Transcript Slide 1
Geometry and Kinematics: Plates (Chapter 10 in D & R) Today's lecture • 1) Building Blocks of the Earth: What's getting deformed? • 2) Geometry + Kinematics = Plate Tectonics • 3) Kinematic evolution Earth Structure: defined by seismic discontinuities; concentric shells of rock or liquid with contrasting chemical and physical properties Core: iron alloy Mantle: ultramafic Crust: mafic to felsic Note the figure that is to scale! Boundary between mantle and crust is called the Moho, short for Mohorovicic discontinuity Oceanic Crust - forms at mid-ocean ridges by partial melting of mantle - basaltic (mafic) in composition - igneous extrusion and intrusion - 5 to 10 km-thick - Oceanic crust is no older than ~200 Ma. Why?? Continental Crust - 5 to 10 times thicker than oceanic crust- 40 km avg. - This is a simplified sketch! Continental crust is very heterogeneous - Long and complex deformation history. Majority of continental crust formed during the Precambrian (before ~570 Ma) The oldest known rock is ~4 Ga! Why so much older than oceanic crust?? Contours of crustal thickness -Most of the continental surface lies within 1 km of sea level. -Most of ocean floor lies at depths ~4 km below sea level. Rheology (behavior during deformation) of the Earth Lithosphere: "lithos" = rock, implying strength. It exhibits a component of elastic strength over geological time scales. Includes crust + uppermost mantle! Varies in thickness. Moves as a plate- exceptions are orogens. Asthenosphere: Weak. It is solid, but behaves like a viscous fluid (convective flow) over geological time scales. Plates of the Earth A plate can include both oceanic and continental lithosphere oceanic vs. continental lithosphere can be distinguished with bathymetry (oceanic equivalent of topography)- WHY? How do we know that plates move? - Earthquakes localized along plate boundaries Most folks were convinced when spreading was demonstrated at mid-ocean ridges What is it? Geometry: Sketch Kinematic models 1) 2) Predictions? Tectonic significance? Transform faults: more evidence for plate motion Not observed! Observed! Oceanic transform faults: Spreading occurs perpendicular to the ridge axis and any curvature is taken up by transform faults. Different rates of spreading. GPS (Global Positioning System) Satellite-based geodesy: A new revolution in Earth Sciences! (more near end of semester!) InSAR Interferometric Synthetic Aperture Radar Continents also break- to form new oceans So far: Opening of oceans and creation of oceanic crust Is the Earth expanding? Spreading at mid-ocean ridges must be compensated by subduction Ocean-Continent convergent margins Continent-Continent convergent margins An example: The Indo-Asian Collision Digital elevation map (DEM) of the HimalayanTibetan orogen Warmer colors represent higher elevations Transform plate boundaries An example: San Andreas Velocity vector diagrams On a sphere, plate movement is described by a rotation at a specified angular velocity (w) around an imaginary axis (rotation pole, also known as Euler pole). Not related to N or S or magnetic poles! Oceanic plates move perpendicular to ridges and parallel to transform faults. Euler poles can be determined for oceanic plates by drawing lines perpendicular to transform faults (and fracture zones). Thought experiment: How much time did it take to produce the present-day area of oceanic crust? The surface area of the Earth is = 4pR2. With R = 6,378 km, area = 5.1x108 km2. 55% of Earth surface is underlain by oceanic crust (0.55 x 5.1x108 km2 = 2.8x108 km2). On average, crust is created at mid-ocean ridges at a rate of 2 to 3 cm/year. The length of ridges is 60,000 km. Thus, oceanic crust is created at a rate of 2 to 3 cm/year x 60,000 km = 1.2 to 1.8 km2/year. The time required to produce the present-day area of oceanic lithosphere is 2.8x108 km2/ (1.2 to 1.8 km2/year) = 155 to 230 Ma. What does this imply about the plate configuration of Earth ~200 m.y.a? Pangea supercontinent and Tethys Ocean http://www.scotese.com/earth.htm Concept of the supercontinent cycle RodiniaPangea mantle convection Wilson cycle: opening and closing of oceans at roughly similar positions DEM of Aleutian trench Extraterrestrial plate tectonics? DEM of Artemis Corona on Venus; same scale as above Plates are rigid! Kinematics described in terms of translations and rotations Next: Geometry and Kinematics of Deformation Starting with Fractures (Read D&R, p. 38-50; 204-226) Important terminology/concepts - Crust: continental vs. oceanic - Mantle - Moho - Rheology: Lithosphere vs. Asthenosphere - Earth's plates - Bathymetry - Evidence for plate motion? - Mid-oceanic ridges - Transform faults and fracture zones - Ocean-continent convergent margins - trench, accretionary wedge, forearc - Continent-continent convergent margins - Plate kinematics - Euler Pole - Velocity vector diagrams - Kinematic history - Supercontinent cycle