GE177b- Objectives Introduce a variety of techniques to describe ‘quantitatively’ deformation of the lithosphere and fault slip history. Introduce.

Slides:

Advertisements

Similar presentations

(Introduction to) Earthquake Energy Balance

Advertisements

The Community Geodetic Model (CGM): What is it and how does it relate to studies of lithospheric rheology? Jessica Murray, David Sandwell, and Rowena Lohman.

Subduction Zone Observatory Big Geodynamics-Related Science Questions Magali Billen Department of Earth & Planetary Sciences UC Davis Collaborators & Students:

A Kinematic Fault Network Model for Crustal Deformation (including seismicity of optimal locking depth, shallow surface creep and geological constraints)

Subduuction Zone Observatory: Faulting and Deformation Jeff Freymueller Geophysical Institute and Dept. of Geology and Geophysics University of Alaska.

Scaling of viscous shear zones with depth dependent viscosity and power law stress strain-rate dependence James Moore and Barry Parsons.

Evolution of Wedge Width Dampens the Response of Rock Uplift Rate to a Change In Fa (from linear to ~1/2 power) A Step-function change in U Is nearly impossible.

3-D Finite Element Modeling of the Rise and Fall of the Himalayan-Tibetan Plateau Mian Liu and Youqing Yang Dept. of Geological Sciences, University of.

Volcano Deformation Constraints on continued episodic inflation at Long Valley Caldera, based on seismic and geodetic observations (Feng et al.) The 1974.

Active Folding within the L.A. Basin with a focus on: Argus et al. (2005), Interseismic strain accumulation and anthropogenic motion in metropolitan Los.

Appendix: On the use of the ‘Elastic Dislocations’

Geodesy, Seismicity, Neotectonics Shimon Wdowinski Rowena Lohman Cecilio Rebollar Gina Schmalzle Kim Outerbridge Jeff McGuire Gordon Seitz Pat Williams.

Strength of the lithosphere: Constraints imposed by laboratory experiments David Kohlstedt Brian Evans Stephen Mackwell.

Numerical simulation of seismic cycles at a subduction zone with a laboratory-derived friction law Naoyuki Kato (1), Kazuro Hirahara (2), and Mikio Iizuka.

Spatial and Temporal Patterns of Deformation Through the Seismic Cycle Jeff Freymueller University of Alaska Fairbanks.

GreatBreak: Grand Challenges in Geodynamics. Characteristics of a Desirable Geodynamic Model Ties together observational constraints on current state.

Observing an Earthquake Cycle Within a Decade

Geodetic monitoring of subduction zones Some idea of the kinematics of the subduction interface can be inferred from surface deformation measured from.

Physically-based Kinematic Model: from sandbox experiment Nina Lin Ge 277, Nov Readings: Bernard et al. (2007) Kinematics of fault-related folding.

CIDER 2011 Research Discussion 1 MULTIDISCIPLINARY.

(Chapter 10 in D & R) Geometry and Kinematics: Plates.

Ge 277- ‘From rock mechanics to seismotectonics’ Objective of seminar Review major results form rock mechanics laboratory experiments and discuss how these.

Roland Burgmann and Georg Dresen

The Spectrum of Fault Slip Behaviors 18 Sep. 2013, C. Marone, Geosc500 Mechanics of Earthquakes and Faulting Stick-slip dynamics and Instability. Introduction.

Paleoseismic and Geologic Data for Earthquake Simulations Lisa B. Grant and Miryha M. Gould.

DGF – Santiago, Chile – Geodesy and Geodynamics By Christophe Vigny National Center for scientific Research (CNRS) & Ecole Normale Supérieure (ENS)

Quantitative Structural Analysis: Where does it start? David D. Pollard, Stanford University Stephen J. Martel, Univ. of Hawaii Structural Geology and.

Assessment Report Department of the Earth Sciences School of Science and Mathematics James Zollweg Chair + Assessment Coordinator.

SISMA Seismic Information System for Monitoring and Alert Galileian Plus Dipartimento di Scienze della Terra, Università di Milano, Italy Politecnico di.

Grand Challenges, Leading Edge Ideas, and Frontiers in Tectonics K.V. Hodges School of Earth and Space Exploration Arizona State University.

IV. The seismic cycle Taiwan Lab.

Geology Introduction to Strike-Slip Faults.

Continental Faults at Depth: the roots of the debate Ge Summary: How continents deform is a much debated question. Whether surface strain is localized.

Intraplate Seismicity Finite element modeling. Introduction Spatial patterns (Fig. 1) –Randomly scattered (Australia) –Isolated “seismic zones” (CEUS)

Interseismic deformation with aseismic stress-dependent fault slip Eric A Hetland, Mark Simons, Ravi Kanda, Sue Owen TO brown-bag – 03 April 2007 a very.

DYNAMIC DISPLACEMENTS OF THE SEA BOTTOM DUE TO SUBDUCTION ZONE EARTHQUAKES A.I. IVASHCHENKO Institute of Oceanology, RAS, Moscow L.I. LOBKOVSKY Institute.

March 2006 WGCEP Workshop Ruth A. Harris U.S. Geological Survey.

CRUSTAL DEFORMATION BREAKOUT Key Scientific Questions  How do magmatic systems evolve and how can we improve eruption forecasting?  How can we quantify.

Massimo Cocco INGV Rome INGV The First EarthScope Institute on the Spectrum of Fault Slip Behaviors October 11-14, 2010, Portland, Oregon.

Inherent Mechanism Determining Scaling Properties of Fault Constitutive Laws Mitsuhiro Matsu’ura Department of Earth and Planetary Science Graduate School.

Using GPS and InSAR to study tectonics, deformation, and earthquakes GPS displacements, velocities (and transients) InSAR displacements.

GEO 5/6690 Geodynamics 15 Oct 2014 © A.R. Lowry 2014 Read for Wed 22 Oct: T&S Last Time: RHEOLOGY Dislocation creep is sensitive to: Temperature.

Yuehua Zeng & Wayne Thatcher U. S. Geological Survey

Modelling Postseismic Deformation: Examples from Manyi, Tibet and L’Aquila, Italy Marcus Bell COMET Student Meeting 2010 Supervisors: B. Parsons and P.

The influence of the geometry of the San Andreas fault system on earthquakes in California Qingsong Li and Mian Liu Geological Sciences, 101 Geol. Bldg.,

I. Introduction to Structural Geology -Ge106- Instructor: Jean-Philippe Avouac (301NM; caltech.edu) Teaching Assistant: Erika Swanson

Constant stress experiment ductile elastic Constant stress (strain varies) Constant strain (stress varies)

Geodetic Deformation, Seismicity and Fault Friction Ge Sensitivity of seismicity to stress perturbations, implications for earthquakes nucleation.

Designing and Assessing Mini-lessons Ellen Iverson and Kristin O’Connell SERC at Carleton College September 2013 Workshop.

Earthquake Machine Mechanical Modeling to Increase Student Understanding of Complex Earth Systems Most of you are probably covering strike-slip faults.

Earthquakes and crustal Deformation - Objectives of class- Introduce a variety of techniques to describe ‘quantitatively’ deformation of the lithosphere.

EART 118 Seismotectonics MWF D250 9:30-10:40 am; Th D250 2:00-4:00 pm Prof.: Thorne Lay, C382 E&MS, Office Hours 11:00-12:00 MWF TA: Lingling Ye, Office.

GEO 5/6690 Geodynamics 24 Oct 2014 © A.R. Lowry 2014 Read for Wed 29 Oct: T&S Last Time: Brittle-field rheology The “Seismogenic Zone” is observed.

Introduction to the modelling of GPS results GPS provides Surface crustal velocities in a global reference frame, or with respect to a block, realized.

III. Strain and Stress Strain Stress Rheology A rheological law relates strain to stress and time.

Conceptual model on how to relate geological structures to co-seismic deformation King et al., JGR 1988 and Stein et al., JGR 1988 Seminar 1, October,

The Time-Predictable Recurrence Model The original models (Shimazaki & Nakata 1980) Complications and pitfalls (Thatcher 1984) Modern examples Relevance.

2002/05/07ACES Workshop Spatio-temporal slip distribution around the Japanese Islands deduced from Geodetic Data Takeshi Sagiya Geographical Survey Institute.

From Subduction to Collision : Taiwan from Angelier.

GeoFEM Kinematic Earthquake Cycle Modeling in the Japanese Islands Hirahara, K. (1), H. Suito (1), M. Hyodo (1) M. Iizuka (2) and H. Okuda (3) (1) Nagoya.

SPICE Research and Training Workshop III, July 22-28, Kinsale, Ireland DEM Simulation of dynamic Slip on a rough Fault Steffen Abe, Ivan.

II. Methods in Morphotectonics 1- Identification of Active Faults 2 Determination of slip-rate on strike-slip faults 3- Determination of fold growth and.

Constructing Activities Based on “Grand Challenges” Michael Wysession Washington University St. Louis, MO.

Velocities in ITRF – not appropriate for interpretation

Coupling at subduction zones Background reading: Pacheco, Sykes, Scholz (1993) Hyndman, Yamano, Oleskevich (1997) Carl Tape November 9, 2007 Thanks.

Earthquakes and crustal Deformation - Objectives of class-

Geodesy & Crustal Deformation

On the relation between Geodetic strain, Seismicity and fault frictional properties Nepal Sumatra Taiwan.

Ruth Neilan and Zheng-Kang Shen

Stable North America Reference Frame Working Group

Presentation transcript:

GE177b- Objectives Introduce a variety of techniques to describe ‘quantitatively’ deformation of the lithosphere and fault slip history. Introduce the basic mechanisms governing lithospheric deformation and conceptual models of the ‘seismic cycle’. Expose the students to a number of modeling tools commonly used in tectonics studies. I will try to lead you to think not only in terms of kinematics but also in terms of stress and rheology.

GE177b- Objectives At the end of the class you should be able -to carry on a active tectonic studies on your own using satellite images, DEM and able to plan a field survey. (Observe, Measure) - to analyze the results based of general concepts in tectonics and simple modeling tools (Interpret, Model) -to read and assess the current literature in active tectonics (Critical Reading)

GE177b- Grading 75% : Labs and Homeworks 25% : Participation to class

I. Introduction to Active Tectonics Objectives: – Introduce some outstanding issues in continental tectonic and seismotectonics. – Give an overview of the tools and concepts that will be addressed over the course of the class.

Plate motion of India relative to Eurasia (Copley et al, 2010)

Topography and seismicity suggests continental deformation is distributed

Velocities relative to Eurasia, Bettinelli et al (2006), Calais et al (2006), Simons et al (2007), Gan et al (2007), Chlieh et al (2010) Where are the active faults?

Satellite Mosaic and topography of Central Asia The response is in the landscape

(Tapponnier and Molnar, 1975)

Some outstanding issues in Active Tectonics Is continental deformation distributed or localized? (Is it appropriate to model continental lithosphere as a viscously deforming medium or an elasto-plastic medium? ) What is the influence of surface processes on tectonics?

Isostatic response to valley deepening might lead to peak uplift (England and Molnar, 1990)… Coupling between Tectonics, Erosion and Climate

Some outstanding issues in Active Tectonics Is continental deformation distributed or localized? (Is it appropriate to model continental lithosphere as a viscously deforming medium or an elasto-plastic medium? ) What is the influence of surface processes on tectonics? Is continental deformation a ‘side effect’ of plate tectonics or does it play an important role in global dynamics?

Plate motion of India relative to Eurasia (Copley et al, 2010)

Some outstanding issues in Active Tectonics Is continental deformation distributed or localized? (Is it appropriate to model continental lithosphere as a viscously deforming medium or an elasto-plastic medium? ) What is the influence of surface processes on tectonics? Is continental deformation a ‘side effect’ of plate tectonics or does it play an important role in global dynamics? What factors determine the relative proportion of seismic and aseismic deformation? (What determines whether a fault patch creeps steadily or produce seismic slip?) How regular/irregular is the ‘seismic cycle’ on a fault?

The ‘Seismic Cycle’ jargon Motion on faults is generally ‘stick-slip’. Some fault creeps aseismically but most produce recurring large earthquakes. Conventionnally we distinguish –Co-seismic deformation –Interseismic deformation –Post-seismic deformation –Secular deformation (long term averaged)

Secular deformation results only from slip on the thrust fault

Secular deformation might result from slip on the thrust fault and distributed deformation within the orogenic wedge

Interseismic deformation might be non stationnary

Reality might lool more like this…

Some outstanding issues in Active Tectonics Is continental deformation distributed or localized? (Is it appropriate to model continental lithosphere as a viscously deforming medium or an elasto-plastic medium? ) What is the influence of surface processes on tectonics? Is continental deformation a ‘side effect’ of plate tectonics or does it play an important role in global dynamics? What factors determine the relative proportion of seismic and aseismic deformation? (What determines whether a fault patch creeps steadily or produce seismic slip?) How regular/irregular is the ‘seismic cycle’ on a fault? Are some aspects of the ‘seismic cycle’ predictable? (rupture extent, magnitude, time, slip, …) How do faults interact? Does it lead to some systematic pattern? What is the rheology governing fault bevavior? ….

What information/observations do we need to make progress on these issues? Good kinematic description of crustal deformation and fault behavior : –active faults –long-term slip rates, –Information about mode of slip (paleoseismo, paleogeodesy) –coseismic slip models –interseismic strain and interseismic coupling models… Constraints on stresses…

GE177b-Outline I. Introduction to Active Tectonics II. Methods in Morphotectonics III. Determining the time evolution of fault slip IV. The ‘seismic cycle’ Appendices: - A: Geochronologic methods in Active Tectonics - B: Geodetic and Remote Sensing techniques - C: Elastic Dislocation Modeling