Abstract. We present a different view of secular variation of the Earth's magnetic field, through the variations in the threshold rigidity known as the variation rate of geomagnetic cutoff rigidity (VRc). As the geomagnetic cutoff rigidity (Rc) lets us differentiate between charged particle trajectories arriving at the Earth and the Earth's magnetic field, we used the VRc to look for internal variations in the latter, close to the 70 • south meridian. Due to the fact that the empirical data of total magnetic field BF and vertical magnetic field Bz obtained at Putre (OP) and Los Cerrillos (OLC) stations are consistent with the displacement of the South Atlantic magnetic anomaly (SAMA), we detected that the VRc does not fully correlate to SAMA in central Chile. Besides, the lower section of VRc seems to correlate perfectly with important geological features, like the flat slab in the active Chilean convergent margin. Based on this, we next focused our attention on the empirical variations of the vertical component of the magnetic field Bz, recorded in OP prior to the Maule earthquake in 2010, which occurred in the middle of the Chilean flat slab. We found a jump in Bz values and main frequencies from 3.510 to 5.860 µHz, in the second derivative of Bz, which corresponds to similar magnetic behavior found by other research groups, but at lower frequency ranges. Then, we extended this analysis to other relevant subduction seismic events, like Sumatra in 2004 and Tohoku in 2011, using data from the Guam station. Similar records and the main frequencies before each event were found. Thus, these results seem to show that magnetic anomalies recorded on different timescales, as VRc (decades) and Bz (days), may correlate with some geological events, as the lithosphereatmosphere-ionosphere coupling (LAIC).
[1] We examine the AE index variability while 12 corotating fast solar wind streams pass the Earth during the ascending phase of the ongoing solar activity cycle. We apply the Discrete Fourier Transform analysis to the associated interplanetary magnetic field (B) data and AE time series with $1 min resolution. Results show noticeable periodicities in the 1-10 hour range. Moreover, the B and AE periodicities in each event are well correlated. For this reason a direct relationship between interplanetary Alfvénic waves and AE oscillations is proposed while those streams pass the Earth.Citation: Diego, P., M. Storini, M. Parisi, and E. G. Cordaro (2005), AE index variability during corotating fast solar wind streams,
Abstract. This publication highlights theoretical work that could explain four different empirical observations indicating a direct relationship between magnetic fields and earthquakes, which would allow the description of a causal mechanism prior to and during the occurrence of earthquakes. These theoretical calculations seek to elucidate the role of the magnetic field in different aspects of solid earth dynamics, with an interest in the study and comprehension of the physics that could generate earthquakes accompanied by simultaneous magnetic signals within the lithosphere. The Motion of Charged Edge Dislocations (MCD) model and its correlation with the magnetic field have been used in order to include the generation of electric currents. The electric currents resulting from stress variation in the lithosphere helps us to analyze the lithosphere as a critical system, before and after the occurrence of earthquakes, by using the concept of earthquake entropy. Where it is found that the non-existence of seismic and magnetic precursors could be interpreted as a violation to the second law of thermodynamics. In addition, the Seismic Moment and the Moment Magnitude of some great earthquakes are quite accurately calculated using the co-seismic magnetic field. The distance-dependent co-seismic magnetic field has been theorized for some of the largest recorded earthquakes. Finally, the frequency of oscillation of the Earth's magnetic field that could be associated with earthquakes is calculated and being consistent to the ultra-low frequency (ULF) signals that some authors propose in the so-called "LAIC Effect" (lithosphere-atmosphere-ionosphere coupling).
Abstract. This publication highlights theoretical work that could explain five
different empirical observations indicating a direct relationship between
magnetic fields and earthquakes, which would allow the description of a
causal mechanism prior to and during the occurrence of earthquakes. These
theoretical calculations seek to elucidate the role of the magnetic field in
different aspects of solid Earth dynamics, with an interest in the study and
comprehension of the physics that could generate earthquakes accompanied by
simultaneous magnetic signals within the lithosphere. The motion of charged
edge dislocations (MCD) model and its correlation with the magnetic field
have been used in order to include the generation of electric currents. The
electric currents resulting from stress variation in the lithosphere help
us to analyze the lithosphere as a critical system, before and after the
occurrence of earthquakes, by using the concept of earthquake entropy. Where
it is found that the nonexistence of seismic and magnetic precursors could
be interpreted as a violation of the second law of thermodynamics. In
addition, the seismic moment and the moment magnitude of some great
earthquakes are quite accurately calculated using the coseismic magnetic
field. The distance-dependent coseismic magnetic field has been theorized
for some of the largest recorded earthquakes. The frequency of oscillation
of the Earth's magnetic field that could be associated with earthquakes is
calculated and is consistent with the ultra-low-frequency (ULF) signals
that some authors propose in the so-called “LAIC effect”
(lithosphere–atmosphere–ionosphere coupling). Finally, the location and
dimensions of the microcracks that explain some anomalous magnetic
measurements are shown.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.