TY  - THES
A1  - Landgraf, Angela
T1  - Fault interaction at different time- and length scales : the North Tehran thrust and Mosha-Fasham fault (Alborz mountains, Iran)
T1  - Störungsinteraktion auf verschiedenen räumlichen und zeitlichen Skalen : die Nord-Teheran Überschiebung und die Mosha-Fasham Störung, Elburs Gebirge, Iran
N2  - The seismically active Alborz mountains of northern Iran are an integral part of the Arabia-Eurasia collision. Linked strike-slip and thrust/reverse-fault systems in this mountain belt are characterized by slow loading rates, and large earthquakes are highly disparate in space and time. Similar to other intracontinental deformation zones such a pattern of tectonic activity is still insufficiently understood, because recurrence intervals between seismic events may be on the order of thousands of years, and are thus beyond the resolution of short term measurements based on GPS or instrumentally recorded seismicity. This study bridges the gap of deformation processes on different time scales. In particular, my investigation focuses on deformation on the Quaternary time scale, beyond present-day deformation rates, and it uses present-day and paleotectonic characteristics to model fault behavior. The study includes data based on structural and geomorphic mapping, faultkinematic analysis, DEM-based morphometry, and numerical fault-interaction modeling. In order to better understand the long- to short term behavior of such complex fault systems, I used geomorphic surfaces as strain markers and dated fluvial and alluvial surfaces using terrestrial cosmogenic nuclides (TCN, 10Be, 26Al, 36Cl) and optically stimulated luminescence (OSL). My investigation focuses on the seismically active Mosha-Fasham fault (MFF) and the seismically virtually inactive North Tehran Thrust (NTT), adjacent to the Tehran metropolitan area. Fault-kinematic data reveal an early mechanical linkage of the NTT and MFF during an earlier dextral transpressional stage, when the shortening direction was oriented northwest. This regime was superseded by Pliocene to Recent NE-oriented shortening, which caused thrusting and sinistral strike-slip faulting. In the course of this kinematic changeover, the NTT and MFF were reactivated and incorporated into a nascent transpressional duplex, which has significantly affected landscape evolution in this part of the range. Two of three distinctive features which characterize topography and relief in the study area can be directly related to their location inside the duplex array and are thus linked to interaction between eastern MFF and NTT, and between western MFF and Taleghan fault, respectively. To account for inferred inherited topography from the previous dextral-transpression regime, a new concept of tectonic landscape characterization has been used. Accordingly, I define simple landscapes as those environments, which have developed during the influence of a sustained tectonic regime. In contrast, composite landscapes contain topographic elements inherited from previous tectonic conditions that are inconsistent with the regional present-day stress field and kinematic style. Using numerical fault-interaction modeling with different tectonic boundary conditions, I calculated synoptic snapshots of artificial topography to compare it with the real topographic metrics. However, in the Alborz mountains, E-W faults are favorably oriented to accommodate the entire range of NW- to NE-directed compression. These faults show the highest total displacement which might indicate sustained faulting under changing boundary conditions. In contrast to the fault system within and at the flanks of the Alborz mountains, Quaternary deformation in the adjacent Tehran plain is characterized by oblique motion and thrust and strike-slip fault systems. In this morphotectonic province fault-propagation folding along major faults, limited strike-slip motion, and en-échelon arrays of second-order upper plate thrusts are typical. While the Tehran plain is characterized by young deformation phenomena, the majority of faulting took place in the early stages of the Quaternary and during late Pliocene time. TCN-dating, which was performed for the first time on geomorphic surfaces in the Tehran plain, revealed that the oldest two phases of alluviation (units A and B) must be older than late Pleistocene. While urban development in Tehran increasingly covers and obliterates the active fault traces, the present-day kinematic style, the vestiges of formerly undeformed Quaternary landforms, and paleo earthquake indicators from the last millennia attest to the threat that these faults and their related structures pose for the megacity.
N2  - Das seismisch aktive Elburs Gebirge im Nordiran ist Bestandteil der Arabisch-Eurasischen Kollisionszone. Gekoppelte Blattverschiebungs- und Überschiebungssysteme dieses Gebirges zeichnen sich durch geringe Spannungsaufbauraten aus. Dementsprechend treten große Erdbeben räumlich und zeitlich weit verteilt voneinander auf und Wiederkehrperioden solcher Erdbeben können tausende von Jahren dauern und wurden noch nicht von kurzzeitigen Messmethoden, wie GPS oder instrumenteller Seismologie erfasst. Diese Arbeit überbrückt verschiedene Zeitskalen. Diese Studie beinhaltet insbesondere Auswertungen struktureller und geomorphologischer Kartierungen, störungskinematische Analysen, auf digitalen Höhenmodellen basierende Morphometrie und numerische Modellierung von Störungsinteraktion. Um das lang- und kurzfristige Verhalten solcher komplexen Schwächezonen besser zu verstehen, benutze ich geomorphologische Oberflächen als Deformationsmarker und datiere alluviale und fluviatile Oberflächen mittels kosmogener Nuklide (TCN, 10Be, 26Al, 36Cl) und optisch stimulierter Lumineszenz (OSL). Mein Untersuchungsgebiet umfasst die seismisch aktive Mosha-Fasham Störung (MFF) und die als seismisch quasi inaktiv geltende Nordteheranstörung (NTT), die sich in unmittelbarer Nähe zum Teheraner Ballungsgebiet befinden. Die Ergebnisse zeigen, dass sich das Deformationfeld mit der Zeit verändert hat. Die störungskinematischen Daten haben ergeben, dass NTT und MFF bereits seit einer früheren dextral-transpressionalen Phase unter NW-gerichteter Einengung mechanisch gekoppelt sind. Dieses System wurde von pliozäner und bis heute andauernder NE-gerichteter Einengung ersetzt, woraufhin sich Überschiebungen und linkslaterale Blattverschiebungen herausbildeten. Während dieses kinematischen Wechsels wurden NTT und MFF reaktiviert und in ein beginnendes transpressionales Duplexsystem eingebunden, welches die Landschaftentwicklung in diesem Teil des Gebirges signifikant beeinflusst hat. Zwei von drei ausgeprägten topographischen Besonderheiten des Untersuchungsgebietes können direkt mit deren Lage in der Duplexanordnung in Verbindung gebracht werden und spiegeln Interaktion zwischen den östlichen Segmenten von NTT und MFF, bzw., zwischen dem westlichen Segment der MFF und der parallelen Taleghan Schwächezone wider. Um diejenige Topographie auszuweisen, die möglicherweise aus der vorhergehenden Phase vererbt wurde, wurde ein neues Konzept tektonischer Landschaftscharakterisierung benutzt. Einfache Landschaften sind unter dem Einfluß gleichbleibender tektonischer Randbedingungen entstanden. Dagegen enthalten zusammengesetzte Landschaften vererbte Elemente vergangener tektonischer Randbedingungen, die mit dem heutigen Spannungsfeld und kinematischen Stil unvereinbar sind. Mittels numerischer Störungsinteraktionsmodellierungen teste ich verschiedene Randbedingungen und berechne synoptische Momentaufnahmen künstlicher Topographie um sie mit reellen topographischen Maßen zu vergleichen. Im Elburs Gebirge treten allerdings auch E-W streichende Schwächezonen auf, die so günstig orientiert sind, dass sie Verformung unter der gesamten Einengungsspanne von Nordwest nach Nordost zeigen. Diese weisen den höchsten totalen Versatz auf. Hier tritt das Grundgebirge zutage und wird versetzt, was, wie die Modellierungen vermuten lassen, auf langanhaltende Verformung unter sich ändernden Randbedingungen hinweisen kann. Quartäre Deformation in der benachbarten Teheran Ebene ist durch Schrägbewegungen, Überschiebungen und Blattverschiebungssyteme gekennzeichnet, die typischerweise in Auffaltungen entlang von Hauptstörungen, vereinzelten Blattverschiebungen und en-échelon Anordnungen untergeordneter oberflächlicher Überschiebungen resultieren. Junge Deformation tritt auf, die Hauptbewegungen fanden allerdings im frühen Quartär und wahrscheinlich späten Pliozän statt. TCN-Datierungen, die erstmalig an geomorphologischen Oberflächen in der Teheran Ebene durchgeführt wurden, ergeben dass die beiden älteren Sedimentationsphasen (Einheiten A und B) älter sind als spätes Pleistozän. Obwohl die urbane Entwicklung im Teheraner Ballungsraum die aktiven Störungslinien zunehmend verdeckt und ausradiert, zeugen der heutige kinematische Stil, die Überreste ehemals unverstellter Quartärer Landschaftsformen und Hinweise auf Paläoerdbeben während der letzten Jahrtausende von der Gefahr, die diese Schwächezonen für die Megastadt bedeuten.
KW  - Störungsinteraktion
KW  - Tektonische Geomorphologie
KW  - Kosmogene Nuklide
KW  - Elburs
KW  - Iran
KW  - Fault interaction
KW  - Tectonic geomorphology
KW  - Cosmogenic nuclides
KW  - Alborz
KW  - Iran
Y1  - 2010
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus-50800
ER  - 
TY  - JOUR
A1  - Kirby, Eric
A1  - Whipple, Kelin X.
T1  - Expression of active tectonics in erosional landscapes
JF  - Journal of structural geology
N2  - Understanding the manner and degree to which topography in active mountain ranges reflects deformation of the Earth's surface remains a first order goal of tectonic geomorphology. A substantial body of research in the past decade demonstrates that incising channel systems play a central role in setting relationships among topographic relief, differential rock uplift rate, and climatically modulated erosional efficiency. This review provides an introduction to the analysis and interpretation of channel profiles in erosional mountain ranges. We show that existing data support theoretical expectations of positive, monotonic relationships between channel steepness index, a measure of channel gradient normalized for downstream increases in drainage area, and erosion rate at equilibrium, and that the transient response to perturbations away from equilibrium engenders specific spatial patterns in channel profiles that can be used to infer aspects of the forcing. These aspects of channel behavior lay the foundation for a series of case studies that we use to illustrate how focused, quantitative analysis of channel morphology can provide insight into the spatial and temporal dynamics of active deformation. Although the complexities of river response to climate, lithology, and uplift patterns mean that multiple interpretations of topographic data alone will always possible, we show that application of stream profile analysis can be a powerful reconnaissance tool with which to interrogate the rates and patterns of deformation in active mountain belts.
KW  - Tectonic geomorphology
KW  - Active tectonics
KW  - River profiles
KW  - Neotectonics
Y1  - 2012
U6  - https://doi.org/10.1016/j.jsg.2012.07.009
SN  - 0191-8141
VL  - 44
SP  - 54
EP  - 75
PB  - Elsevier
CY  - Oxford
ER  - 
TY  - JOUR
A1  - Kirby, Eric
A1  - Harkins, Nathan
T1  - Distributed deformation around the eastern tip of the Kunlun fault
JF  - INTERNATIONAL JOURNAL OF EARTH SCIENCES
N2  - Whether active strain within the Indo-Asian collision zone is primarily localized along major strike-slip fault systems or is distributed throughout the intervening crust between faults remains uncertain. Despite refined estimates of slip rates along many of the major fault zones, relatively little is known about how displacement along these structures is accommodated at fault terminations. Here, we show that a systematic decrease in left-lateral slip rates along the eastern similar to 200 km of the Kunlun fault, from > 10 mm/year to < 1 mm/year, is coincident with high topography in the Anyemaqen Shan and with a broad zone of distributed shear and clockwise vorticity within the Tibetan Plateau. Geomorphic analysis of river longitudinal profiles, coupled with inventories of cosmogenic radionuclides in fluvial sediment, reveal correlated variations in fluvial relief and erosion rate across the Anyemaqen Shan that reflect ongoing differential rock uplift across the range. Our results imply that the termination of the Kunlun fault system is accommodated by a combination of distributed crustal thickening and by clockwise rotation of the eastern fault segments.
KW  - Tibetan plateau
KW  - Active tectonics
KW  - Tectonic geomorphology
KW  - Strike-slip faults
Y1  - 2013
U6  - https://doi.org/10.1007/s00531-013-0872-x
SN  - 1437-3254
SN  - 1437-3262
VL  - 102
IS  - 7
SP  - 1759
EP  - 1772
PB  - SPRINGER
CY  - NEW YORK
ER  - 
TY  - JOUR
A1  - Gao, Mingxing
A1  - Zeilinger, Gerold
A1  - Xu, Xiwei
A1  - Wang, Qingliang
A1  - Hao, Ming
T1  - DEM and GIS analysis of geomorphic indices for evaluating recent uplift of the northeastern margin of the Tibetan Plateau, China
JF  - Geomorphology : an international journal on pure and applied geomorphology
N2  - The northeastern margin of the Tibetan Plateau is a tectonically active region consisting of a series of faults with bounded intermountain basins and is located in the transition zone between the Tibetan Plateau and the Loess Plateau. Active deformation that may affect the topography in this region can be quantified using geomorphic indices. Therefore, we applied geomorphic indices such as the hypsometric integral and the stream length gradient index to infer neo-tectonics in the northeastern margin of the Tibetan Plateau. Different time-scaled geodetic leveling data and river incision rates were also integrated into the investigation. The results show that the hypsometric integrals are not significantly affected by lithology but spatially correspond to the hanging walls of thrust faults. The hypsometric integrals are also positively correlated with the leveling data. Although the stream length gradient index is influenced by lithology, its most pronounced anomalies of the stream length gradient are associated with the thrust faults. Consequently, the uplift in the northeast margin of the Tibetan Plateau appeared to be concentrated along the hanging walls of the thrust faults.
KW  - Tectonic geomorphology
KW  - Hypsometry analysis
KW  - Stream length gradient
KW  - Active tectonics
KW  - Leveling data
KW  - Tibetan Plateau
Y1  - 2013
U6  - https://doi.org/10.1016/j.geomorph.2013.02.008
SN  - 0169-555X
VL  - 190
IS  - 20
SP  - 61
EP  - 72
PB  - Elsevier
CY  - Amsterdam
ER  - 
TY  - JOUR
A1  - Thompson, Jessica A.
A1  - Chen, Jie
A1  - Yang, Huili
A1  - Li, Tao
A1  - Bookhagen, Bodo
A1  - Burbank, Douglas
T1  - Coarse- versus fine-grain quartz OSL and cosmogenic Be-10 dating of deformed fluvial terraces on the northeast Pamir margin, northwest China
JF  - Quaternary geochronology : the international research and review journal on advances in quaternary dating techniques
N2  - Along the NE Pamir margin, flights of late Quaternary fluvial terraces span actively deforming fault-related folds. We present detailed results on two terraces dated using optically stimulated luminescence (OSL) and cosmogenic radionuclide Be-10 (CRN) techniques. Quartz OSL dating of two different grain sizes (4-11 mu m and 90-180 mu m) revealed the fine-grain quartz fraction may overestimate the terrace ages by up to a factor of ten. Two-mm, small-aliquot, coarse-grain quartz OSL ages, calculated using the minimum age model, yielded stratigraphically consistent ages within error and dated times of terrace deposition to similar to 9 and similar to 16 ka. We speculate that, in this arid environment, fine-grain samples can be transported and deposited in single, turbid, and (sometimes) night-time floods that prevent thorough bleaching and, thereby, can lead to relatively large residual OSL signals. In contrast, sand in the fluvial system is likely to have a much longer residence time during transport, thereby providing greater opportunities for thorough bleaching. CRN Be-10 depth profiles date the timing of terrace abandonment to similar to 8 and similar to 14 ka: ages that generally agree with the coarse-grain quartz OSL ages. Our new terrace age of similar to 13-14 ka is broadly consistent with other terraces in the region that indicate terrace deposition and subsequent abandonment occurred primarily during glacial-interglacial transitions, thereby suggesting a climatic control on the formation of these terraces on the margins of the Tarim Basin. Furthermore, tectonic shortening rates calculated from these deformed terraces range from similar to 1.2 to similar to 4.6 mm/a and, when combined with shortening rates from other structures in the region, illuminate the late Quaternary basinward migration of deformation to faults and folds along the Pamir-Tian Shan collisional interface.
KW  - Tectonic geomorphology
KW  - Deformation
KW  - Quaternary terraces
KW  - Pamir
KW  - Tian shan
Y1  - 2018
U6  - https://doi.org/10.1016/j.quageo.2018.01.002
SN  - 1871-1014
SN  - 1878-0350
VL  - 46
SP  - 1
EP  - 15
PB  - Elsevier
CY  - Oxford
ER  -