Geophysical investigations in the Nankai Trough and Sumatran subduction zones

Martin, Kylara Margaret

08 July 2013

The 2004 Sumatra-Andaman and the 2011 Tohoku-Oki earthquakes demonstrate the importance of understanding subduction zone earthquakes and the faults that produce them. Faults that produce earthquakes and/or tsunamis in these systems include plate boundary megathrusts, splay faults (out of sequence thrusts), and strike-slip faults from strain partitioning. Offshore Japan, IODP Exp. 314 collected logging while drilling (LWD) data across several seismically-imaged fault splays in the Nankai Trough accretionary prism. I combine LWD resistivity data with a model of fluid invasion to compare the permeabilities of sands. My results indicate that sands within faulted zones are 2-3 orders of magnitude more permeable than similar undisturbed sands. Therefore fault zones are likely to be fluid conduits within the accretionary wedge. Fluids can affect the physical and chemical properties of the faulted material, increasing pore pressures and effectively lubricating the faults. Fluids play an important role in fault slip, but hazard analysis also requires an understanding of fault geometry and slip direction. Both Japan and Sumatra exhibit strain partitioning, where oblique convergence between tectonic plates is partitioned between the megathrust and strike-slip faults proximal to the arc. Offshore Sumatra, I combine profiles from a 2D seismic survey (SUMUT) with previous bathymetry and active seismic surveys to characterize the West Andaman Fault adjacent to the Aceh forearc Basin. Along this fault I interpret transpressional flower structures that cut older thrust faults. These flower structures indicate that the modern West Andaman Fault is a right lateral strike-slip fault and thus helps to accommodate the translational component of strain in this highly oblique subduction zone. Offshore the Kii Peninsula, Japan, I analyze a trench-parallel depression that forms a notch in the seafloor just landward of the megasplay fault system, along the seaward edge of the forearc Kumano Basin. Using a 12 km wide, 3D seismic volume, I observe vertical faults and faults which dip toward the central axis of the depression, forming apparent flower structures. The along-strike geometry of the vertical faults makes predominantly normal or thrust motion unlikely. I conclude, therefore, that this linear depression is the bathymetric expression of a transtensional fault system. While the obliquity of convergence in the Nankai Trough is small (~15 degrees), this Kumano Basin Edge Fault Zone could be due to partitioning of the plate convergent strain. The location of the West Andaman Fault and KBEFZ within the forearc may be controlled by the rheology contrast between active accretionary wedges and the more stable crust beneath forearc basins. / text

Strain partitioning

Subduction zone

Permeability

Nankai Trough

Sumatra

Kumano Basin

Geophysics

West Andaman Fault

Petrographic and Kinematic Investigation of the Volcaniclastic and Plutonic Rocks of the Northern Alisitos Arc, Baja California, Mexico

Tutak, Fatin

19 February 2008

The Alisitos arc segment forms part of the western zone of Jura-Cretaceous Peninsular Ranges batholith of Baja California. It extends south from the ancestral Agua Blanca Fault to the state boundary between Baja Norte and Sur. The study area is located within a fold and thrust belt intruded by a number of plutons that were emplaced during and after the deformational event. The northern end of the Alisitos arc is characterized by subvertical tight to isoclinal folds and high-angle reverse faults that define a northwest trending, southwest vergent fold and thrust belt. The aABF defines the northern limit to the Alisitos arc segment. In this study we present the results of a petrographic study of igneous rocks in order to determine the relative timing and the distribution of deformation within the northern Alisitos arc segment. The study includes samples of the mylonitic shear zone of the aABF, and plutonic samples from intrusions proximal to the aABF emplaced later during regional deformation. These samples were investigated in order to characterize the distribution of the subsolidus strain in grain scale and the sense of shear during later phases of deformation in the northern Alisitos arc. The results are presented and discussed based on the mineralogical and textural observations from the Balbuena pluton, the Piedra Rodada pluton, and volcaniclastics that were deformed within the aABF. The Balbuena pluton, emplaced at ~ 108 Ma after the surrounding country rocks had already been folded, exhibits little if any evidence for subsolidus deformation. In contrast, the Piedra Rodada pluton, emplaced at ~ 105 Ma just to the southwest of the aABF, exhibits a strong magmatic fabric overprinted by a moderate subsolidus fabric to the southwest that grades into a strong subsolidus fabric with proximity to the fault. Kinematics observed from lineation parallel-foliation normal sections exhibit consistent top-to-the southwest sense of shear.

Arc collision

Peninsular Ranges batholith

ancestral Agua Blanca fault

magmatic fabric

strain partitioning

American Studies

Arts and Humanities

Champ de déformation du socle paléozoïque des Pyrénées / Strainfield of the Paleozoic basement of the Pyrenees

Cochelin, Bryan

08 November 2016

Cette thèse présente une étude structurale qualitative et quantitative du socle paléozoïque des Pyrénées. Elle se base sur une étude de terrain et une compilation exhaustive et inédite des structures, harmonisées à l'échelle de toute la chaîne des Pyrénées. A partir de cette base de données, nous avons construit le champ de déformation régional varisque produit au Paléozoïque supérieur (310-295 Ma). On montre que lors du raccourcissement régional majeur, la déformation est partitionnée entre une croûte supérieure s'épaississant en régime transpressif et une croûte inférieure fluant latéralement. Une zone d' " attachement " a permis de maintenir la cohérence cinématique entre ces deux domaines aux comportements structuraux contrastés. Le fluage latéral au sein de la croûte inférieure permet l'emplacement de dômes extensifs dans ce contexte convergent. Le refroidissement progressif de la croûte favorise i) le couplage mécanique progressif entre ces deux domaines et ii) une localisation de la déformation dans des zones de cisaillement transpressives verticales d'échelle crustale. Bien que situées dans l'avant-pays de la chaîne varisque, les Pyrénées enregistrent une déformation typique d'une lithosphère anormalement chaude. Ce contexte thermique est l'expression d'une délamination progressive du manteau lithosphérique initiée dans les zones internes de l'orogène et qui a permis la fermeture de la syntaxe ibéro-armoricaine ainsi que l'échappement latéral de la croûte ductile pyrénéenne pris dans cette syntaxe. L'analyse quantitative du champ de déformation à partir d'outils géostatistiques montre que ce champ résulte d'une déformation assimilable à un cisaillement pur produit par un raccourcissement NS tandis que la composante dextre de la transpression se concentre aux bordures de plutons ou de dômes. Ainsi, la mise en place de ces objets structuraux gouverne l'hétérogénéité du champ de déformation. La cohérence du champ de déformation varisque met en question l'existence de nappes de socle lors de la construction du prisme orogénique pyrénéen à partir du Crétacé supérieur. En dehors de la bordure ouest et sud de la Zone Axiale, le socle n'est affecté que par des réactivations mineures, y compris dans les Pyrénées centrales où le chevauchement de Nogueres ne peut être enraciné. Ce chevauchement correspondrait plutôt à un décollement dans les séries paléozoïques supérieures, impliquant des quantités de raccourcissement moindres durant la collision pyrénéenne que celles calculées précédemment. / We present a qualitative and quantitative structural study of the Paleozoic basement of the Pyrenees. Based on new observations and an extensive compilation of structural data that were harmonized at the scale of the orogen, we built the regional-scale Variscan strain field. The main Variscan deformation was partitioned between transpressional thickening of the upper crust and the laterally flowing lower crust. An attachment zone acted to maintain the kinematic coherency between these two structural domains. Lateral flow of the lower crust accompanied emplacement of syn-convergence extensional domes. Regional cooling progressively increases the degree of mechanical coupling between the two structural levels and enhanced strain localization in steep regional transpressive shear zones. Though part of the foreland of the Variscan orogen the Pyrenees developed strain patterns typical of hot crusts/lithospheres. Such a hot thermal context is due to lithospheric mantle delamination that initiated beneath the hinterland of the orogen and allowed the Iberian-Armorican syntax to close and extrude the soft Pyrenean crust trapped in it. Geostatistical analysis of the strain field suggests that it results bulk pure shear deformation with a dextral transpressional component restricted to the boundaries of plutons and domes. Emplacement of such structural objects governed the degree of heterogeneity of the strain field. The coherency of the strain field argues against the stacking of large basement nappes in the Axial Zone of the Pyrenees during building of the orogenic prism since the Late Cretaceous. Only the southern and western parts of the Axial Zone are affected by "Alpine" thrusting and only minor local reactivation occurred elsewhere in the Axial Zone. Therefore, the Nogueres thrust cannot root into the Axial Zone but is a decollement within Late Paleozoic series. This suggests a lower amount of Alpine shortening in this part of the Pyrenees than previously estimated.

Pyrénées

Varisque

Syntaxe

Partitionnement de la déformation

Champ de déformation

Orogène chaud

Pyrenees

Variscan

Syntax

Strain partitioning

Strain field

Hot orogen

GPS Velocity Field In The Transition From Subduction To Collision Of The Eastern Sunda And Banda Arcs, Indonesia

Nugroho, Hendro

06 July 2005

Campaign GPS measurements during 2001-2003 in the transition between subduction and collision of the Banda arc reveal how strain is partitioned away from the trench and distributed to other parts of the arc-trench system. Genrich, et. al. (1996) conducted a GPS campaign (1992-1994) throughout the Eastern Sunda and Banda arcs that demonstrated partial accretion of the arc to the Australian plate. We reoccupied many of the sites from this earlier study and 7 additional stations, 3 of which are new benchmarks. Our study shortened many baselines and extended the observation epoch to ten years for many key stations. The resulting GPS velocity field for the active Banda arc-continent collision reveals: 1) several mostly rigid crustal blocks exist in the transition from subduction to collision, 2) relative to an Asian reference frame, most of these blocks move in the same direction as the Australian lower plate, but at different rates, 3) block boundaries may exist between the islands of Lombok and Komodo, Flores and Sumba, Savu and West Timor, and between Timor and Darwin, 4) the Timor Trough may account for at least 20 mm/yr of motion between Timor and Darwin, 5) a major transverse fault off the coast of West Timor separates the Savu/Flores/Sumba block from the Timor/Wetar Block and may account for variations in movement in Rote, 6) the Flores thrust moves the eastern Sunda arc north relative to Asia by decreasing amounts to the west, 7) the back-arc Wetar Thrust system takes up the majority of plate convergence between Australia and Asia, and 8) fault boundaries are not found between many blocks, such as various islands of the Sunda arc and forearc with different amounts of motion.

GPS

Geology

Tectonics

Geodynamics

Plate Boundary

Strain Partitioning

GPS Velocity Field

Collision

Eastern Indonesia

Indonesia

Banda Arc

Sunda Arc

Geology

Geologic Map and Structural Analysis of the Twin Rocks 7.5 Minute Quadrangle, Wayne County, Utah

Sorber, Samuel C.

23 June 2006

A new geologic map of the Twin Rocks 7.5 minute quadrangle primarily located within Capitol Reef National Park, south-central Utah, provides stratigraphic and structural detail not previously available. This map has also been instrumental in understanding the evolution and development of fluvial terraces associated with Sulfur Creek and the structural geology of the backlimb of the Miners Mountain uplift. Nine bedrock stratigraphic formations and eight types of Quaternary deposits were mapped throughout the quadrangle. Bedrock stratigraphy ranges in age from Permian to Jurassic. New details absent on previous geologic maps include members of the Chinle and Moenkopi Formations and the Jurassic Page Sandstone, a stratigraphic unit herein separated from the Navajo Sandstone. Terraces associated with Sulfur Creek record the central pathway of ancient streams rather than the lateral extent of the floodplain. Volcanic boulder-rich terrace deposits were likely created as stream channels were clogged with volcanic boulders and subsequently abandoned. The boulder-fill effectively armored the underlying softer bedrock. As the stream moved away from the abandoned, boulder-filled channel, it eroded and downcut into the adjacent softer mudstone bedrock, rather than eroding through the more resistant boulder alluvium. Thus, the abandoned boulder-filled channel becomes elevated relative to the stream. This inverted topography is preserved as elevated fluvial terrace deposits. This style of preservation of linear terraces developed over a broad area is in contrast to nearby terraces along the Fremont River which are preserved as "steps" cut into the resistant sandstones of the Glen Canyon Group along the Waterpocket Fold. These terraces have been used to identify changes in the location of Sulfur Creek through time. Kinematic analysis of structures in the backlimb of the uplift show a principle compressive stress orientation nearly perpendicular to the uplift axis and rotated 30° counter clockwise from the stress indicated by deformation bands measured in the forelimb. These data suggest that stress transmitted through the basement is partitioned and rotated in the backlimb, likely due to decoupling and differential slip in strata with low shear strength. Such decoupling would allow the stress to be rotated perpendicular to the resisting fold axis, rather than parallel to the far-field stress transmitted through the basement. Sandbox models produced in this study display boundary perpendicular structures similar to those measured in the backlimb of the Miners Mountain uplift.

Miners Mountain

geology

structural geology

kinematic analysis

kinematics

backlimb

strain partitioning

fluvial architecture

Capitol Reef

Capitol Reef geology

Sulfur Creek

clog and abandon

Geology