Global Distribution of Crustal Material Inferred by Seismology Nozomu Takeuchi (ERI, Univ of Tokyo) (1)Importance of Directional Measurements from geophysicists’

Slides:

Advertisements

Similar presentations

SPP 1257 Modelling of the Dynamic Earth from an Integrative Analysis of Potential Fields, Seismic Tomography and other Geophysical Data M. Kaban, A. Baranov.

Advertisements

Do Plumes Exist? Gillian R. Foulger Durham University GEOL 4061 Frontiers of Earth Science.

Subduction Factory: Its Role in the Evolution of the Solid Earth Y

Plate tectonics is the surface expression of mantle convection

The Myth of Whole Mantle Convection JUDGE FOR YOURSELF… Don L. Anderson.

Determining the nature of the LLSVP CIDER Workshop 2012 Maxim Ballmer, Jamie Barron, Rohan Kundargi, Curtis Williams, Rick Carlson, Jasper Konter, Jackie.

Society-relevant Arrays for Developing Countries: Opportunities and Challenges in South Africa Andy Nyblade Penn State University Workshop on Arrays in.

The Earth’s Structure Seismology and the Earth’s Deep Interior The Earth’s Structure from Travel Times Spherically symmetric structure: PREM - Crustal.

Earth’s Interior and Geophysical Properties Chapter 17.

Crustal Structure and Deformation in the Northern California Coast Ranges Gavin P. Hayes 1, Kevin P. Furlong 1, S. Schwartz 2, C. Hall 2, C. Ammon 1 1.

Lecture Outlines Physical Geology, 14/e Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display. Plummer, Carlson &

Mantle geochemistry: How geochemists see the deep Earth Don DePaolo/Stan Hart CIDER - KITP Summer School Lecture #1, July 2004.

Body and Surface Wave Seismic Tomography for Regional Geothermal Assessment of the Western Great Basin Glenn Biasi 1, Leiph Preston 2, and Ileana Tibuleac.

Seismological Crust Models for KamLAND Experiment Nozomu Takeuchi (University of Tokyo)

THE AUSTRALIAN NATIONAL UNIVERSITY Infrasound Technology Workshop, November 2007, Tokyo, Japan OPTIMUM ARRAY DESIGN FOR THE DETECTION OF DISTANT.

Predicting Global Perovskite to Post-Perovskite Phase Boundary Don Helmberger, Daoyuan Sun, Xiaodong Song, Steve Grand, Sidio Ni, and Mike Gurnis.

CRUSTAL SEISMOLOGY HELPS CONSTRAIN THE NATURE OF MANTLE MELTING ANOMALIES: THE GALAPAGOS VOLCANIC PROVINCE AGU Chapman Conference Ft. William, Scotland,

Chapter 17 Earth’s Interior and Geophysical Properties

Geology of the Lithosphere 2. Evidence for the Structure of the Crust & Upper Mantle What is the lithosphere and what is the structure of the lithosphere?

Determining the nature of the LLSVP Post-AGU CIDER Workshop 2012 Maxim Ballmer, Jamie Barron, Rohan Kundargi, Curtis Williams, Rick Carlson, Jasper Konter,

3D seismic imaging of the earth’s mantle Barbara Romanowicz Department of Earth and Planetary Science U.C. Berkeley.

The Four Candidate Earth Explorer Core Missions consultative Workshop October 1999, Granada, Spain, Revised by CCT GOCE S 23 The gravity.

Eclogite in the upper mantle? chemical heterogeneities andseismology Sebastian Rost DEEP 23. Februar 2005.

Application of empirical Green’s functions for the construction and validation of the GBCVM Morgan P. Moschetti and Michael H. Ritzwoller Center for Imaging.

RAPID SOURCE PARAMETER DETERMINATION AND EARTHQUAKE SOURCE PROCESS IN INDONESIA REGION Iman Suardi Seismology Course Indonesia Final Presentation of Master.

Travel-time versus Distance Curves

Section 1: Earth: A Unique Planet

Crust and upper mantle structure of Tien Shan Orogen and its surroundings by ambient noise tomography and earthquake tomography Yong Zheng a, Yingjie Yang.

TPW unplugged: Absolute plate motions and true polar wander in the absence of hotspot tracks, 320 — 130 Ma Bernhard Steinberger In collaboration with Trond.

Large Low Shear Velocity Provinces in the lowermost mantle, and Plume Generation Zones at their margins Bernhard Steinberger Collaborators: Kevin Burke.

Department of Geology & Geophysics

Terra Incognita (Again? Again! Again.) The zonal nature of the spectrum of lateral heterogeneity in the mantle as function of depth: five zones A very.

An array analysis of seismic surface waves

Geological data, geophysics and modelling of the mantle Yanick Ricard & Joerg Schmalzl " Geophysical observations; Introduction " Geochemical measurements.

Probing Earth’s deep interior using mantle discontinuities Arwen Deuss University of Cambridge, UK also: Jennifer Andrews, Kit Chambers, Simon Redfern,

Large-Scale Seismological Imaging of the Mariana Subduction Zone

Seismological observations Earth’s deep interior, and their geodynamical and mineral physical interpretation Arwen Deuss, Jennifer Andrews University of.

The Lithosphere There term lithosphere is in a variety of ways. The most general use is as: The lithosphere is the upper region of the crust and mantle.

10 Sept 2006SCEC/USGS Workshop: CA 3D Seismic Velocity Model The Role of Ambient Noise Tomography in Developing the California 3-D Seismic Velocity Model:

Water in the Mantle ? Can be stored: 1)Hydrous minerals - only stable shallow 2) Dissolved in normally anhydrous minerals 3)A hydrous silica-rich fluid.

17.1 Notes: Earth’s Mantle & Crust Continental crust Thickness: Continental crust is thicker (30-40Km) Age: older (up to 4.4 billion yrs old) Composition:

Geophysical observations of the 100 km region around KamLAND Tohru Watanabe Dept. of Earth Sciences University of Toyama (Japan)

Global seismic tomography and its CIDER applications Adam M. Dziewonski KITP, July 14, 2008.

Section 1: Earth: A Unique Planet

Seismological studies on mantle upwelling in NE Japan: Implications for the genesis of arc magmas Junichi Nakajima & Akira Hasegawa Research Center for.

Lower mantle upper mantle potential hotspot Based on illustration by Lidunka Vočadlo, University College London We propose this scenario: Layered Mantle.

1 LARGE IGNEOUS PROVINCES: Results of Delamination? Don L. Anderson Caltech.

There are Mantle Plumes originating from the CMB!.

The crust and the Earth’s interior

Constraints on the observation of mantle plumes using global seismology Arwen Deuss University of Cambridge, UK.

EXPLORING EARTH’S INTERIOR Chapter 14. Seismic rays are refracted away from the normal as they penetrate the earth, which causes them to bend, because.

Reference Earth model: heat-producing elements & geoneutrino flux *Yu Huang, Roberta Rudnick, and Bill McDonough Geology, U Maryland *Slava Chubakov, Fabio.

Geology 5640/6640 Introduction to Seismology 13 Apr 2015 © A.R. Lowry 2015 Read for Wed 15 Apr: S&W (§3.6) Last time: Ray-Tracing in a Spherical.

Perspectives for geoneutrinos after KamLAND results based on work with L. Carmignani, G. Fiorentini, T. Lasserre, M. Lissia, B. Ricci, S. Schoenert, R.

Geodynamics, Seismology & Plumes Gillian R. Foulger University of Durham, UK.

Seismogenic Characteristics and Seismic Structure of the Mariana Arc: Comparison with Central America Douglas A. Wiens, James Conder, Sara Pozgay, Mitchell.

Earth Layers Warm-Up #1 What’s inside the earth?

GOCE GRADIENT TENSOR CHARACTERIZATION OF THE COUPLED PARANÁ (SOUTH AMERICA) AND ETENDEKA (AFRICA) MAGMATIC PROVINCES Patrizia Mariani and Carla Braitenberg.

How can global seismic tomography help in studies of “Early Earth” Berkeley, December 10, 2011.

Seismic Waves Surface Waves Seismic Waves are shock waves given off by earthquakes. There are 2 types: 1. Body Waves originate from the focus (F) travel.

Lecture Outlines Physical Geology, 12/e Plummer & Carlson Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.

EXPLORING EARTH’S INTERIOR

Questions of the Day 2/28/2017 What is the difference between the epicenter of an earthquake and the focus of an earthquake?

Douglas A. Wiens & James Conder

Lithosphere Delamination and Small-Scale Convection Beneath California Imaged with High Resolution Rayleigh Wave Tomography Donald W. Forsyth and Yingjie.

Université Joseph Fourier Grenoble, France

Layers of the Earth.

Length scale of heterogeneity

Geophysics/Tectonics

Session 5: Higher level products (Internal)

Presentation transcript:

Global Distribution of Crustal Material Inferred by Seismology Nozomu Takeuchi (ERI, Univ of Tokyo) (1)Importance of Directional Measurements from geophysicists’ point of view (2) Improvements of Neutrino Flux Modeling in the seismological aspects

Parameters Required for Geo-neutrino Simulation = Parameters Resolved by Geo-neutrino Observation Earth’s Composition Earth’s Structure (compositions of crust & mantle) (distributions of crustal materials) Approach for Retrieving Earth’s Structure “Geophysical Decomposition” as a tool for interpretation of the observed data Importance of directional measurements

Prediction by High Pressure Experiments Ringwood & Irifune (1988) Density measurements in the upper mantle conditions Oceanic crusts can be trapped around the 660, but finally entrained into the lower mantle. Fate of the Oceanic Crusts (1)

Suggestion by Mantle Convection Simulation Nakagawa & Tackley (2005) Oceanic crusts can sink into the lowermost mantle, and accumulate at the bottom of upwelling regions. Fate of the Oceanic Crusts (2)

Fate of the Oceanic Crusts (3) Indirect Evidence by Seismic Tomography S velocity Bulk-sound velocity Masters et al. (2000) Chemical heterogeneities are suggested at the bottom of upwelling regions. possible accumulation of oceanic crusts

Example Classification of Geo-Neutrino Source continental crust oceanic crust (1) Surface Crust(2) Ambient Mantle (3) Crust in and around Subducting Slabs (4) Crust at the bottom of upwelling regions (LLSVPs) detector Can we decompose the observed flux into the above four components? We can utilize differences in incoming directions (directivities).

neutrino flux at the detector (r’) decay rate = x intensity factor determined by source distributions Formulation by Enomoto et al. (2007) Expected Directivity by the Surface Crust (1) Intensity Factor from j-th Directional Bin V

Expected Directivity by the Surface Crust (2) N S EW distance from the center bottoming radius azimuth direction from the center painted color

Difference in Expected Directivities +2%+1% N S EW km depth km depth Obayashi et al. (2009)

“Geophysical Decomposition” As an Interpretation Tool : incident angle : incident azimuth Coefficients can be determined by solving an inverse problem. reference model : larger mass fraction of depleted mantle? anomalies in bulk composition of the Earth? entrainments of continental crust? megalith on the 660? enriched elements in the lowermost mantle?

(short period data) (broadband data) Appropriate Choice of the Tomography Models Fukao et al. (2001)

broadband sensorshort period (high sensitivity) sensor Type of Seismic Data

Hz Hz Hz Hz 1-5 Hz 5-10 Hz Usefulness of Broadband Waveforms all frequencies broadband data Short period data

Comparison of Station Coverage 200 stations 20,000 stations short period data Broadband data homogeneous heterogeneous

500 km depth Masters et al. (2000) Data Type and Obtained Tomography Models Bijwaard et al. (1998) 500 km depth broadband data Short period data Models Obtained by Using : overall structures, structures beneath oceans broadband data short period data : detailed structures in subduction zones

Difficulties to Obtain Data-Based Crustal Models Too thin to resolve the global map. Sensitive frequency band is very “noisy”. Recent Progresses in Seismology Dense broadband arrays with sufficient resolving power. Use of “noise” to reveal crustal structures. Current global model (CRUST 2.0) is not fully data-based.

Importance of Data Based Science Kodaira et al. (2010) Crust 2.0 Crustal Structure by Exploration Data Improvements in Crust Models (1) (short period data)

Improvements in Crust Models (1) Zheng et al. (2011) Dense broadband arrays are beginning to reveal crustal maps Mapping by Broadband Data

Improvements in Crust Models (2) Future Challenge Broadband networks installed by ERI Use of broadband OBS data Data based crustal map in wide areas around Japan

OBS observations in (short period data) Validation of our crustal map Further refinements in the resolved regions

Challenge to Detection of Crusts in the Mantle (1) Station 1 Station 2 Station 3 coherent phase incoherent phase (scattered waves) coherent phase: sensitive to larger-scale structures incoherent phase: sensitive to smaller-scale structures Conventional tomography This Study

Challenge to Detection of Crusts in the Mantle (2) Required ResolutionCurrent Resolution Use of incoherent phases may fill the gap between supply and demand.

Summary of The Talk “Geophysical Decomposition” Importance of Directional Measurements Data Based Seismological Earth Models Use of “noise” in our broadband OBS Use of “incoherence” in seismic waveforms

Comparison of 3-D Seismic Velocity Models Predominance of larger lateral scale length of heterogeneities. S velocity structure at 2800 km depth Low velocity province beneath the Pacific and Africa.