about
Geologic carbon storage is unlikely to trigger large earthquakes and reactivate faults through which CO2 could leakFault lubrication during earthquakesLithospheric flexure and thermal anomaliesFrictional heating, fluid pressure, and the resistance to fault motionVariability in the power-law distributions of rupture eventsDiscriminating between natural and anthropogenic earthquakes: insights from the Emilia Romagna (Italy) 2012 seismic sequence.Anthropogenic triggering of large earthquakes.Volcanic passive margins: another way to break up continents.Compression-extension transition of continental crust in a subduction zone: A parametric numerical modeling study with implications on Mesozoic-Cenozoic tectonic evolution of the Cathaysia Block.Near-trench slip potential of megaquakes evaluated from fault properties and conditionsImpoundment of the Zipingpu reservoir and triggering of the 2008 Mw 7.9 Wenchuan earthquake, ChinaExtreme hydrothermal conditions at an active plate-bounding fault.Continental crust formation on early Earth controlled by intrusive magmatism.Numerical Studies on the Failure Process of Heterogeneous Brittle Rocks or Rock-Like Materials under Uniaxial CompressionStress drops of induced and tectonic earthquakes in the central United States are indistinguishable.The Use of Empirical Methods for Testing Granular Materials in Analogue Modelling.On the effective stress law for rock-on-rock frictional sliding, and fault slip triggered by means of fluid injection.Scale dependence of rock friction at high work rate.Three-dimensional deformation caused by the Bam, Iran, earthquake and the origin of shallow slip deficit.'Melt welt' mechanism of extreme weakening of gabbro at seismic slip rates.Low coseismic friction on the Tohoku-Oki fault determined from temperature measurements.Fission and reconfiguration of bilobate comets as revealed by 67P/Churyumov-Gerasimenko.GEOPHYSICS. Weak subduction makes great quakes.Depth dependent stress revealed by aftershocks.Heating, weakening and shear localization in earthquake rupture.April 2012 intra-oceanic seismicity off Sumatra boosted by the Banda-Aceh megathrust.Linking scales in sea ice mechanics.Rotary shear experiments under X-ray micro-computed tomography.Quantifying Interparticle Forces and Heterogeneity in 3D Granular Materials.Evidence for fault weakness and fluid flow within an active low-angle normal fault.Stress transfer by the 1988-1989M= 5.3 and 5.4 Lake Elsman foreshocks to the Loma Prieta fault: Unclamping at the site of peak mainshock slipMechanics of fold-and-thrust belts and accretionary wedges: Cohesive Coulomb TheoryDiapiric ascent of magmas through power law crust and mantleA renormalization group approach to the stick-slip behavior of faultsLithospheric strength and intraplate seismicity in the New Madrid seismic zoneInduced seismicity associated with fluid injection into a deep well in Youngstown, OhioTectonic evolution of a continental collision zone: A thermomechanical numerical modelNormal faulting sequence in the Pumqu-Xainza Rift constrained by InSAR and teleseismic body-wave seismologyHow pore fluid pressurization influences crack tip processes during dynamic ruptureStrength of stick-slip and creeping subduction megathrusts from heat flow observations
P2860
Q28647377-798789E1-61D7-4BD2-915D-BB5069092F8FQ29013023-8B250971-AA7E-4DFC-A936-61FE2985851DQ29037735-DF6F3564-020B-4FB5-A3D7-CF32ED4AD859Q29540773-3B693D55-BB0E-47C3-8A57-71CCC623256FQ30049090-175F2FA2-EE79-41CC-A6B6-EC220402AE72Q33670775-688AC171-0285-4740-8686-97D5B913C0E0Q34085875-750051A5-24F6-40D7-B7CE-024E99F0DB6AQ36129185-3556DF4C-6916-4B95-A285-08B3786C0D6BQ36275212-A3295847-B77B-48AE-9459-8B68B4D25EC4Q37019420-6EA71A4A-319A-49D1-972D-A613E259F48DQ37343198-C5ACDA83-08FF-4490-87D0-77EAE7B31000Q38780637-DF2FE138-45C3-49B5-A365-64606C583CE5Q38797775-2F8176C0-16AE-4795-987E-6B30B77B0FF7Q40992373-C1BEE160-7B0B-4D5C-A624-B85C313B4F91Q41212271-F0BAC6B7-AE9D-48BD-AA23-40088593204AQ41365525-98351444-F6BA-45F3-B12B-E2AA15029B3CQ41589192-FF43FB54-80B9-4279-B646-9068461F809EQ41950017-CC8BA34D-A18F-4422-8033-871DBDEE1433Q45048150-277D2C3B-623C-422A-A976-8F1C6F0E697DQ46036853-ACB7E2E1-ABDF-4CC3-8E05-26DF7EC18C2EQ46157668-88D29C49-AD04-444C-AF3C-20DEFD9F3D1FQ46843796-96AD5AD3-3E61-42E6-9C7A-6EE31959C862Q46972087-B024437F-02CE-49A2-A617-0DA9A913C189Q47145825-557701D6-468C-48AE-B464-FB94A7AFAB35Q47291651-96B02176-6CFD-4E4C-BC02-5C635EAD11EDQ47828066-F4017410-DE31-4ECF-9B42-BF581D5D30AAQ48029893-454C8E40-EA95-4BDA-932F-671E48E6FD65Q48048400-A0C91835-93E0-450E-8E5A-B94A1013649EQ51168587-44D15486-C49A-46F4-872A-DD2272BC5939Q52058945-6CF892DF-3F3A-481E-AD0F-786FF9A49E2AQ56020292-093CCEB3-010A-491F-B99C-3BF8DE13F5A0Q56048510-DFD17A2A-258F-437C-8C04-49155C6430C4Q56048977-9EA22250-A7BF-42AB-96D2-C96977C78AD6Q56428954-4CF6FD3A-13D8-401E-A852-2225B4808170Q56430575-8D3B5E28-C982-48EF-9AFF-E718D343B01FQ56453352-D826E500-7E9D-4B57-8BA4-771F5C289071Q56675342-47078C3D-5CD7-4485-8694-B15509CE708AQ56838886-05166267-F41D-4312-9F79-D5F9F062243DQ56997232-0470FBDB-B8A8-4599-A297-46A6FC3ED5B4Q57100632-C9139428-BF4D-4457-804E-ADC6D41C9650
P2860
description
im Januar 1978 veröffentlichter wissenschaftlicher Artikel
@de
wetenschappelijk artikel
@nl
наукова стаття, опублікована в 1978
@uk
name
Friction of rocks
@en
Friction of rocks
@nl
type
label
Friction of rocks
@en
Friction of rocks
@nl
prefLabel
Friction of rocks
@en
Friction of rocks
@nl
P356
P1476
Friction of rocks
@en
P2093
J. Byerlee
P2888
P304
P356
10.1007/BF00876528
P577
1978-01-01T00:00:00Z
P6179
1044059657