A Non-Extensive Statistical Mechanics View on Easter Island Seamounts Volume Distribution

Vallianatos, Filippos

doi:10.3390/geosciences8020052

Cited by 4 publications

(4 citation statements)

References 42 publications

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“…Also worth mentioning are selected entropic applications beyond BG in other areas of knowledge: complex networks [ 16 , 17 , 18 ]; economics [ 149 , 150 , 151 , 152 , 153 , 154 , 155 , 156 ]; geophysics (earthquakes, atmosphere) [ 157 , 158 , 159 , 160 , 161 , 162 , 163 , 164 , 165 , 166 ]; general and quantum chemistry [ 139 , 167 , 168 , 169 , 170 , 171 ]; hydrology and engineering (water engineering [ 172 ] and materials engineering [ 173 , 174 ]); power grids [ 175 ]; the environment [ 176 ]; medicine [ 177 , 178 , 179 ]; biology [ 180 , 181 ]; computational processing of medical images (microcalcifications in mammograms [ 182 ] and magnetic resonance for multiple sclerosis [ 183 ]) and time series (e.g., ECG in coronary disease [ 184 ] and EEG in epilepsy [ 185 , 186 ]); train delays [ 187 ]; citations of scientific publications and scientometrics [ 188 , 189 ]; global optimization techniques [ 190 ...…”

Section: Non-boltzmannian Entropy Measures and Distributionsmentioning

confidence: 99%

Beyond Boltzmann–Gibbs–Shannon in Physics and Elsewhere

Tsallis

2019

Entropy

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The pillars of contemporary theoretical physics are classical mechanics, Maxwell electromagnetism, relativity, quantum mechanics, and Boltzmann–Gibbs (BG) statistical mechanics –including its connection with thermodynamics. The BG theory describes amazingly well the thermal equilibrium of a plethora of so-called simple systems. However, BG statistical mechanics and its basic additive entropy S B G started, in recent decades, to exhibit failures or inadequacies in an increasing number of complex systems. The emergence of such intriguing features became apparent in quantum systems as well, such as black holes and other area-law-like scenarios for the von Neumann entropy. In a different arena, the efficiency of the Shannon entropy—as the BG functional is currently called in engineering and communication theory—started to be perceived as not necessarily optimal in the processing of images (e.g., medical ones) and time series (e.g., economic ones). Such is the case in the presence of generic long-range space correlations, long memory, sub-exponential sensitivity to the initial conditions (hence vanishing largest Lyapunov exponents), and similar features. Finally, we witnessed, during the last two decades, an explosion of asymptotically scale-free complex networks. This wide range of important systems eventually gave support, since 1988, to the generalization of the BG theory. Nonadditive entropies generalizing the BG one and their consequences have been introduced and intensively studied worldwide. The present review focuses on these concepts and their predictions, verifications, and applications in physics and elsewhere. Some selected examples (in quantum information, high- and low-energy physics, low-dimensional nonlinear dynamical systems, earthquakes, turbulence, long-range interacting systems, and scale-free networks) illustrate successful applications. The grounding thermodynamical framework is briefly described as well.

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Section: Non-boltzmannian Entropy Measures and Distributionsmentioning

confidence: 99%

Beyond Boltzmann–Gibbs–Shannon in Physics and Elsewhere

Tsallis

2019

Entropy

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“…In the case of the recorded AE activity during the fracture of brittle materials (concrete and rocks), the continuous variable X corresponds to an AE parameter, such as the inter-event time or inter-event distance between two successive micro-cracks generated within the material, due to the applied mechanical stress [24,26,27]. The maximization of q-entropy under appropriate constraints generates probability distributions, the so-called q-distributions, such as q-exponential, q-Gaussian, q-Weibull distributions, etc [32][33][34]. The q-exponential distribution has been extensively used to describe the cumulative distribution functions (CDF) of seismic parameters in global and regional scale, and the AE activity in laboratory-scale fracturing experiments of rocks [24][25][26][27][28].…”

Section: Non-extensive Statistical Analysis Of Acoustic Emissionsmentioning

confidence: 99%

The use of acoustic emissions technique in the monitoring of fracturing in concrete using soundless chemical demolition agent

Saltas

Peraki

Vallianatos

2019

Frattura Ed Integrità Strutturale

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Soundless chemical demolition agents (SCDAs) have been used during the last decades in the demolition of boulders and concrete structures as well as in open-surface and sub-surface rock excavation, as an alternative to the use of explosives posing safety risks. However, the knowledge of the governing fracture mechanisms in brittle materials is rather limited. In the present work, we thoroughly investigate the use of the acoustic emission technique to study the SCDA-induced fracture process in concrete blocks. Energy-related features and waveform parameters of the recorded AE activity are correlated to the fracture mode of the concrete where a quasi-static behavior is observed. Monitoring of the progressive fracture is also achieved by the 3D localization of the AE sources. The distribution of the inter-event times of the recorded hits is further analyzed in the context of non-extensive statistical physics.

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“…The objectives of the present work are to study, in terms of Tsallis entropy, the spatial properties of magnitude–frequency distribution of seismicity in complex systems where fracturing and strong correlations exist, such as in the volcanotectonic Yellowstone system, along with the spatiotemporal properties of the swarms which occurred on the Yellowstone Lake during December–January 2008–2009 and the 2010 Madison Plateau using the ideas of Non-Extensive Statistical Physics (NESP) and Tsallis entropy [ 10 , 11 , 12 ], which is one of the entropies used within the family of generalized entropies (see [ 13 , 14 , 15 , 16 , 17 ]). Since the complexity issues related with Geophysical problems are not high-order issues, the applicability of Tsallis entropy in Earth physics has been demonstrated in a series of recent publications on seismicity [ 18 , 19 , 20 , 21 , 22 ], natural hazards [ 23 , 24 ], plate tectonics [ 25 ], geomagnetic reversals [ 26 ], volcanic systems [ 27 ], rock physics [ 28 ], applied geophysics [ 29 ], and fault-length distributions [ 30 , 31 ]. Using the seismic data provided by the University of Utah Seismological Stations (UUSS), we analyzed the inter-event time and distance distributions of the earthquakes that occurred during the two swarms, fitting the observed data with the q -exponential function that maximizes the Tsallis entropy, along with the magnitude-frequency distribution, as formulated in the frame of NESP [ 32 ].…”

Section: Introductionmentioning

confidence: 99%

Complexity of the Yellowstone Park Volcanic Field Seismicity in Terms of Tsallis Entropy

Chochlaki

Michas

Vallianatos

2018

Entropy

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The Yellowstone Park volcanic field is one of the most active volcanic systems in the world, presenting intense seismic activity that is characterized by several earthquake swarms over the last decades. In the present work, we focused on the spatiotemporal properties of the recent earthquake swarms that occurred on December-January 2008-2009 and the 2010 Madison Plateau swarm, using the approach of Non Extensive Statistical Physics (NESP). Our approach is based on Tsallis entropy, and is used in order to describe the behavior of complex systems where fracturing and strong correlations exist, such as in tectonic and volcanic environments. This framework is based on the maximization of the non-additive Tsallis entropy S q , introducing the q-exponential function and the entropic parameter q that expresses the degree of non-extentivity of the system. The estimation of the q-parameters could be used as a correlation degree among the events in the spatiotemporal evolution of seismicity. Using the seismic data provided by University of Utah Seismological Stations (UUSS), we analyzed the inter-event time (T) and distance (r) distribution of successive earthquakes that occurred during the two swarms, fitting the observed data with the q-exponential function, resulting in the estimation of the Tsallis entropic parameters q T , q r for the inter-event time and distance distributions, respectively. Furthermore, we studied the magnitude-frequency distribution of the released earthquake energies E as formulated in the frame of NESP, which results in the estimation of the q E parameter. Our analysis provides the triplet (q E , q T , q r ) that describes the magnitude-frequency distribution and the spatiotemporal scaling properties of each of the studied earthquake swarms. In addition, the spatial variability of q E throughout the Yellowstone park volcanic area is presented and correlated with the existence of the regional hydrothermal features.

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A Non-Extensive Statistical Mechanics View on Easter Island Seamounts Volume Distribution

Cited by 4 publications

References 42 publications

Beyond Boltzmann–Gibbs–Shannon in Physics and Elsewhere

Beyond Boltzmann–Gibbs–Shannon in Physics and Elsewhere

The use of acoustic emissions technique in the monitoring of fracturing in concrete using soundless chemical demolition agent

Complexity of the Yellowstone Park Volcanic Field Seismicity in Terms of Tsallis Entropy

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