Verfügbarkeit: Mechanics of earthquake faulting =

Mechanics of earthquake faulting =: Meccanica delle faglie sismogenetiche /

Gespeichert in:

Bibliographische Detailangaben
Körperschaft:	International School of Physics "Enrico Fermi" Varenna, Italy
Weitere Verfasser:	Bizzarri, A. (Andrea), 1802-1877 (HerausgeberIn), Das, S. (HerausgeberIn), Petri, A. (Alberto) (HerausgeberIn)
Format:	Elektronisch Tagungsbericht E-Book
Sprache:	English
Veröffentlicht:	Amsterdam : IOS Press, 2019.
Schriftenreihe:	Proceedings of the International School of Physics Enrico Fermi ; Course 202
Schlagworte:	Faults (Geology) > Congresses. Geodynamics > Congresses. Earthquakes > Congresses. Failles (Géologie) > Congrès. Géodynamique > Congrès. Tremblements de terre > Congrès. Earthquakes Faults (Geology) Geodynamics Congress proceedings (reports) Conference papers and proceedings Conference papers and proceedings. Actes de congrès.
Online-Zugang:	Volltext
Beschreibung:	1 online resource
ISBN:	9781614999799 1614999791

Internformat

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505	0		\|a Intro; Title Page; Contents; Preface; Course group shot; The mechanics of supershear earthquake ruptures; 1. Introduction; 2. Physical problem; 3. Numerical solutions; 4. Frequency content; 5. The penetration of the forbidden zone; 6. The shear-Mach and the Rayleigh-Mach cones; 7. The two transition styles: the direct transition and the mother-daughter mechanism; 8. Different ground motions; 9. Concluding remarks; Unusual large earthquakes on oceanic transform faults; 1. Introduction; 2. Pre-existing zones of weakness on the ocean floor
505	8		\|a 3. Re-activation of old transform faults: earthquakes with conjugate faulting in oceanic environments3.1. The 1989 great Macquarie Ridge earthquake reactivated a dormant conjugate fault; 3.2. The 1987-1992 and the January 23, 2018 Gulf of Alaska earthquake sequences; 3.3. The Mw7.8 18 June 2000 Wharton Basin earthquake: simultaneous rupture of conjugate faults in an oceanic setting; 3.4. The January 11 and 12, 2012 twin Sumatra earthquake (Mw8.6,8.2); 4. A great earthquake on a fossil fracture zone: the 2004 Tasman Sea earthquake; 4.1. Slip below the Moho during earthquakes
505	8		\|a 5. A great earthquake with the main fault plane normal to regional transform faults: the 1998 Mw8.1 Antarctic plate earthquake6. Conclusions; The evolution of fault slip rate prior to earthquake: The role of slow- and fast-slip modes; 1. Wide spectrum of slip rate from fast- to slow-slip; 1.1. Various types of slow earthquakes; 1.2. Complexity of slow earthquakes; 1.3. The early acceleration phase of slow-slip event; 2. Episodic unlocking of fault prior to large earthquake; 2.1. Foreshock sequence of the 2011 Mw 9.0 Tohoku-Oki, Japan earthquake
505	8		\|a 2.2. Foreshock sequence of the 2014 Mw 8.2 Iquique, Chile earthquake2.3. Triggering of the 2014 Mw 7.3 Papanoa, Mexico earthquake by a slow-slip event; 2.4. Foreshock sequence of the 2016 Mw 7.0 Kumamoto, Japan earthquake; 3. Discussion; 4. Conclusions; The spectrum of fault slip modes from elastodynamic rupture to slow earthquakes; 1. Introduction; 2. Mechanics of slow slip; 2.1. Friction laws for slow slip; 2.2. Laboratory observations of the full spectrum of slip modes from fast to slow; 2.3. Mechanics of laboratory slow earthquakes
505	8		\|a 3. Earthquake scaling laws for dynamic rupture and slow slip4. Conclusions; From foreshocks to mainshocks: mechanisms and implications for earthquake nucleation and rupture propagation; 1. Introduction; 2. Foreshocks and mainshocks; 2.1. 1934 and 1966 Parkfield, California, USA; 2.2. 1992 Joshua Tree, California, USA; 2.3. 1999 Izmit, Turkey; 2.4. 1999 Hector Mine, California, USA; 3. Mainshock initial rupture process; 3.1. 1989 Loma Prieta, California, USA; 3.2. 2004 Parkfield, California, USA; 4. Near source observations at SAFOD; 5. Discussion; 6. Conclusions
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655		7	\|a Actes de congrès. \|2 rvmgf
700	1		\|a Bizzarri, A. \|q (Andrea), \|d 1802-1877, \|e editor. \|1 https://id.oclc.org/worldcat/entity/E39PBJjtd3w3TCfxvjTMHykFKd \|0 http://id.loc.gov/authorities/names/n2010048050
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contents	Intro; Title Page; Contents; Preface; Course group shot; The mechanics of supershear earthquake ruptures; 1. Introduction; 2. Physical problem; 3. Numerical solutions; 4. Frequency content; 5. The penetration of the forbidden zone; 6. The shear-Mach and the Rayleigh-Mach cones; 7. The two transition styles: the direct transition and the mother-daughter mechanism; 8. Different ground motions; 9. Concluding remarks; Unusual large earthquakes on oceanic transform faults; 1. Introduction; 2. Pre-existing zones of weakness on the ocean floor 3. Re-activation of old transform faults: earthquakes with conjugate faulting in oceanic environments3.1. The 1989 great Macquarie Ridge earthquake reactivated a dormant conjugate fault; 3.2. The 1987-1992 and the January 23, 2018 Gulf of Alaska earthquake sequences; 3.3. The Mw7.8 18 June 2000 Wharton Basin earthquake: simultaneous rupture of conjugate faults in an oceanic setting; 3.4. The January 11 and 12, 2012 twin Sumatra earthquake (Mw8.6,8.2); 4. A great earthquake on a fossil fracture zone: the 2004 Tasman Sea earthquake; 4.1. Slip below the Moho during earthquakes 5. A great earthquake with the main fault plane normal to regional transform faults: the 1998 Mw8.1 Antarctic plate earthquake6. Conclusions; The evolution of fault slip rate prior to earthquake: The role of slow- and fast-slip modes; 1. Wide spectrum of slip rate from fast- to slow-slip; 1.1. Various types of slow earthquakes; 1.2. Complexity of slow earthquakes; 1.3. The early acceleration phase of slow-slip event; 2. Episodic unlocking of fault prior to large earthquake; 2.1. Foreshock sequence of the 2011 Mw 9.0 Tohoku-Oki, Japan earthquake 2.2. Foreshock sequence of the 2014 Mw 8.2 Iquique, Chile earthquake2.3. Triggering of the 2014 Mw 7.3 Papanoa, Mexico earthquake by a slow-slip event; 2.4. Foreshock sequence of the 2016 Mw 7.0 Kumamoto, Japan earthquake; 3. Discussion; 4. Conclusions; The spectrum of fault slip modes from elastodynamic rupture to slow earthquakes; 1. Introduction; 2. Mechanics of slow slip; 2.1. Friction laws for slow slip; 2.2. Laboratory observations of the full spectrum of slip modes from fast to slow; 2.3. Mechanics of laboratory slow earthquakes 3. Earthquake scaling laws for dynamic rupture and slow slip4. Conclusions; From foreshocks to mainshocks: mechanisms and implications for earthquake nucleation and rupture propagation; 1. Introduction; 2. Foreshocks and mainshocks; 2.1. 1934 and 1966 Parkfield, California, USA; 2.2. 1992 Joshua Tree, California, USA; 2.3. 1999 Izmit, Turkey; 2.4. 1999 Hector Mine, California, USA; 3. Mainshock initial rupture process; 3.1. 1989 Loma Prieta, California, USA; 3.2. 2004 Parkfield, California, USA; 4. Near source observations at SAFOD; 5. Discussion; 6. Conclusions
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series2	Proceedings of the International School of Physics Enrico Fermi ;
spelling	International School of Physics "Enrico Fermi" (202nd : 2018 : Varenna, Italy) Mechanics of earthquake faulting = Meccanica delle faglie sismogenetiche / edited by A. Bizzarri, S. Das and A. Petri. Meccanica delle faglie sismogenetiche Amsterdam : IOS Press, 2019. 1 online resource text txt rdacontent computer c rdamedia online resource cr rdacarrier Proceedings of the International School of Physics Enrico Fermi ; Course 202 Online resource; title from PDF title page (EBSCO, viewed August 5, 2019) Intro; Title Page; Contents; Preface; Course group shot; The mechanics of supershear earthquake ruptures; 1. Introduction; 2. Physical problem; 3. Numerical solutions; 4. Frequency content; 5. The penetration of the forbidden zone; 6. The shear-Mach and the Rayleigh-Mach cones; 7. The two transition styles: the direct transition and the mother-daughter mechanism; 8. Different ground motions; 9. Concluding remarks; Unusual large earthquakes on oceanic transform faults; 1. Introduction; 2. Pre-existing zones of weakness on the ocean floor 3. Re-activation of old transform faults: earthquakes with conjugate faulting in oceanic environments3.1. The 1989 great Macquarie Ridge earthquake reactivated a dormant conjugate fault; 3.2. The 1987-1992 and the January 23, 2018 Gulf of Alaska earthquake sequences; 3.3. The Mw7.8 18 June 2000 Wharton Basin earthquake: simultaneous rupture of conjugate faults in an oceanic setting; 3.4. The January 11 and 12, 2012 twin Sumatra earthquake (Mw8.6,8.2); 4. A great earthquake on a fossil fracture zone: the 2004 Tasman Sea earthquake; 4.1. Slip below the Moho during earthquakes 5. A great earthquake with the main fault plane normal to regional transform faults: the 1998 Mw8.1 Antarctic plate earthquake6. Conclusions; The evolution of fault slip rate prior to earthquake: The role of slow- and fast-slip modes; 1. Wide spectrum of slip rate from fast- to slow-slip; 1.1. Various types of slow earthquakes; 1.2. Complexity of slow earthquakes; 1.3. The early acceleration phase of slow-slip event; 2. Episodic unlocking of fault prior to large earthquake; 2.1. Foreshock sequence of the 2011 Mw 9.0 Tohoku-Oki, Japan earthquake 2.2. Foreshock sequence of the 2014 Mw 8.2 Iquique, Chile earthquake2.3. Triggering of the 2014 Mw 7.3 Papanoa, Mexico earthquake by a slow-slip event; 2.4. Foreshock sequence of the 2016 Mw 7.0 Kumamoto, Japan earthquake; 3. Discussion; 4. Conclusions; The spectrum of fault slip modes from elastodynamic rupture to slow earthquakes; 1. Introduction; 2. Mechanics of slow slip; 2.1. Friction laws for slow slip; 2.2. Laboratory observations of the full spectrum of slip modes from fast to slow; 2.3. Mechanics of laboratory slow earthquakes 3. Earthquake scaling laws for dynamic rupture and slow slip4. Conclusions; From foreshocks to mainshocks: mechanisms and implications for earthquake nucleation and rupture propagation; 1. Introduction; 2. Foreshocks and mainshocks; 2.1. 1934 and 1966 Parkfield, California, USA; 2.2. 1992 Joshua Tree, California, USA; 2.3. 1999 Izmit, Turkey; 2.4. 1999 Hector Mine, California, USA; 3. Mainshock initial rupture process; 3.1. 1989 Loma Prieta, California, USA; 3.2. 2004 Parkfield, California, USA; 4. Near source observations at SAFOD; 5. Discussion; 6. Conclusions Faults (Geology) Congresses. Geodynamics Congresses. Earthquakes Congresses. Failles (Géologie) Congrès. Géodynamique Congrès. Tremblements de terre Congrès. Earthquakes fast Faults (Geology) fast Geodynamics fast Congress https://id.nlm.nih.gov/mesh/D016423 proceedings (reports) aat Conference papers and proceedings fast Conference papers and proceedings. lcgft http://id.loc.gov/authorities/genreForms/gf2014026068 Actes de congrès. rvmgf Bizzarri, A. (Andrea), 1802-1877, editor. https://id.oclc.org/worldcat/entity/E39PBJjtd3w3TCfxvjTMHykFKd http://id.loc.gov/authorities/names/n2010048050 Das, S., editor. http://id.loc.gov/authorities/names/no2003007302 Petri, A. (Alberto), editor. https://id.oclc.org/worldcat/entity/E39PCjMqb86xgYKH6Tk3CprtXd http://id.loc.gov/authorities/names/nr95034785 has work: Mechanics of earthquake faulting (Text) https://id.oclc.org/worldcat/entity/E39PCFJRrm83Yg6g8MdYrXfFGb https://id.oclc.org/worldcat/ontology/hasWork International School of Physics "Enrico Fermi." Proceedings of the International School of Physics "Enrico Fermi" ; Course 202. http://id.loc.gov/authorities/names/n42019799 FWS01 ZDB-4-EBA FWS_PDA_EBA https://search.ebscohost.com/login.aspx?direct=true&scope=site&db=nlebk&AN=2217264 Volltext
spellingShingle	Mechanics of earthquake faulting = Meccanica delle faglie sismogenetiche / Intro; Title Page; Contents; Preface; Course group shot; The mechanics of supershear earthquake ruptures; 1. Introduction; 2. Physical problem; 3. Numerical solutions; 4. Frequency content; 5. The penetration of the forbidden zone; 6. The shear-Mach and the Rayleigh-Mach cones; 7. The two transition styles: the direct transition and the mother-daughter mechanism; 8. Different ground motions; 9. Concluding remarks; Unusual large earthquakes on oceanic transform faults; 1. Introduction; 2. Pre-existing zones of weakness on the ocean floor 3. Re-activation of old transform faults: earthquakes with conjugate faulting in oceanic environments3.1. The 1989 great Macquarie Ridge earthquake reactivated a dormant conjugate fault; 3.2. The 1987-1992 and the January 23, 2018 Gulf of Alaska earthquake sequences; 3.3. The Mw7.8 18 June 2000 Wharton Basin earthquake: simultaneous rupture of conjugate faults in an oceanic setting; 3.4. The January 11 and 12, 2012 twin Sumatra earthquake (Mw8.6,8.2); 4. A great earthquake on a fossil fracture zone: the 2004 Tasman Sea earthquake; 4.1. Slip below the Moho during earthquakes 5. A great earthquake with the main fault plane normal to regional transform faults: the 1998 Mw8.1 Antarctic plate earthquake6. Conclusions; The evolution of fault slip rate prior to earthquake: The role of slow- and fast-slip modes; 1. Wide spectrum of slip rate from fast- to slow-slip; 1.1. Various types of slow earthquakes; 1.2. Complexity of slow earthquakes; 1.3. The early acceleration phase of slow-slip event; 2. Episodic unlocking of fault prior to large earthquake; 2.1. Foreshock sequence of the 2011 Mw 9.0 Tohoku-Oki, Japan earthquake 2.2. Foreshock sequence of the 2014 Mw 8.2 Iquique, Chile earthquake2.3. Triggering of the 2014 Mw 7.3 Papanoa, Mexico earthquake by a slow-slip event; 2.4. Foreshock sequence of the 2016 Mw 7.0 Kumamoto, Japan earthquake; 3. Discussion; 4. Conclusions; The spectrum of fault slip modes from elastodynamic rupture to slow earthquakes; 1. Introduction; 2. Mechanics of slow slip; 2.1. Friction laws for slow slip; 2.2. Laboratory observations of the full spectrum of slip modes from fast to slow; 2.3. Mechanics of laboratory slow earthquakes 3. Earthquake scaling laws for dynamic rupture and slow slip4. Conclusions; From foreshocks to mainshocks: mechanisms and implications for earthquake nucleation and rupture propagation; 1. Introduction; 2. Foreshocks and mainshocks; 2.1. 1934 and 1966 Parkfield, California, USA; 2.2. 1992 Joshua Tree, California, USA; 2.3. 1999 Izmit, Turkey; 2.4. 1999 Hector Mine, California, USA; 3. Mainshock initial rupture process; 3.1. 1989 Loma Prieta, California, USA; 3.2. 2004 Parkfield, California, USA; 4. Near source observations at SAFOD; 5. Discussion; 6. Conclusions Faults (Geology) Congresses. Geodynamics Congresses. Earthquakes Congresses. Failles (Géologie) Congrès. Géodynamique Congrès. Tremblements de terre Congrès. Earthquakes fast Faults (Geology) fast Geodynamics fast
subject_GND	https://id.nlm.nih.gov/mesh/D016423 http://id.loc.gov/authorities/genreForms/gf2014026068
title	Mechanics of earthquake faulting = Meccanica delle faglie sismogenetiche /
title_alt	Meccanica delle faglie sismogenetiche
title_auth	Mechanics of earthquake faulting = Meccanica delle faglie sismogenetiche /
title_exact_search	Mechanics of earthquake faulting = Meccanica delle faglie sismogenetiche /
title_full	Mechanics of earthquake faulting = Meccanica delle faglie sismogenetiche / edited by A. Bizzarri, S. Das and A. Petri.
title_fullStr	Mechanics of earthquake faulting = Meccanica delle faglie sismogenetiche / edited by A. Bizzarri, S. Das and A. Petri.
title_full_unstemmed	Mechanics of earthquake faulting = Meccanica delle faglie sismogenetiche / edited by A. Bizzarri, S. Das and A. Petri.
title_short	Mechanics of earthquake faulting =
title_sort	mechanics of earthquake faulting meccanica delle faglie sismogenetiche
title_sub	Meccanica delle faglie sismogenetiche /
topic	Faults (Geology) Congresses. Geodynamics Congresses. Earthquakes Congresses. Failles (Géologie) Congrès. Géodynamique Congrès. Tremblements de terre Congrès. Earthquakes fast Faults (Geology) fast Geodynamics fast
topic_facet	Faults (Geology) Congresses. Geodynamics Congresses. Earthquakes Congresses. Failles (Géologie) Congrès. Géodynamique Congrès. Tremblements de terre Congrès. Earthquakes Faults (Geology) Geodynamics Congress proceedings (reports) Conference papers and proceedings Conference papers and proceedings. Actes de congrès.
url	https://search.ebscohost.com/login.aspx?direct=true&scope=site&db=nlebk&AN=2217264
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