It is agreed that mantle dynamics have played a role in generating and maintaining the elevated topography of Anatolia during Neogene times. However, there is debate about the relative importance of subduction zone and asthenospheric processes. Key issues concern onset and cause of regional uplift, thickness of the lithospheric plate, and the presence/absence of temperature and/or compositional anomalies within the convecting mantle. Here, we tackle these interlinked issues by analyzing and modeling two disparate suites of observations. First, a drainage inventory of 1,844 longitudinal river profiles is assembled. This database is inverted to calculate the variation of Neogene regional uplift through time and space by minimizing the misfit between observed and calculated river profiles subject to independent calibration. Our results suggest that regional uplift commenced at 20 Ma in the east and propagated westward. Second, we have assembled a database of geochemical analyses of basaltic rocks. Two different approaches have been used to quantitatively model this database with a view to determining the depth and degree of asthenospheric melting across Anatolia. Our results suggest that melting occurs at depths as shallow as 60 km in the presence of mantle potential temperatures as high as 1400°C. There is evidence that temperatures are higher in the east, consistent with the pattern of subplate shear wave velocity anomalies. Our combined results are consistent with isostatic and admittance analyses and suggest that elevated asthenospheric temperatures beneath thinned Anatolian lithosphere have played a first‐order role in generating and maintaining regional dynamic topography and basaltic magmatism.
The Afghan-Tajik Depression is a sedimentary basin in the Alpine-Himalayan mountain chain. It is traversed by series of north-south arcuate folds, suggesting that the basin is undergoing east-west compression. A second set of folds in the south of the depression runs east-west, crosscutting those trending north-south. We present results from teleseismic body waveform inversion and depth phase modeling for five recent earthquakes, and from detailed mapping of structures related to active faulting based on satellite imagery and topographic data. We argue that both sets of folds are active and that deformation is vertically partitioned, with north-south compression accommodated on east-west–trending thrust faults within the basement, and east-west compression accommodated on north-south–trending thrust faults above a detachment within the basin fill. The observation that orthogonal shortening can be accommodated simultaneously in this way has several important implications. Juxtaposed orthogonal fold systems identified in the geological record may not require temporally separate events, particularly in gravity-driven fold-and-thrust belts in foreland-basin settings. Pervasive detachment may limit the size of potential earthquakes by preventing single events from rupturing the entire seismogenic layer. However, it may also disguise geomorphic signatures of faulting and interseismic strain accumulation within the lower layer, hindering accurate seismic hazard assessment and regional tectonic interpretations.
Quantifying the depths and temperatures from which igneous rocks are derived is an important step in understanding volcanic, magmatic and mantle processes. We present meltPT, a Python package that allows users to apply twelve published whole-rock thermobarometers within a consistent framework, as well as combine thermobarometric results and geothermal models to estimate mantle potential temperatures. We apply meltPT to basaltic rocks from mid-ocean ridges and the Hawaiian Islands. We find mid-ocean ridge basalts equilibrate between 1–2 GPa and 1275–1475 ℃, corresponding to an ambient mantle potential temperature of ~1400 ℃. We estimate that the Hawaiian plume has an excess temperature of ~150 ℃. Hawaiian melt-equilibration depths increase from 1–3 GPa to 2.5–5 GPa through each island's life cycle. Our results indicate that multiple lithologies are present within the plume, and that transient plume reconfiguration in response to changing plate velocity is a viable mechanism for generating Hawaiʻi's two geochemically distinct plume tracks.
<p>Glacial and fluvial landforms record the recent history of Earth&#8217;s surface, and hold information on the climatic or tectonic processes that shape the landscape. Southern Patagonia hosts uniquely well-preserved fluvial cut-and-fill terraces. A record of fluvial incision since 1.5&#8211;4 Ma is preserved from K-Ar dated basalt flows atop relict paleosurfaces, and published regional thermochronometric dating and modelling suggest an increased phase of exhumation in the last 1&#8211;3 Ma. However, few constraints exist on the onset of river incision, which might provide clues as to possible drivers of regional landscape change. To constrain the timing of Pleistocene incision and landscape evolution in southern Patagonia, we present new cosmogenic <sup>10</sup>Be exposure ages of surface cobbles and amalgamated pebbles from fluvial terraces in the Tres Lagos region 50&#186;S) and the R&#237;o Santa Cruz. Locally, dated basalt flows set a maximum age of ~2.2 Ma for the Tres Lagos terraces, and between 2.2 and 1.7 Ma in the Condor Cliffs region of the R&#237;o Santa Cruz. Preliminary <sup>10</sup>Be ages for terrace surfaces in the Tres Lagos region reveal ages between 45&#8211;845 ka. Ages of upstream fluvial terraces of the R&#237;o Santa Cruz reveal ages between 290&#8211;830 ka. The sequence of terrace ages shows that the phase of net incision started ca. 1 Ma after widespread emplacement of basalts, concomitant with enhanced climatic forcing following the Mid-Pleistocene Transition. Ages are also in agreement with the incision history recorded in dated fluvial terraces of other Patagonian rivers, notably the R&#237;o Deseado, where ages range from 400 ka&#8211;1 Ma (47&#186;S; Tobal et al., 2021). We argue that the combined results suggest that this net-incisional phase was widespread, therefore unlikely to result from local tectonic drivers, hence probably climatically driven. Our record of Pleistocene landscape evolution is similar to other records throughout the Andes, where the timing of fluvial incision has been linked with the transition to enhanced climatic forcing after ~1 Ma (e.g., Central Andes). Our results point a strong influence of the Mid-Pleistocene Transition on landscape evolution on a continental scale, and notably also in the southernmost regions of South America.</p>
Alluvial rivers aggrade, incise, and adjust their sediment‐transport rates in response to changing sediment and water supply. Fluvial landforms, such as river terraces, and downstream stratigraphic archives may therefore record information about past environmental change. Using a physically based model describing sediment transport and long‐profile evolution of alluvial rivers, we explore how their responses to environmental change depend on distance downstream, forcing timescales, and whether sediment or water supply is varied. We show that amplitudes of aggradation and incision, and therefore the likelihood of terrace formation, are greater upstream and in shorter and/or wetter catchments. Aggradation and incision, and therefore terrace ages, may also lag behind environmental change. How sediment‐transport rates evolve depends strongly on whether water or sediment supply is varied. Diverse responses to environmental change could arise in natural alluvial valleys, controlled by their geometry and hydrology, with important implications for paleo‐environmental interpretations of fluvial archives.
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