Earthquake magnitude and source parameters

Abstract

abstract Previous attempts to find empirical linear relationships between the magnitude, M, of an earthquake and the logarithm of one or more of the source parameters (length L, width W, displacement D) are reviewed. The fault parameters associated with a set of 27 earthquakes with strike-slip movement in the magnitude range 3.4 to 8.3 are used to test these empirical relationships. It is found that there is no linear relationship between M and log L or log W that is valid over the whole magnitude range. However, a rather good linear relationship is found between M and log D. Using all of the present data, this relationship is M = 1.32 log ⁡ D + 4.27 If only large magnitude events are used, this becomes M = 1.04 log ⁡ D + 4.96 Some improvement in determinations of the displacement D for low magnitude events is necessary in order to distinguish between these two formulas. It is surmised that the second may be closer to the truth. The consequences of such a relationship are discussed.

Keywords

Magnitude (astronomy)LogarithmEarthquake magnitudeDisplacement (psychology)MathematicsRange (aeronautics)Linear relationshipFault (geology)StatisticsGeodesyGeologySeismologyPhysicsGeometryMathematical analysisEngineering

Affiliated Institutions

Brown University US

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Publication Info

Year: 1969
Type: article
Volume: 59
Issue: 5
Pages: 1969-1982
Citations: 85
Access: Closed

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APA Style

                            
                                    Michael A. Chinnery
                                
                            (1969). 
                            Earthquake magnitude and source parameters. 
                            Bulletin of the Seismological Society of America
                            , 59
                            (5)
                            , 1969-1982.
                            https://doi.org/10.1785/bssa0590051969

Identifiers

DOI: 10.1785/bssa0590051969