Chi‐Yu King scite author profile

Terrestrial gases in groundwater and soil air have been extensively studied in recent years in seismically active areas, especially in USSR, China, Japan, and United States, in search of premonitory changes that might be useful for earthquake prediction. Concentrations of radon, helium, hydrogen, mercury, carbon dioxide, and several other volatiles have been found generally to be anomalously high along active faults, suggesting that the faults may be paths of least resistance for the terrestrial gases generated or stored in the earth to escape to the atmosphere. Temporal gas concentration changes with durations of a few hours to many months have been observed before many large earthquakes at a relatively small number of favorably situated stations at epicentral distances of up to several hundreds of kilometers. These “sensitive” stations are generally located along active faults, especially at intersections or bends of faults, or some other structurally weak zones, possibly because of tectonic strain concentration at such places. However, gas concentrations, especially those measured at or near the ground surface, may also be significantly affected by meteorological, hydrological, and other nontectonic changes in the environment. The nontectonically induced variations must be carefully eliminated or recognized in the search of true earthquake‐related anomalies.

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Forest-killing diffuse CO2 emission at Mammoth Mountain as a sign of magmatic unrest

Farrar

Sorey

Evans

et al. 1995

Nature

279

160

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Stress drop in earthquakes

1968

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A correlation is made between earthquake magnitude and parameters of fault trace on the basis of dislocation theory. For earthquakes with magnitudes M between 5.5 and 8.5, the correlation with fault length L and the maximum horizontal or vertical offset D (both in cm) is approximately log L D 2 = 2.24 M − 4.99. Combining this result with a magnitude-energy formula, it is found that the stress drop is dependent upon magnitude, with the fractional stress drop increasing with magnitude.

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Spatial radon anomalies on active faults in California

King

Evans

et al. 1996

Applied Geochemistry

182

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Chi‐Yu King

Gas geochemistry applied to earthquake prediction: An overview

Forest-killing diffuse CO2 emission at Mammoth Mountain as a sign of magmatic unrest

Stress drop in earthquakes

Spatial radon anomalies on active faults in California

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