VAN method

The VAN method – named after P. Varotsos, K. Alexopoulos and K. Nomicos, authors of the 1981 papers describing it^[1]^[2] – measures low frequency electric signals, termed "seismic electric signals" (SES), by which Varotsos and several colleagues claimed to have successfully predicted earthquakes in Greece.^[3]^[4] Both the method itself and the manner by which successful predictions were claimed have been severely criticized^[5]^[6]^[7] and debated by VAN, but the critics have not retracted their views.^[8]^[9] In 2001 the estimation of the time window of the forthcoming earthquake was changed to use a new analysis, termed "natural time".^[10] Research related to the VAN method is currently carried out at the Solid Earth Physics Institute, University of Athens, Greece.

Description of the VAN method

Prediction of earthquakes with this method is based on the detection, recording and evaluation of seismic electric signals or SES. These electrical signals have a fundamental frequency component of 1 Hz or less and an amplitude the logarithm of which scales with the magnitude of the earthquake.^[11] According to VAN proponents, SES are emitted by rocks under stresses caused by plate-tectonic forces. There are three types of reported electric signal:^[4]

Electric signals that occur shortly before a major earthquake. Signals of this type were recorded 6.5 hours before the 1995 Kobe earthquake in Japan, for example.^[12]
Electric signals that occur some time before a major earthquake.
A gradual variation in the Earth's electric field some time before an earthquake.

Several hypotheses have been proposed to explain SES:

Stress-related phenomena: Seismic electric signals are perhaps attributed to the piezoelectric behaviour of some minerals, especially quartz, or to effects related to the behavior of crystallographic defects under stress or strain. Series of SES, termed SES activities (which are recorded before major earthquakes), may appear a few weeks to a few months before an earthquake when the mechanical stress reaches a critical value.^[2]^[13] The generation of electric signals by minerals under high stress leading to fracture has been confirmed with laboratory experiments.^[14]
Thermoelectric phenomena: Alternately, Chinese researchers proposed a mechanism which relies on the thermoelectric effect in magnetite.^[15]
Groundwater phenomena: Three mechanisms have been proposed relying on the presence of groundwater in generating SES. The electrokinetic effect is associated with the motion of groundwater during a change in pore pressure.^[16] The seismic dynamo effect is associated with the motion of ions in groundwater relative to the geomagnetic field as a seismic wave creates displacement. Circular polarization would be characteristic of the seismic dynamo effect, and this has been observed both for artificial and natural seismic events.^[17] A radon ionization effect, caused by radon release and then subsequent ionization of material in groundwater, may also be active. The main isotope of radon is radioactive with a half-life of 3.9 days, and the nuclear decay of radon is known to have an ionizing effect on air. Many publications have reported increased radon concentration in the vicinity of some active tectonic faults a few weeks prior to strong seismic events.^[18] However, a strong correlation between radon anomalies and seismic events has not been demonstrated.^[19]

While the electrokinetic effect may be consistent with signal detection tens or hundreds of kilometers away, the other mechanisms require a second mechanism to account for propagation:

Signal transmission along faults: In one model, seismic electric signals propagate with relatively low attenuation along tectonic faults, due to the increased electrical conductivity caused either by the intrusion of ground water into the fault zone(s) or by the ionic characteristics of the minerals.^[20]
Rock circuit: In the defect model, the presence of charge carriers and holes can be modeled as making an extensive circuit.^[21]

Seismic electric signals are detected at stations which consist of pairs of electrodes (oriented NS and EW) inserted into the ground, with amplifiers and filters. The signals are then transmitted to the VAN scientists in Athens where they are recorded and evaluated. Currently the VAN team operates 9 stations, while in the past (until 1989) they could afford up to 17.^[22]

The VAN team claimed that they were able to predict earthquakes of magnitude larger than 5, with an uncertainty of 0.7 units of magnitude, within a radius of 100 km, and in time window ranging from several hours to a few weeks. Several papers confirmed this success rate, leading to statistically significant conclusion.^[23] For example, there were eight M ≥ 5.5 earthquakes in Greece from January 1, 1984 through September 10, 1995, and the VAN network forecast six of these.^[24]

The VAN method has also been used in Japan,^[10] but in early attempts success comparable to that achieved in Greece was "difficult" to attain.^[25] A preliminary investigation of seismic electric signals in France led to encouraging results.^[26]

Earthquake prediction using "natural time" analysis

Since 2001 the VAN team has attempted to improve the accuracy of the estimation of the time of the forthcoming earthquake. To that end, they introduced the concept of natural time, a time series analysis technique which puts weight on a process based on the ordering of events.^[27] Two terms characterize each event, the "natural time" $χ$ , and the energy $Q$ . $χ$ is defined as $k / N$ , where k is an integer (the $k$ -th event) and $N$ is the total number of events in the time sequence of data. A related term, $p k$ , is the ratio $Q k / Q total$ , which describes the fractional energy released. They introduce a critical term $κ$ , the "variance in natural time", which puts extra weight on the energy term $p k$ :

\kappa =\sum _{k=1}^{N}p_{k}(\chi _{k})^{2}-{\bigl (}\sum _{k=1}^{N}p_{k}\chi _{k}{\bigr )}^{2}

where

\textstyle \chi _{k}=k/N

and

\textstyle \ p_{k}={\frac {Q_{k}}{\sum _{n=1}^{N}Q_{n}}}

which gives

\kappa =\sum _{k=1}^{N}p_{k}(k/N)^{2}-{\bigl (}\sum _{k=1}^{N}p_{k}(k/N){\bigr )}^{2}

Their current method detects SES as valid when $κ$ = 0.070. Once the SES are deemed valid, a second analysis is started in which the subsequent seismic (rather than electric) events are noted, and the region is divided up as a Venn diagram with at least two seismic events per overlapping rectangle. When the distribution of $κ$ for the rectangular regions has its maximum at $κ$ = 0.070, a critical seismic event is imminent, i.e. it will occur in a few days to one week or so, and a report is issued.^[28]

Results

The VAN team claim that out of seven mainshocks with magnitude Mw>=6.0 from 2001 through 2010 in the region of latitude N 36° to N 41° and longitude E 19° to E 27°, all but one could be classified with relevant SES activity identified and reported in advance through natural time analysis. Additionally, they assert that the occurrence time of four of these mainshocks with magnitude Mw>=6.4 were identified to within "a narrow range, a few days to around one week or so."^[29] These reports are inserted in papers housed in arXiv, and new reports are made and uploaded there.^[30] For example, a report preceding the strongest earthquake in Greece during the period 1983-2011, which occurred on February 14, 2008, with magnitude (Mw) 6.9, was publicized in arXiv almost two weeks before, on February 1, 2008.^[31] A description of the updated VAN method was collected in a book published by Springer in 2011, titled "Natural Time Analysis: The New View of Time."^[32]

Natural time analysis also claims that the physical connection of SES activities with earthquakes is as follows: Taking the view that the earthquake occurrence is a phase-change (critical phenomenon), where the new phase is the mainshock occurrence, the above-mentioned variance term κ is the corresponding order parameter.^[32] The κ value calculated for a window comprising a number of seismic events comparable to the average number of earthquakes occurring within a few months, fluctuates when the window is sliding through a seismic catalogue. The VAN team claims that these κ fluctuations exhibit a minimum a few months before a mainshock occurrence and in addition this minimum occurs simultaneously with the initiation of the corresponding SES activity, and that this is the first time in the literature that such a simultaneous appearance of two precursory phenomena in independent datasets of different geophysical observables (electrical measurements, seismicity) has been observed.^[33] Furthermore, the VAN team claims that their natural time analysis of the seismic catalogue of Japan during the period from January 1, 1984 until the occurrence of the magnitude 9.0 Tohoku earthquake on March 11, 2011, revealed that such clear minima of the κ fluctuations appeared before all major earthquakes with magnitude 7.6 or larger. The deepest of these minima was said to occur on January 5, 2011, i.e., almost two months before the Tohoku earthquake occurrence.^[34] Finally, by dividing the Japanese region into small areas, the VAN team states that some small areas show minimum of the κ fluctuations almost simultaneously with the large area covering the whole Japan and such small areas clustered within a few hundred kilometers from the actual epicenter of the impending major earthquake.^[35]^[36]

Criticisms of VAN

Currently, the major criticism of the VAN method is that results have not yet been replicated by scientists outside specific research groups in Greece and Japan. Testing of the method needs to be done by scientists unrelated to these two groups. Independent verification is a standard protocol in science.

Historically, the usefulness of the VAN method for prediction of earthquakes had been a matter of debate. Both positive and negative criticism on an older conception of the VAN method is summarized in the 1996 book "A Critical Review of VAN", edited by Sir James Lighthill.^[37] A critical review of the statistical methodology was published by Y. Y. Kagan of UCLA in 1997.^[38] Note that these criticisms predate the time series analysis methods introduced by the VAN group in 2001. The main points of the criticism were:

Predictive success: VAN has claimed to have observed at a recording station in Athens a perfect record of a one-to-one correlation between SESs and earthquake of magnitude ≥ 2.9 which occurred 7 hours later in all of Greece.^[39] However, it was later shown that the list of earthquake used for the correlation was false. Although VAN stated in their article that the list of earthquakes was that of the Bulletin of the National Observatory of Athens (NOA), it was found that 37% of the earthquakes actually listed in the bulletin, including the largest one, were not in the list used by VAN for issuing their claim. In addition, 40% of the earthquake which VAN claimed had occurred were not in the NOA bulletin.^[40] Examining the probability of chance correlation of 22 claims of successful predictions by VAN of M > 4.0 from January 1, 1987 through November 30, 1989 ^[41] it was found that 74% were false, 9% correlated by chance, and for 14% the correlation was uncertain.^[42] No single event correlated at a probability greater than 85%, whereas the level required in statistics for accepting a hypothesis test as positive would more commonly be 95%.

Proposed SES propagation mechanism: An analysis of the propagation properties of SES in the Earth’s crust showed that it is impossible that signals with the amplitude reported by VAN could have been generated by small earthquakes and transmitted over the several hundred kilometers between the epicenter and the receiving station.^[43] In effect, if the mechanism is based on piezoelectricity or electrical charging of crystal deformations with the signal traveling along faults, then none of the earthquakes which VAN claimed were preceded by SES generated an SES themselves. There is also some doubt that the phenomena of rock physics seen in certain laboratory conditions can be assumed to take place in the Earth’s seismogenic crust.

Electromagnetic compatibility issues: VAN’s publications are further weakened by failure to address the problem of eliminating the many and strong sources of change in the magneto-electric field measured by them, such as telluric currents from weather, and electromagnetic interference (EMI) from man-made signals. One critical paper clearly correlates an SES used by the VAN group with digital radio transmissions made from a military base.^[44]

Scientific reporting: Most importantly, the method is hindered by a lack of statistical testing of the validity of the VAN hypothesis because the researchers keep changing the parameters of the hypothesis (the moving the goalposts) technique).^[45]

Public policy: Finally, one requirement for any earthquake prediction method is that, in order for any prediction to be useful, it must predict a forthcoming earthquake within a reasonable time-frame, epicenter and magnitude. If the prediction is too vague, no feasible decision (such as to evacuate the population of a certain area for a given period of time) can be made. In practice, the VAN group issued a series of telegrams in the 1980s, warning of impending earthquakes that did not occur, or did not occur within the parameters listed in the telegrams. During the same time frame, the technique also missed major earthquakes.^[46] These inaccurate predictions from the early VAN method led to public criticism and the cost associated with false alarms generated ill will.^[47] Major opponents of VAN were the Greek seismologists Vassilis Papazachos and G. Stavrakakis. The debate between Papazachos and the VAN team has repeatedly caused public attention in their home country Greece and has been extensively discussed in the Greek media.

Notes

↑ Varotsos, Alexopoulos & Nomicos 1981a, 1981b
1 2 Varotsos & Alexopoulos 1984
↑ Varotsos & Kuhlanek 1993 (preface to a special edition about VAN)
1 2 Varotsos, Alexopoulos & Lazaridou 1993
↑ Mulargia & Gasperini 1992
↑ Geller 1997, §4.5
↑ ICEF 2011, p. 335
↑ Lighthill 1996 (proceedings of a conference that reviewed VAN)
↑ twenty articles in a special issue of Geophysical Research Letters (table of contents)
1 2 Uyeda, Kamogawa & Tanaka 2009
↑ Varotsos, Alexopoulos & Nomicos 1981a; Varotsos et al. 1981; Varotsos, Alexopoulos & Nomicos 1982.
↑ Matsumoto, Ikeya & Yamanaka 1998.
↑ Varotsos et al. 1986, p. 120.
↑ Hadjicontis et al. 2007
↑ Shen et al. 2011.
↑ Gershenzon, Gokhberg & Yunga 1993.
↑ Honkura et al. 2009.
↑ Pulinets 2007.
↑ ICEF 2011, p. 334.
↑ Varotsos et al. 1998.
↑ Freund 1998.
↑ Varotsos & Lazaridou 1991
↑ Hamada 1993
↑ Uyeda 1996
↑ Utada 1993, p. 153
↑ Maron et al. 1993
↑ Varotsos, Sarlis & Skordas 2002; Varotsos 2006.
↑ Varotsos, Sarlis & Skordas 2011, Chapter 7.
↑ Varotsos, Sarlis & Skordas 2011, p. 326
↑ Lazaridou-Varotsos 2013, p. 169-170
↑ Uyeda & Kamogawa 2008
1 2 Varotsos, Sarlis & Skordas 2011
↑ Varotsos et al. 2013
↑ Sarlis et al. 2013
↑ Sarlis et al. 2015
↑ Huang 2015
↑ Lighthill 1996.
↑ Kagan 1997, p. 512.
↑ Varotsos, Alexopoulos & Nomicos 1981b.
↑ Wyss 1996a.
↑ Varotsos & Lazaridou 1991.
↑ Wyss & Allmann 1996.
↑ Bernard 1992; Bernard & LeMouel 1996.
↑ Pham et al. 1998.
↑ Mulargia & Gasperini 1992; Mulargia & Gasperini 1996; Wyss 1996b.
↑ Hamada 1993.
↑ Mulargia & Geller 2003, p. 318.

References

Bernard, P. (1992), "Plausibility of long distance electrotelluric precursors to earthquakes", Journal of Geophysical Research, 97: 17531–17546, Bibcode:1992JGR....9717531B, doi:10.1029/92JB01215
Bernard, P.; LeMouel, J. (1996), "On electrotelluric signals", in Sir James Lighthill, A Critical Review of VAN – Earthquake Prediction from Seismic Electrical Signals, London, UK: World Scientific Publishing Co Pte Ltd, pp. 118–154, ISBN 978-981-02-2670-1
Freund, F. (1998), "Pre-earthquake signals – Part II: Flow of battery currents in the crust" (PDF), Natural Hazards and Earth System Sciences, 7: 543–548, doi:10.5194/nhess-7-543-2007
Geller, Robert J. (December 1997), "Earthquake prediction: a critical review.", Geophysical Journal International, 131 (3): 425–450, Bibcode:1997GeoJI.131..425G, doi:10.1111/j.1365-246X.1997.tb06588.x
Gershenzon, N.; Gokhberg, M.; Yunga, S. (1993), "On the electromagnetic field of an earthquake focus", Physics of the Earth and Planetary Interiors, 77 (1-2): 13–19, Bibcode:1993PEPI...77...13G, doi:10.1016/0031-9201(93)90030-D
Hadjicontis, V.; Mavromatou, C.; Antsygina, T.; Chishko, K. (2007), "Mechanism of electromagnetic emission in plastically deformed ionic crystals", Phys. Rev. B, 76 (2): 024106, Bibcode:2007PhRvB..76b4106H, doi:10.1103/PhysRevB.76.024106
Hamada, K. (August 1993), "Statistical evaluation of the SES predictions issued in Greece: alarm and success rates", Tectonophysics, 224 (1-3): 203–210, Bibcode:1993Tectp.224..203H, doi:10.1016/0040-1951(93)90073-S
Honkura, Y.; Ogawa, Y.; Matsushima, M.; Nagaoka, S.; Ujihara, N.; Yamawaki, T. (October 2009), "A model for observed circular polarized electric fields coincident with the passage of large seismic waves", Journal of Geophysical Research, 114: B10103, Bibcode:2009JGRB..11410103H, doi:10.1029/2008JB006117
Huang, Qinghua (2015-01-27). "Forecasting the epicenter of a future major earthquake". Proceedings of the National Academy of Sciences. 112 (4): 944–945. doi:10.1073/pnas.1423684112. ISSN 0027-8424. PMC 4313830. PMID 25583499.
International Commission on Earthquake Forecasting for Civil Protection (30 May 2011), "Operational Earthquake Forecasting: State of Knowledge and Guidelines for Utilization", Annals of Geophysics, 54 (4): 315–391, doi:10.4401/ag-5350
Lazaridou-Varotsos, M. (2013), Earthquake Prediction by Seismic Electric Signals: The Success of the VAN method over thirty years, Springer-Praxis, doi:10.1007/978-3-642-24406-3, ISBN 978-3-642-24405-6
Lighthill, Sir James, ed. (1996), A Critical Review of VAN – Earthquake Prediction from Seismic Electrical Signals, London, UK: World Scientific Publishing Co Pte Ltd, ISBN 978-981-02-2670-1
Maron, C.; Baubron, G.; Herbreteau, L.; Massinon, B. (August 1993), "Experimental study of a VAN network in the French Alps", Tectonophysics, 224 (1-3): 51–81, Bibcode:1993Tectp.224...51M, doi:10.1016/0040-1951(93)90058-R
Matsumoto, H.; Ikeya, M.; Yamanaka, C. (1998), "Analysis of barber-pole color and speckle noises recorded 6 and a half hours before the Kobe earthquake", Japanese Journal of Applied Physics, 37 (1): L1409–L1411, Bibcode:1998JaJAP..37L1409M, doi:10.1143/JJAP.37.L1409
Mulargia, F.; Gasperini, P. (July 1992), "Analyzing the statistical validity of earthquake precursors. An application to the "VAN" method", Geophysical Journal International, 111 (1): 32–44, doi:10.1111/j.1365-246x.1992.tb00552.x
Mulargia, F.; Gasperini, P. (1996), "Behind VAN: Tectonic stress changes or earthquake induced alertness?", in Sir James Lighthill, A Critical Review of VAN – Earthquake Prediction from Seismic Electrical Signals, London, UK: World Scientific Publishing Co Pte Ltd, pp. 244–249, ISBN 978-981-02-2670-1
Mulargia, F.; Geller, R. (2003), Earthquake Science and Seismic Risk Reduction, Springer, ISBN 978-1402017773
Pham, V.; Boyer, D.; Chouliaras, G.; Le Mouël, J.; Rossignol, J.; Stavrakakis, G. (June 1998), "Characteristics of electromagnetic noise in the Ioannina region (Greece); a possible origin for so called 'Seismic Electric Signal' (SES)", Geophysical Research Letters, 25 (12): 2229–2232, Bibcode:1998GeoRL..25.2229P, doi:10.1029/98GL01593
Pulinets, S. (May 2007), "Natural radioactivity, earthquakes, and the ionosphere", Eos, Transactions, American Geophysical Union, 88 (20): 217–218, Bibcode:2007EOSTr..88..217P, doi:10.1029/2007EO200001
Shen, Xuhui; Zhang, Xuemin; Wang, Lanwei; Chen, Huaran; Wu, Yun; Yuan, Shigeng; Shen, Junfeng; Zhao, Shufan; Qian, Jiadong; Ding, Jianhai (2011-12-10). "The earthquake-related disturbances in ionosphere and project of the first China seismo-electromagnetic satellite". Earthquake Science. 24 (6): 639–650. doi:10.1007/s11589-011-0824-0. ISSN 1674-4519.
Sarlis, Nicholas V.; Skordas, Efthimios S.; Varotsos, Panayiotis A.; Nagao, Toshiyasu; Kamogawa, Masashi; Tanaka, Haruo; Uyeda, Seiya (2013-08-20). "Minimum of the order parameter fluctuations of seismicity before major earthquakes in Japan". Proceedings of the National Academy of Sciences. 110 (34): 13734–13738. doi:10.1073/pnas.1312740110. ISSN 0027-8424. PMC 3752201. PMID 23918353.
Sarlis, Nicholas V.; Skordas, Efthimios S.; Varotsos, Panayiotis A.; Nagao, Toshiyasu; Kamogawa, Masashi; Uyeda, Seiya (2015-01-27). "Spatiotemporal variations of seismicity before major earthquakes in the Japanese area and their relation with the epicentral locations". Proceedings of the National Academy of Sciences. 112 (4): 986–989. doi:10.1073/pnas.1422893112. ISSN 0027-8424. PMC 4313817. PMID 25548194.
Sarlis, N.; Lazaridou, M.; Kapiris, P.; Varotsos, P. (1999-11-01). "Numerical model of the selectivity effect and the ΔV/L criterion". Geophysical Research Letters. 26 (21): 3245–3248. doi:10.1029/1998GL005265. ISSN 1944-8007.
Uyeda, S. (1996), "Introduction to the VAN method of earthquake prediction", in Sir James Lighthill, A Critical Review of VAN – Earthquake Prediction from Seismic Electrical Signals, London, UK: World Scientific Publishing Co Pte Ltd, ISBN 978-981-02-2670-1
Uyeda, Seiya; Kamogawa, Masashi (2008-09-23). "The Prediction of Two Large Earthquakes in Greece". Eos, Transactions American Geophysical Union. 89 (39): 363–363. doi:10.1029/2008EO390002. ISSN 2324-9250.
Uyeda, S.; Kamogawa, M.; Tanaka, H. (February 2009), "Analysis of electrical activity and seismicity in the natural time domain for the volcanic-seismic swarm activity in 2000 in the Izu Island region, Japan", Journal Geophysical Research, 114 (B2): B02310, Bibcode:2009JGRB..11402310U, doi:10.1029/2007JB005332
Utada, H. (August 1993), "On the physical background of the VAN earthquake prediction method", Tectonophysics, 224 (1-3): 153–160, Bibcode:1993Tectp.224..153U, doi:10.1016/0040-1951(93)90067-T
Varotsos, P.; Alexopoulos, K. (1984-12-01). "Physical properties of the variations of the electric field of the earth preceding earthquakes, I". Tectonophysics. 110 (1): 73–98. doi:10.1016/0040-1951(84)90059-3.
Varotsos, P.; Alexopoulos, K. (1984-12-01). "Physical properties of the variations of the electric field of the earth preceding earthquakes. II. determination of epicenter and magnitude". Tectonophysics. 110 (1): 99–125. doi:10.1016/0040-1951(84)90060-X.
Varotsos, P. (2006), "What happened before the last five strong earthquakes in Greece", Proc. Jpn. Acad. Ser. B, 82 (2): 86–91, Bibcode:2006PJAB...82...86V, doi:10.2183/pjab.82.86
Varotsos, P.; Alexopoulos, K.; Lazaridou, M. (1993), "Latest aspects of earthquake prediction in Greece based on seismic electric signals, II", Tectonophysics, 224: 1–37, Bibcode:1993Tectp.224....1V, doi:10.1016/0040-1951(93)90055-O
Varotsos, P.; Alexopoulos, K.; Nomicos, K. (1981a), "Seismic electric currents", Proceedings of the Academy of Athens, 56: 277–286
Varotsos, P.; Alexopoulos, K.; Nomicos, K. (1981b), "Seven-hour precursors to earthquakes determined from telluric currents,", Praktika of the Academy of Athens, 56: 417–433
Varotsos, P.; Alexopoulos, K.; Nomicos, K. (1982), "Electrotelluric precursors to earthquakes", Proceedings of the Academy of Athens, 57: 341–363
Varotsos, P.; Alexopoulos, K.; Nomicos, K.; Lazaridou, M. (1986), "Earthquake prediction and electric signals", Nature, 322 (6075): 120, Bibcode:1986Natur.322..120V, doi:10.1038/322120a0
Varotsos, P.; Alexopoulos, K.; Nomicos, K.; Papaioannou, G.; Varotsos, M.; Revelioti-Dologlou, E. (1981), "Determination of the epicenter of impending earthquakes from precursor changes of the telluric current", Proceedings of the Academy of Athens, 56: 434–446
Varotsos, P.; Kuhlanek, P. (August 1993), "Preface [to special issue: "Measurements and Theoretical Models of the Earth's Electric Field Variations Related to Earthquakes"]", Tectonophysics, 224 (1-3): vii–viii, doi:10.1016/0040-1951(93)90054-n
Varotsos, P.; Lazaridou, M. (March 1991), "Latest aspects of earthquake prediction in Greece based on seismic electric signals" (PDF), Tectonophysics, 188 (3-4): 321–347, Bibcode:1991Tectp.188..321V, doi:10.1016/0040-1951(91)90462-2
Varotsos, P.; Eftaxias, K.; Lazaridou, M.; Dologlou, E.; Hadjicontis, V. (1996-05-27). "Reply to "Inaccuracies in seismicity and magnitude data used by Varotsos and Co-workers," by M. Wyss". Geophysical Research Letters. 23 (11): 1303–1306. doi:10.1029/96GL01415. ISSN 1944-8007.
Varotsos, P.; Eftaxias, K.; Lazaridou, M.; Dologlou, E.; Hadjicontis, V. (1996-05-27). "Reply to "Probability of chance correlations of earthquakes with predictions in areas of heterogeneous seismicity rate: The VAN Case," by M. Wyss and A. Allmann". Geophysical Research Letters. 23 (11): 1311–1314. doi:10.1029/96GL00908. ISSN 1944-8007.
Varotsos, P.; Sarlis, N.; Lazaridou, M.; Kapiris, P. (1998), "Transmission of stress induced electric signals", Journal of Applied Physics, 83: 60–70, Bibcode:1998JAP....83...60V, doi:10.1063/1.366702
Varotsos, P.; Sarlis, N.; Skordas, E. (2002), "Long-range correlations in the electric signals that precede rupture" (PDF), Physical Review E, 66: 011902, doi:10.1103/physreve.66.011902
Varotsos, P.; Sarlis, N.; Skordas, E. (2011), Natural time analysis : the new view of time ; Precursory seismic electric signals, earthquakes and other complex time series, Springer Praxis, ISBN 364216448-X
Varotsos, P. A.; Sarlis, N. V.; Skordas, E. S.; Lazaridou, M. S. (2013-03-18). "Seismic Electric Signals: An additional fact showing their physical interconnection with seismicity". Tectonophysics. 589: 116–125. doi:10.1016/j.tecto.2012.12.020.
Wyss, M. (May 1996a), "Inaccuracies in seismicity and magnitude data used by Varotsos and coworkers", Geophysical Research Letters, 23 (11): 1299–1302, Bibcode:1996GeoRL..23.1299W, doi:10.1029/95GL03545
Wyss, M. (1996b), "Brief summary of some reasons why the VAN hypothesis for predicting earthquakes has to be rejected", in Sir James Lighthill, A Critical Review of VAN – Earthquake Prediction from Seismic Electrical Signals, London, UK: World Scientific Publishing Co Pte Ltd, pp. 250–266, ISBN 978-981-02-2670-1
Wyss, M.; Allmann, A. (May 1996), "Probability of chance correlations of earthquakes with predictions in areas of heterogeneous seismicity rate: the VAN case", Geophysical Research Letters, 23 (11): 1307–1310, Bibcode:1996GeoRL..23.1307W, doi:10.1029/95GL03548
Wyss, M.; Allmann, A. (1996-05-27). "Probability of chance correlations of earthquakes with predictions in areas of heterogeneous seismicity rate: The VAN Case". Geophysical Research Letters. 23 (11): 1307–1310. doi:10.1029/95GL03548. ISSN 1944-8007.

External links

Nature debates. Is the reliable prediction of individual earthquakes a realistic scientific goal?
VAN earthquake prediction method.
P. Varotsos' bibliography (the principal source of "VAN" papers).

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