Difference between revisions of "Rocks That Crackle and Sparkle and Glow: Strange Pre-Earthquake Phenomena"

Seismic waves are the most dramatic and most intensely studied  manifestations of earthquakes. However, we also know of non-seismic  phenomena, which precede large earthquakes. Some of them have been  reported for centuries, even millennia. The list is long and diverse: bulging of  the Earth's surface, changing well water levels, ground-hugging fog, low  frequency electromagnetic emission, earthquake lights from ridges and  mountain tops, magnetic field anomalies up to 0.5% of the Earth's dipole  field, temperature anomalies by several degrees over wide areas as seen in  satellite images, changes in the plasma density of the ionosphere, and strange  animal behavior. Because it seems nearly impossible to imagine that such  diverse phenomena could have a common physical cause, there is great  confusion and even greater controversy. This explains why reports on nonseismic  pre-earthquake phenomena are regarded with suspicion in the scientific  community. This may change with the recent discovery that igneous and  metamorphic rocks, which make up a major portion of the Earth's crust, contain  electric charge carriers, which have been overlooked in the past. These charge  carriers are defect electrons in the valence band, i.e., positive holes. Under  normal conditions they are dormant, but when they ??wake up'', the rocks begin  to sparkle and glow. This paper describes the physical and chemical nature of  these positive holes, how they are introduced into minerals and rocks, and how  they become activated. Evidence will be presented that, once the positive holes  are generated, currents propagate through the rocks leading to electromagnetic  emission, to positive surface potentials, to corona discharges, to positive ion  emission, and to mid-infrared radiation. These phenomena are expressions of  the same fundamental process: the ??awakening'' of dormant positive hole  charge carriers that turn rocks momentarily into p-type semiconductors.[[Category:Scientific Paper]]