike-slip faulting indicating NE-SW contraction. This corroborates the observation that the Late Cretaceous – Paleocene inversion occurred in a predominantly thrust faulting regime. A similar reorientation and sequential change in the state of stress is
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also reported from the Holy Cross Mountains in the Carpathian foreland of southeastern
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Poland (Lamarche et al., 2002). Hence, both the change in stress regime and reorientation of σ1 axis from N-S to NE-SW seem to be of regional scale, either due to clockwise rotation of
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the far-field stress or readjustment of shortening to an optimum orientation perpendicular to
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the strike of pre-existing structures.
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The stress fields attributed to the Cenozoic Rift System represent horizontal σ3 axes of various orientations (Fig. 9c). Post-inversion normal faulting regimes with N-S-trending σ3 axes are reported from the Osning Thrust of the Lower Saxony Basin and from the Lusatian
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Thrust of the Bohemian Massif (Coubal et al., 2015; Saintot et al., 2013). Our fault-slip data indicate a post-fold normal faulting regime with NW-SE-trending σ3 axis (Fig. 7m). This stress axis is close to the σ3 axis of Miocene normal faulting reported from southwest of the Thuringian Forest (Rauche and Franzke, 1990). By contrast, Vandycke (2002) obtained a normal faulting regime with NE-SW-trending σ3 axis along the Lower Rhine Graben, and Sippel et al. (2009) measured an oblique normal faulting regime with low value of ϕ at northern tip of the Leinetal Graben, indicating permutation between NE-SW- and NW-SEtrending σ3 and σ2 axes, respectively. Farther south, fault-slip data along the Upper Rhine Graben indicate a normal faulting regime with an E-W-trending σ3 axis (Bergerat, 1987; 25
ACCEPTED MANUSCRIPT Villemin and Bergerat, 1987). Apart from the relatively stable area of Thuringia, the various orientations of horizontal σ3 axis seem to be consistent with and approximately perpendicular
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to the local structural trends (Fig. 9c). Nevertheless, Lopes Cardozo and Behrmann (2006)
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argue for a transtensional opening of the Upper Rhine Graben under a NW-SE-trending
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horizontal σ1 axis, which is more likely coherent to the present-day states of stress (Fig. 1a and Fig. 9d).
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The structural setting of the Rhine Graben within the regional intraplate stress field is already interpreted as passive rifting in response to the build-up of Alpine collision associated with
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counterclockwise rotation of the horizontal σ1 axis from NE-SW to NW-SE (Ahorner, 1975; Dèzes et al., 2004; Illies, 1975; Peterek et al., 1997; Rauche and Franzke, 1990). Coubal et al.
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(2015) reconstructed the stress reorientation in oblique thrust and strike-slip faulting regimes
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along the Lusatian Thrust of the Bohemian Massif. Our post-fold NW-SE-trending horizontal
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σ1 axis belongs to a stress tensor with moderate to low value of ϕ (Fig. 7n), indicating a strike-slip to oblique thrust faulting regime (Fig. 9d). This state of stress is consistent with the results of Sippel et al. (2009) from the Lower Saxony Basin. According to in-situ stress
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measurements and earthquake focal mechanisms (Grünthal and Stromeyer, 1992; Heidbach et al., 2010), the present-day Central Europe is characterized by a NW-SE-trending horizontal σ1 axis (Fig. 1a), with deformation mainly localized along major fault zones (Ahorner, 1975; Illies, 1975). However, in contrast to our findings in the central German platform, inversion of earthquake fault plane solutions indicate that the state of stress is mainly strike-slip along the Upper Rhine Graben with permutation between σ1 and σ2 axes, i.e. oblique normal faulting, towards the Lower Rhine Graben (Fig. 9d) (Hinzen, 2003; Homuth et al., 2014).
26
ACCEPTED MANUSCRIPT 5.3
Cover versus basement deformation
Surveys on the inherited basement structures in the central German platform reveal two
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prominent orthogonal NW-SE- and NE-SW-striking fault sets that have been active in
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Carboniferous – Permian times (Fielitz, 1992; Matte, 1991; Rieke et al., 2001; Scheck et al.,
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2002; Schröder, 1987; Wilson et al., 2004). Our fault-slip data collected from a small number of granite outcrops in the Thuringian Forest indicate that fault sets parallel to these strikes
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have dextral and sinistral strike-slip components, respectively, with the NW-SE-striking fault set indicating additional normal and reverse components on inclined fault planes. We do not
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have any age criteria for the fault-slip data. However, correlation of the data between the basement and cover rocks (Fig. 7a-h) indicates similar fault patterns and kinematics. This
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similarity in brittle deformation implies that the fault patterns of the cover rocks could be
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induced by reactivation of pre-existing basement structures under the subsequent stress fields.
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This could be the case where the map-scale NW-SE-striking faults of the basement displace the Zechstein layer and the corresponding fault can be traced up into the cover rocks in the Thuringian Basin (Fig. 2) (Malz, 2014; Malz and Kley, 2012). Seismic profiles across the
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Lower Saxony Basin confirm the involvement of pre-Permian basement in both the extension and inversion of the Mesozoic structures (Baldschuhn et al., 2001; Betz et al., 1987).
The structural style observed in the Thuringian Basin differs from that described by Otto (2003) for the Elbe Fault Zone, across which a thick-skinned deformation with vertical basement displacements in the central part changes to a thin-skinned deformation where Zechstein detaches the cover from an unaffected basement farther north. Franzke et al. (2007) argue that the Zechstein evaporites act as a detachment layer and provide mechanical decoupling between the basement and cover rocks north of the Harz Mountains. The change from an exclusively thick-skinned structural style in Thuringia to a mixed thick- and thin27
ACCEPTED MANUSCRIPT skinned style farther north is very likely due to the northward increasing thickness of Zechstein evaporites. Local to regional observations suggest that the presence of salt-related
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structures strongly depends on distribution of different Zechstein cycles (e.g., Doornenbal
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and Stevenson, 2010; Reinhardt, 1993). The first cycle of Zechstein, the Werra cycle, is
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mostly flat-lying and thicker in our study area than to the north, with minor extent of salt structures that retrace the underlying basement structures (Hoppe, 1960). The second cycle of Zechstein, the Stassfurt cycle, which is extremely ductile (Nachsel and Franz, 1983) and
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acted as the main decoupling horizon for detached structures in northern central German
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platform (Holländer, 2000), roughly dwindles towards south across our study area. Hence, the contradictory results could be partly explained by the differences in mechanical stratigraphy.
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Nevertheless, we would rather interpret the similar fracture patterns of the basement and
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cover in terms of local versus regional aspects of deformation. Whereas the evolution of local
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structures strongly depends on the mechanical stratigraphy, the regional stress fields affect the entire stratigraphy regardless of lithological contrasts (Gunzburger and Magnenet, 2014). Hence, scaling up the consistent fault-slip data of the Triassic cover strata across a wide area
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fades out local variations in fracture patterns and results in computation of comparable stress tensors to that of the underlying Carboniferous – Permian basement (Fig. 7). The normal faulting stress tensors of the basement and cover (Fig. 7a and e) have very close orientations of stress axes and values of ϕ (Table 2). The strike-slip faults of the basement (Fig. 7b) yield a stress tensor close to that of the pre-tilt strike-slip faults of the cover (Fig. 7j), indicating a N-S-trending σ1 axis. The thrust faults of the basement and cover provide similar stress tensors with NE-SW-trending σ1 axes (Fig. 7c and g). We interpret that these observations likely reflect the reorientation of σ1 concomitant with the change from strike-slip to reverse kinematics rather than synchronous different shortening directions in the basement and cover 28
ACCEPTED MANUSCRIPT rocks (Hecht et al., 2003). The residual fault-slip data that did not fit with other best fitting stress tensors result in similar stress tensors for both the basement and cover (Fig. 7d and h).
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In the regional scale, these data characterize fault reactivations under the post-tilt NW-SE-
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trending σ1 axis (Fig. 7n). Although the states of stress of the basement could be attributed to
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the Late Variscan crustal deformation (Zulauf, 1993), we assume that the Mesozoic –
Conclusions
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6
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Cenozoic events may have overprinted the earlier brittle deformation.
In this study, we analyzed the post-Triassic brittle deformation of a relatively stable area of
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the central German platform to reconstruct the changes in far-field stress through time. In a
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non-classical approach, we scaled up the fault-slip data collected throughout the study area
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into large subsets of consistent kinematics and chronology. This approach minimized the role of local fault block rotations and misinterpretations, thus allowing us to deduce regional states of stress. Our results reveal a succession of events whose chronology is constrained by
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relative tilt geometries and kinematic change indicators obtained from the Triassic strata. The oldest event recorded represents a normal faulting regime with NE-SW-trending σ3 axis. This event was followed by strike-slip and thrust faulting regimes concomitant with reorientation of σ1 axis from N-S to NE-SW, supposedly during the Late Cretaceous inversion. Two younger events postdate the inversion and involve reactivation of pre-existing fractures by a normal faulting regime with NW-SE-trending σ3 axis and an oblique thrust faulting regime with NW-SE-trending σ1 axis. The succession of events is coherent with the general Mesozoic – Cenozoic tectonic evolution of Central Europe. The fracture patterns of the basement rocks appear to record the same states of stress as the cover strata. This observation 29
ACCEPTED MANUSCRIPT suggests uniform stress transmission throughout the brittle upper crust, despite the presence of rheologically ductile rocks of Zechstein, which have locally acted as detachment layer
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between the basement and cover. A correlation of the brittle deformation between the
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surrounding structural domains confirms that the state of stress is variable and/or overprinted
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by younger events in the vicinity of major zones of deformation. The numerous discrete states of stress reconstructed in some researches along major faults seem unlikely to evidence distinct tectonic events separated in time, unless dating of syn-kinematic fault minerals is
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provided.
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Acknowledgements
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This study was accomplished through financial support of the German Research Foundation
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(DFG) under the research grant no. NA1165/2-1 ―Stress Field Evolution in a Plate Interior‖. The fieldwork was partly covered by projects INFLUINS no. 03IS2091 and OPTIRISS no. 2012FE9080, funded by the German Federal Ministry of Education and Research (BMBF)
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and by the Thuringian Development Bank (TAB), respectively. We thank TLUG Weimar, especially A. Nestler, and LAGB Sachsen-Anhalt, K. Stedingk, for their kind and prompt support in accessing the visited quarries. J.-F. Groth, D. Turner and T. Knörrich assisted during the fieldwork. Detailed comments by D. Delvaux and an anonymous reviewer, as well as constructive remarks by the editor Ph. Agard, contributed towards improving this manuscript.
30
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Fig. 1. Location of the study area within the regional tectonic framework. (a) Plate kinematics affecting Western Eurasia. Nubia – Eurasia plate convergence in Eurasia-fixed reference frame after Nocquet and Calais (2004). North America – Eurasia plate divergence after DeMets et al. (1990). SHmax is average orientation of the present-day maximum horizontal shortening for central German platform (after Heidbach et al., 2010; Tesauro et al., 2006). Shaded relief map is based on digital elevation data of USGS-EROS Centre (http://eros.usgs.gov). (b) Main structural elements of Central Europe, simplified after Kley and Voigt (2008) and Dèzes et al. (2004). Abbreviations: CEB, Central European Basin; EFZ, Elbe Fault Zone; FL, Franconian Lineament; HM, Harz Mountains; LG, Leinetal Graben; LRG, Lower Rhine Graben; LSB, Lower Saxony Basin; LT, Lusatian Thrust; OT, Osning Thrust; TF, Thuringian Forest; URG, Upper Rhine Graben.
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Fig. 2. Geological map of the study area in central German platform, simplified after Toloczyki et al. (2006), illustrating distribution of measurement sites for fault-slip data collection. EGS, Eichenberg-Gotha-Saalfeld Fault Zone. Stereoplot indicates lower hemisphere equal area projection of best-fitting great circle (gray girdle) through the poles of bedding planes indicated by solid dots (n, number of data). Convergent black arrows indicate deduced first-order shortening perpendicular to b-axis of local folds. Orientations are given as dip/azimuth in degrees. Details on geographic coordinates, lithology and orientation of strata for the measurement sites, as well as stereoplots of the collected fault-slip data are given as supplementary material in the online repository to this article.
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Fig. 3. Tilt correction for the fault-slip data of cover rocks. (a) Tilted conjugate-like normal faults on a flank of folded strata. (b) Tilted strike-slip fault plane, characterized by striae parallel to the bedding plane. (c) Overturned limb of a local anticline, with marked bedding-parallel flexural slip. (d) Conjugate-like normal faults cutting through previously tilted strata. (e) Sub-vertical strike-slip fault plane cutting through steeply tilted, folded strata. Stereoplots indicate selected fault-slip data of each outcrop and are equal area projection of the lower hemisphere, including magnetic north (marked by small M). Numbers at top left corner of stereoplots refer to locality of measurement site indicated in Fig. 2. Faults are shown by great circles, including striae as solid dots and slip arrows with double arrows referring to relative strike-slip component and single arrows referring to relative motion of the hanging-wall. Dashed great circles are 41
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bedding planes. Isolated solid and open dots are poles to the bedding and fault planes, respectively. Back tilting is performed by rotation of the fault planes around a horizontal axis parallel to the strike of local bedding plane. Stress axes are determined based on right dihedra method of Angelier and Mechler (1977), and marked as 5-, 4and 3-tined stars for σ1, σ2 and σ3, respectively.
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Fig. 4. Fault kinematic change in the cover rocks. (a) Successive normal and dextral striae evidenced by slickolites overprinting calcite slickenfibers. (b) Successive normal and reverse striae characterized by calcite slickenfibers overprinting slickolites. (c) Successive reverse and sinistral striae indicated by calcite slickenfibers overprinting tectonic groove marks, possibly on a tilted normal fault (shown in gray). (d) Successive striae evidencing kinematic change from dextral to reverse, possibly on a 43
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pre-existing normal fault (shown in gray). (e) Successive horizontal stylolites indicating clockwise change in the direction of contraction. (f) Successive striae evidencing kinematic change from reverse to dextral on steeply tilted bedding plane. (g) Normal striae on a tilted sinistral fault slickenside. (h) Contrasting dextral and sinistral slickolites on a sub-vertical fault plane. Single white and black arrows on the pictures refer to the 1st and 2nd relative chronologies, respectively, indicated by the corresponding numbers on the stereoplots. Convergent and divergent double arrows refer to direction of contraction and extension, respectively, determined based on right dihedra method of Angelier and Mechler (1977). Other description of stereoplots as in Fig. 3.
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Fig. 5. Fault kinematic changes in the basement rocks. (a) Reverse reactivation of a normal fault evidenced by calcite slickenfibers crystallized on incongruous steps of Riedel shear fractures. Note that, in this case, the white and black arrows respectively refer to the 1st and 2nd chronology of slip of the footwall, as the picture is taken from underside of the hanging-wall. (b) Twisted striae on a sub-vertical fault plane suggest successive increments of dextral strike-slip motion and fault block rotation under the same contraction. The 1st and 2nd chronologies on the stereoplots refer to relative motion of the hanging-wall in both cases. Other descriptions of stereoplots as in Fig. 3 and Fig. 4.
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Fig. 6. Paleostress maps for the study area. Horizontal maximum and minimum principal stress axes, σ1 and σ3, are given based on right dihedra method of Angelier and Mechler (1977). The data for which a relative tilt geometry could be reconstructed 46
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(Fig. 3) are categorized as pre-, syn- and post-tilt geometries (a, b and c). The data obtained from horizontal strata, as well as the basement granite, are categorized into consistent kinematics with and presented in parallel to the relative tilt geometries as ―not tilted‖ stress axes (d, e and f). Numbers next to the stress axes indicate relative binary chronology based on successive striae of the corresponding fault-slip data (Fig. 4). Details of the stress tensors are given in Table 1. Background geology as in Fig. 2.
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Fig. 7. Stress tensors for consistent fault-slip datasets. The top box indicates stereoplots of the fault-slip data separated from the entire datasets of the basement and cover rocks based on kinematic consistency. The bottom box indicates stereoplots of the fault-slip data of the cover rocks separated based on consistent chronology and kinematics. Stress tensors are computed based on direct inversion method of Angelier (2002) and given as the orientation of σ1, σ2 and σ3 axes, with 60, 75 and 90% confidence ellipses, 48
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azimuthal confidences in gray curves and the ratio of stress magnitude differences ϕ. Other descriptions of stereoplots as in Fig. 3 and Fig. 4. Details of the stress tensors are given in Table 2.
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Fig. 8. Chronological matrix analysis of events, based on Angelier (1991). Rows and columns refer to the first and second binary chronology, respectively. Numbers are counts of each binary chronology observed throughout the study area. Compatible area characterizes the binary chronologies that are consistent with the given order of the events. Letters refer to the corresponding stress tensors of the cover rocks given in Fig. 7 (i, j, k, l, m, n); ―fl‖ refers to the folding event (Fig. 2). Simplified stereoplots are given for visual appraisal of the events.
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Fig. 9. Post-Triassic stress field evolution in Central Europe. (a) Early Jurassic – Early Cretaceous normal faulting prior to folding of strata. (b) Late Cretaceous – Paleocene strike-slip and thrust faulting before and during inversion of earlier normal faults. (c) Oligocene – Early Miocene normal faulting after folding. (d) Late Miocene – Quaternary stress fields. States of stress and approximate age of events are compiled after: Be, Bergerat (1987); Ra, Rauche and Franzke (1990); Pe, Peterek et al. (1997); Va, Vandycke (2002); Hi, Hinzen (2003); Lo, Lopes Cardozo and Behrmann (2006); Fr, Franzke et al. (2007); Si, Sippel et al. (2009); Sa, Saintot et al. (2013); Ho, Homuth et al. (2014); Co, Coubal et al. (2015); Pr, present study (bold arrows). Background structures as in Fig. 1b. 51
ACCEPTED MANUSCRIPT Table 1. Stress tensors for separated fault-slip data of individual sites. Stress tensors
Long. E
Lithology
Bedding
Fault-slip n
03
50.94192
11.54044
Muschelkalk
Bh
Nr
03
04
51.05900
11.70806
Muschelkalk
Bn 105/22N
Ss
13
Ss
04
Chronology σ1
Pre-tilt 1st
σ2
σ3
ϕ
005/76
184/14
274/00
0.55
195/09
053/79
286/07
0.54
2nd
035/19
206/70
304/03
0.46
10
51.11917
10.01889
Muschelkalk
Bn 139/24E
Ss
SC R
Site Lat. N
T
Geology
IP
Location
05
Pre-tilt
175/01
275/84
085/05
0.50
11
51.11667
10.02167
Muschelkalk
Bn 108/48N
Nr
05
Pre-tilt
011/75
121/05
213/14
0.49
14
51.11389
10.04250
Muschelkalk
Bi 106/80S
Ss
05
Syn-tilt
218/30
101/39
334/37
0.49
15
51.11306
10.05778
Muschelkalk
Bn 115/13S
Ss
05
252/18
038/68
158/11
0.50
16
51.05972
09.98806
Muschelkalk
Bn 119/28S
Nr
02
025/86
128/01
218/04
0.50
Ss
05
187/06
040/83
278/04
0.50
Nr
17
Pre-tilt 1st
121/85
302/05
212/00
0.48
Ss
04
Pre-tilt 2nd
203/02
304/78
112/12
0.50
Iv
03
Syn-tilt
208/05
117/11
323/78
0.50
196/14
051/73
288/09
0.50
05
50.83750
10.91472
Muschelkalk
Bn 030/36E
Ss
08
51.07750
09.95806
Muschelkalk
Bn 130/50S
Iv
09.95111
Muschelkalk
MA
D
51.06389
Bn 121/33S
TE
17
Syn-tilt
222/42
106/26
354/37
0.49
06
Syn-tilt 1st
212/01
122/11
308/79
0.52
298/24
043/31
177/49
0.55
06
2nd
NU
Ss
06
Pre-tilt
51.05667
11.71083
Muschelkalk
Bn 097/16S
Ss
03
21
51.22889
11.30000
Muschelkalk
Bi 117/64N
Ss
02
Pre-tilt
203/07
007/83
113/02
0.50
Iv
09
Syn-tilt 1st
015/12
284/07
164/76
0.50
Iv
02
057/06
324/31
157/59
0.50
Nr
02
091/82
297/07
207/03
0.50
Ss
07
1st
019/04
278/69
111/20
0.51
Iv
09
2nd
212/03
302/06
093/83
0.48
Ss
07
1st
203/03
300/65
112/25
0.58
Iv
04
2nd
218/05
308/05
081/83
0.50
215/22
359/64
119/14
0.49
026/57
173/29
272/15
0.51
23
51.01553
51.10911
AC
22
CE P
19
11.70011
11.70514
Muschelkalk
Muschelkalk
Bh
Bh
2nd
24
51.11128
11.71308
Muschelkalk
Bh
Ss
03
26
51.11194
09.86000
Muschelkalk
Bn 012/54E
Nr
03
Iv
21
035/05
302/33
134/57
0.58
012/76
129/07
221/13
0.50
Post-tilt
27
51.06111
10.00056
Muschelkalk
Bh
Nr
02
29
50.57194
10.51861
Muschelkalk
Bn 104/32S
Iv
08
Syn-tilt
023/29
119/11
229/58
0.50
31
50.45556
10.44806
Muschelkalk
Bn 117/22S
Ss
17
Pre-tilt 1st
018/02
115/79
287/11
0.50
Iv
05
Syn-tilt
226/03
135/08
338/82
0.50
52
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33
50.67139
50.62707
10.66306
10.71105
Lithology
Granite
Granite
Bedding
-
-
Fault-slip n
Chronology σ1
σ2
σ3
ϕ
Nr
03
Post-tilt 2nd
140/65
039/05
306/24
0.50
Ss
07
168/16
284/56
069/29
0.49
Iv
03
045/25
139/09
248/63
0.51
Ss
10
160/13
292/72
067/13
0.51
Nr
05
325/08
056/07
0.47
06
326/79
135/11
225/02
0.48
05
316/01
053/80
226/10
0.54
06
221/04
128/33
318/57
0.50
186/79
Ss
10
230/02
338/82
140/07
0.50
Iv
18
221/03
311/04
097/85
0.54
Nr
03
213/82
015/08
105/02
0.49
Nr
12
064/81
324/02
234/09
0.50
Ss
10
195/11
344/77
103/06
0.52
02
285/03
020/58
193/32
0.54
215/02
102/84
305/05
0.51
261/84
125/04
034/04
0.46
130/04
229/65
038/25
0.49
34
50.63037
10.71425
Granite
-
Nr
35
50.52792
10.67708
Granite
-
Ss
10.69840
Muschelkalk
Granite
Bh
-
MA
50.63215
10.45083
50.62028
10.43582
Muschelkalk
Bh
Ss
32
40
50.92972
10.73694
Muschelkalk
Bn 124/39N
Nr
08
Ss
08
Nr
10
Post-tilt
258/86
016/02
106/04
0.49
Iv
08
Syn-tilt
251/00
341/29
160/61
0.53
Ss
02
Post-tilt
121/10
013/60
217/27
0.50
Iv
04
032/23
302/00
211/67
0.49
Nr
07
130/84
303/06
033/01
0.51
Ss
06
040/03
267/85
129/03
0.50
Ss
04
331/05
208/80
062/08
0.50
174/04
287/79
084/10
0.50
50.79278
CE P
43
50.77000
10.77083
10.88472
AC
42
TE
Ss
39
D
37
50.58722
NU
Iv 36
T
32
Long. E
Stress tensors
IP
Site Lat. N
Geology
SC R
Location
Muschelkalk
Muschelkalk
Bn 139/67E
Bh
Pre-tilt 1st 2nd
44
50.49640
10.60185
Muschelkalk
Bh
Ss
03
46
50.55236
10.63193
Muschelkalk
Bf
Iv
07
Syn-tilt
242/05
152/01
051/85
0.45
47
50.55360
10.63305
Muschelkalk
Bf
Iv
15
Syn-tilt
208/04
117/19
309/71
0.53
48
50.66833
10.68452
Granite
-
Iv
06
034/23
300/10
187/64
0.52
Nr
03
089/60
334/14
237/26
0.50
001/04
222/84
091/04
0.49
50
50.64338
10.69451
Granite
-
Ss
04
52
51.18092
10.34109
Muschelkalk
Bh
Nr
04
1st
053/82
297/03
206/07
0.49
Iv
07
2nd
201/05
110/09
322/80
0.51
53
ACCEPTED MANUSCRIPT
51.34485
10.49187
Lithology
Muschelkalk
Bedding
Bh
Fault-slip n
230/73
128/04
0.48
Ss
02
126/11
279/78
035/05
0.49
Iv
09
1st
188/00
098/39
278/51
0.50
Ss
04
040/01
302/81
130/09
0.50
04
129/06
281/84
0.49
188/03
278/03
058/86
0.43
Muschelkalk
Bh
Iv
57
51.06704
10.27026
Muschelkalk
Bn 148/14E
Iv
58
50.91328
11.21780
Muschelkalk
Bh
Nr
Nr
05
Pre-tilt
063/87
268/02
178/01
0.52
Iv
04
Pre-tilt
001/11
093/10
224/75
0.50
03
Syn-tilt
209/12
300/07
056/75
0.50
03
50.31306
10.51856
Muschelkalk
Bh
1st
141/75
307/15
038/03
0.50
05
2nd
012/08
279/16
128/72
0.49
Nr
04
1st
192/75
291/02
021/15
0.50
Iv
12
2nd
003/04
272/05
134/84
0.49
07
217/03
353/86
127/03
0.49
51.49552
10.38614
Muschelkalk
Bn 018/29E
Ss
07
221/19
056/71
313/05
0.49
62
50.51756
10.68438
Rhyolite
-
Iv
02
038/07
308/01
212/82
0.49
Ss
03
215/09
316/53
118/36
0.50
Nr
03
101/43
279/47
010/01
0.57
Iv
06
170/15
079/02
341/75
0.50
Nr
05
340/83
091/03
182/07
0.51
Ss
18
024/05
283/64
116/26
0.46
Iv
05
206/09
296/04
048/80
0.49
Ss
03
211/05
013/84
121/02
0.50
Ss
03
272/03
026/82
182/07
0.50
213/18
119/11
359/69
0.50
66
51.12507
51.09367
CE P
65
50.64378
11.48074
11.70657
AC
63
TE
Ss
61
D
60
MA
Iv
02
NU
Bn 134/43N
2nd
039/03
Iv Muschelkalk
ϕ
037/16
10.31443
11.10458
σ3
07
51.20324
50.74185
σ2
Ss
55
59
Chronology σ1
T
53
Long. E
Stress tensors
IP
Site Lat. N
Geology
SC R
Location
11.64241
Zechstein
Muschelkalk
Muschelkalk
Bh
Bn 112/12S
Bn 112/20S
71
51.12100
11.55956
Muschelkalk
Bn 117/80S
Iv
02
72
51.20839
11.67153
Muschelkalk
Bn 072/12S
Ss
02
114/02
013/80
204/10
0.50
73
51.19906
11.59680
Muschelkalk
Bn 172/15E
Ss
06
210/05
011/85
120/02
0.50
74
50.99357
11.82502
Muschelkalk
Bh
Ss
14
014/02
278/70
105/19
0.53
Iv
03
238/04
328/02
080/86
0.47
Ss
03
1st
015/01
274/82
105/08
0.50
Ss
05
2nd
118/07
309/83
208/01
0.50
Ss
07
185/02
082/84
275/06
0.50
75
76
50.93801
50.95144
12.03288
11.97187
Zechstein
Bh
Buntsandstein Bf
Post-tilt
Pre-tilt
54
ACCEPTED MANUSCRIPT Location
Geology
Stress tensors
Long. E
Lithology
Bedding
Fault-slip n
Chronology σ1
σ2
σ3
ϕ
77
10.63671
Muschelkalk
Bn 137/20S
Nr
08
Pre-tilt 1st
287/81
154/06
063/07
0.51
Ss
03
2nd
172/10
072/43
273/45
0.50
Ss
10
1st
017/18
253/60
115/23
0.52
Iv
12
210/02
308/77
0.52
04
292/06
063/80
0.50
51.35243
10.57243
Muschelkalk
Bh
Iv
81
51.24872
10.23531
Muschelkalk
Bh
Nr
IP
78
120/13
05
1st
098/88
312/02
222/01
0.50
02
2nd
036/13
129/14
265/70
0.50
136/01
266/89
046/01
0.45
Syn-tilt 2nd
201/07
82
51.15563
10.28585
Muschelkalk
Bf
Ss
SC R
51.40684
T
Site Lat. N
85
50.70506
11.23834
Muschelkalk
Bh
Ss
04
027/01
133/84
297/05
0.50
87
50.79847
11.30925
Muschelkalk
Bh
Nr
08
073/80
328/02
238/09
0.50
Iv
02
222/02
312/05
108/84
0.48
Iv
03
208/12
298/00
029/78
0.50
Iv
03
186/10
089/30
293/58
0.50
02
Post-tilt
MA
NU
Iv
50.83196
11.22312
Muschelkalk
Bh
89
50.82264
11.46522
Muschelkalk
Bh
90
50.79982
11.60964
Muschelkalk
Bh
Ss
02
109/02
224/85
019/05
0.50
91
50.80273
11.60465
Muschelkalk
Bh
Nr
08
223/78
131/00
041/12
0.50
Iv
03
208/03
299/02
064/87
0.50
Bn 138/55W Iv
15
223/13
315/07
074/75
0.49
Nr
11
1st
126/81
295/09
025/02
0.50
Ss
04
2nd
007/11
266/44
107/44
0.49
Nr
04
099/62
290/28
198/05
0.50
Iv
07
214/09
305/04
057/80
0.50
50.88012
TE
11.51573
Muschelkalk
CE P
93
50.89175
11.53530
AC
92
D
88
Muschelkalk
Bh
Syn-tilt
Bedding is given as strike/dip: Bh, horizontal; Bn, tilted; Bf, folded; Bi, overturned. Fault-slip: Nr, normal; Iv, reverse; Ss, strikeslip. n, number of fault-slip data. Orientation of stress axes (σ1≥σ2≥σ3) is given as azimuth/plunge in degrees. ϕ, ratio of stress magnitude differences defined as ϕ=(σ2−σ3)/(σ1−σ3).
55
ACCEPTED MANUSCRIPT
n
σ1
σ2
σ3
ϕ
α
a
30
018/77
139/07
230/11
0.35
26±24
b
46
183/18
326/68
089/12
0.44
T
Table 2. Stress tensors for consistent fault-slip datasets.
c
22
042/12
133/06
250/77
0.36
d
12
318/03
215/74
049/15
0.13
e
138
126/85
306/05
036/00
0.38
16±13
f
251
211/04
348/85
121/04
0.48
12±13
g
261
029/03
299/01
194/87
0.49
17±16
h
69
125/01
221/77
035/13
0.20
24±24
i
115
117/85
304/05
214/01
0.48
15±11
j
61
189/05
023/85
279/01
0.49
09±09
k
30
013/04
281/26
112/63
0.18
23±17
l
163
030/01
300/00
209/89
0.53
13±10
m
23
158/76
024/10
292/10
0.47
16±10
n
47
233/85
038/05
0.34
23±24
Basement
MA
D
TE 129/01
NU
Cover Fig. 7
IP
23±14
SC R
Fig. 7
21±12 34±17
AC
CE P
n, number of fault-slip data. Orientation of stress axes (σ1≥σ2≥σ3) is given as azimuth/plunge in degree. ϕ, ratio of stress magnitude differences defined as ϕ=(σ2−σ3)/(σ1−σ3). α, average misfit angle between actual slip and maximum resolved shear stress in degrees (acceptable for α<25°).
56
ACCEPTED MANUSCRIPT Highlights
Fault kinematic changes are documented for the central German platform.
Structural binary chronologies unravel the succession of tectonic events.
Analysis of the entire fault-slip dataset reconstructs regional states of stress.
The basement rocks and cover strata indicate the same states of stress.
CE P
TE
D
MA
NU
SC R
IP
T
AC
7
57