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1. Pre‐Thrusting Stratigraphic Control on the Transition From a Thin‐Skinned to Thick‐Skinned Structural Style: An Example From the Double‐Decker Idaho‐Montana Fold‐Thrust Belt

   https://doi.org/10.1029/2020TC006429  

   Parker, S. D.; Pearson, D. M. (May 2021, Tectonics)

   Abstract Continental fold‐thrust belts display a variety of structural styles, ranging from thin‐skinned thrusts following weak lithologic contacts to thick‐skinned thrusts that deform mechanical basement. The common practice of splitting fold‐thrust belts into thin‐skinned and thick‐skinned map domains has not yielded a predictive model of the primary controls on structural style. Within the Mesozoic‐Paleogene Idaho‐Montana fold‐thrust belt (44°N‐45°N, 112°W‐114°W), we identify crosscutting thin‐skinned and thick‐skinned thrusts within an otherwise thin‐skinned map domain. This transition occurs within a thin (∼2.5 km) portion of the western Laurentian passive margin, where lower strata pinch out over a prominent basement high (Lemhi arch). Early fold‐thrust belt shortening of sedimentary cover rocks was accommodated through detachment folding, followed by east‐directed, thin‐skinned thrusting along regional‐scale faults (Thompson Gulch and Railroad Canyon thrusts). Later, basement and cover rocks were tilted toward the southeast and a basement‐involved normal fault was reactivated during thick‐skinned thrusting (Radio Tower‐Baby Joe Gulch‐Italian Gulch thrusts), which accommodated shortening at an oblique angle to and truncated the basal detachment of the older thin‐skinned thrusts. This progression from thin‐skinned to thick‐skinned thrusting occurred >50 km from the foreland, coincident with a regional basement high. Thus, the Idaho‐Montana fold‐thrust belt is a double‐decker system, with upper thin‐skinned and lower thick‐skinned domains. This double‐decker model is applicable to other fold‐thrust belts and predicts that the transition from thin‐skinned to thick‐skinned thrusting occurs where the growing critically tapered wedge can no longer fit within the sedimentary cover rocks and the basal detachment steps down into the structurally lower mechanical basement. 

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2. Tectonostratigraphy and major structures of the Georgian Greater Caucasus: Implications for structural architecture, along-strike continuity, and orogen evolution

   https://doi.org/10.1130/GES02385.1  

   Trexler, Charles C.; Cowgill, Eric; Niemi, Nathan A.; Vasey, Dylan A.; Godoladze, Tea (January 2022, Geosphere)

   Abstract Although the Greater Caucasus Mountains have played a central role in absorbing late Cenozoic convergence between the Arabian and Eurasian plates, the orogenic architecture and the ways in which it accommodates modern shortening remain debated. Here, we addressed this problem using geologic mapping along two transects across the southern half of the western Greater Caucasus to reveal a suite of regionally coherent stratigraphic packages that are juxtaposed across a series of thrust faults, which we call the North Georgia fault system. From south to north within this system, stratigraphically repeated ~5–10-km-thick thrust sheets show systematically increasing bedding dip angles (<30° in the south to subvertical in the core of the range). Likewise, exhumation depth increases toward the core of the range, based on low-temperature thermochronologic data and metamorphic grade of exposed rocks. In contrast, active shortening in the modern system is accommodated, at least in part, by thrust faults along the southern margin of the orogen. Facilitated by the North Georgia fault system, the western Greater Caucasus Mountains broadly behave as an in-sequence, southward-propagating imbricate thrust fan, with older faults within the range progressively abandoned and new structures forming to accommodate shortening as the thrust propagates southward. We suggest that the single-fault-centric “Main Caucasus thrust” paradigm is no longer appropriate, as it is a system of faults, the North Georgia fault system, that dominates the architecture of the western Greater Caucasus Mountains. 

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3. Mode of intracontinental mountain building controlled by lower crustal composition and mantle lithosphere depletion

   https://doi.org/10.1038/s41467-025-63468-1  

   Xu, Xi; Zuza, Andrew V; Gerya, Taras; Chen, Lin; Kuang, Xingtao; Chen, Hanlin; Wang, Baodi; Liu, Jingao; Shi, Xuhua; Sun, Yanyun; et al (December 2025, Nature Communications)

   Tectonic plate convergence is accommodated across the continental lithosphere via discrete lithospheric subduction or distributed shortening and thickening. These end-member deformation modes control intra-plate mountain building, but their selection mechanism remains unclear. The variable composition of the continental crust and lithospheric mantle, which impacts its density and rheology, can be inferred by the distribution of magnetic-indicated crustal iron. Here we demonstrate that vertically coherent pure-shear shortening dominated the active Tian Shan orogen, central Asia, based on high-resolution aeromagnetic imaging and geophysical-geodetic observations. Integrating these findings with thermomechanical collisional models reveals that the mode of intracontinental deformation depends on contrasts in lower crust composition and mantle lithosphere depletion between the converging continents and central orogenic region. Distributed shortening prevails when the converging continents have a more iron-enriched mafic crust and iron-depleted mantle lithosphere when compared to the intervening orogenic region. Conversely, continental subduction occurs without such lithospheric contrasts. This result explains how the Tian Shan orogen formed via distributed lithospheric thickening without continental subduction or underthrusting. Our interpretations imply that iron distribution in the crust correlates with lithospheric compositional, density, and rheological structure, which impacts the preservation and destruction of Earth’s continents, including long-lived cratons, during intracontinental orogeny. 

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4. Cenozoic structural framework and crustal shortening of the Tethyan Himalaya, Himachal Pradesh, northwestern India

   https://doi.org/10.1130/abs/2024AM-402536  

   Branton, Evon; Haproff, Peter J; Vlaha, Dominik; Zuza, Andrew; Guevara, Victor; Reyes, Francisco; Webb, A Alexander; Singh, Birendra P (January 2024, Geological Society of America Abstracts with Programs)

   The Tethyan Himalayan sequence (THS) is the structurally highest lithotectonic unit of Indian affinity within the Cenozoic Himalayan orogen. In the NW Himalaya of the Himachal Pradesh, India, the Neoproterozoic–Cretaceous THS is thought to have relatively modest deformation despite the unit commonly recording early collision-related shortening. This lack of significant deformation contrasts that of other Himachal lithotectonic units closer to the foreland. In addition, burial depths of the Himachal THS estimated from structural reconstructions (~10 km) and basal metamorphic pressures (7–8 kbar, ~28 km lithostatic burial) conflict. To address these issues, we performed geologic mapping, thermochronology, and restored new balanced cross sections along two transects across the Himachal THS to better constrain its deformation state and timing, stratigraphic thickness, and burial extent. Along the Spiti and Pin valleys, the THS is shortened by seven NE-dipping thrusts and one SW-dipping thrusts that mostly form fault-propagation folds. The Mata Nappe region (NE of Spiti Valley) has been reinterpreted as a thrust pop-up structure, consistent with structural observations. Along this transect, the estimated THS thickness measured from the basal Akpa granite and Haimanta Group to the uppermost-exposed Tandi Group is ~12.3 km. Restoration of one cross section along this transect yields a minimum shortening of ~30 km (~22% strain). Farther SE along Sutlej Valley, the THS is cut by three SW-dipping thrusts and several S-dipping normal faults. The estimated thickness of the exposed Akpa granite and Haimanta Group is ~8.5 km. Restoration of one cross section along this transect yields a minimum shortening of ~8 km (~21% strain). Thrusts mapped along both transects are interpreted to branch from a single decollement formed by the South Tibet detachment and Great Counter thrust. Our THS shortening estimates added to those for other Indian rocks in the Himachal Himalaya (Webb, 2013) yields a total minimum estimate of ~515–537 km. Preliminary zircon (U-Th)/He dates along Spiti and Pin valleys generally young towards the SW from ca. 42–5 Ma. These results confirm: (1) relatively minor shortening of the Himachal THS that was likely compensated by duplexing of other units; and (2) the discrepancy between THS burial estimates, which may be a product of non-lithostatic pressure. 

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5. Diverse Deformation Mechanisms and Lithologic Controls in an Active Orogenic Wedge: Structural Geology and Thermochronometry of the Eastern Greater Caucasus

   https://doi.org/10.1029/2022TC007349  

   Tye, A. R.; Niemi, N. A.; Cowgill, E.; Kadirov, F. A.; Babayev, G. R. (December 2022, Tectonics)

   Abstract Orogenic wedges are common at convergent plate margins and deform internally to maintain a self‐similar geometry during growth. New structural mapping and thermochronometry data illustrate that the eastern Greater Caucasus mountain range of western Asia undergoes deformation via distinct mechanisms that correspond with contrasting lithologies of two sedimentary rock packages within the orogen. The orogen interior comprises a package of Mesozoic thin‐bedded (<10 cm) sandstones and shales. These strata are deformed throughout by short‐wavelength (<1 km) folds that are not fault‐bend or fault‐propagation folds. In contrast, a coeval package of thick‐bedded (up to 5 m) volcaniclastic sandstone and carbonate, known as the Vandam Zone, has been accreted and is deformed via imbrication of coherent thrust sheets forming fault‐related folds of 5–10 km wavelength. Structural reconstructions and thermochronometric data indicate that the Vandam Zone package was accreted between ca. 13  and 3 Ma. Following Vandam Zone accretion, thermal modeling of thermochronometric data indicates rapid exhumation (∼0.3–1 mm/yr) in the wedge interior beginning between ca. 6 and 3 Ma, and a novel thermochronometric paleo‐rotation analysis suggests out‐of‐sequence folding of wedge‐interior strata after ca. 3 Ma. Field relationships suggest that the Vandam Zone underwent syn‐convergent extension following accretion. Together, the data record spatially and temporally variable deformation, dependent on both the mechanical properties of deforming lithologies and perturbations such as accretion of material from the down‐going to the overriding plate. The diverse modes of deformation are consistent with the maintenance of critical taper. 

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