Record-breaking events during the compressive failure of porous materials

Pál, Gergő; Raischel, Frank; Lennartz-Sassinek, Sabine; Kun, Ferenc; Main, Ian

doi:10.1103/physreve.93.033006

Cited by 27 publications

(11 citation statements)

References 39 publications

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“…The model proved to be very successful in reproducing the observed power law statistics of burst sizes, energies, durations, and of the waiting times between consecutive events [18,19]. Most recently we have also analyzed the details of the time series of bursts of the model searching for the record breaking events [20].…”

Section: Simulation Of Uniaxial Compressionmentioning

confidence: 98%

“…The fault itself develops as a localized shear band formed by multiple fracturing and refracturing both prior to and during slip. To study this problem, recently we have introduced a discrete element model of porous sedimentary rocks which captures the essential ingredients of the materials' microstructure and of the dynamics of breaking [18][19][20].…”

Section: Introductionmentioning

confidence: 99%

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Fragmentation and shear band formation by slow compression of brittle porous media

et al. 2016

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Localized fragmentation is an important phenomenon associated with the formation of shear bands and faults in granular media. It can be studied by empirical observation, by laboratory experiment, or by numerical simulation. Here we investigate the spatial structure and statistics of fragmentation using discrete element simulations of the strain-controlled uniaxial compression of cylindrical samples of different finite size. As the system approaches failure, damage localizes in a narrow shear band or synthetic fault "gouge" containing a large number of poorly sorted noncohesive fragments on a broad bandwidth of scales, with properties similar to those of natural and experimental faults. We determine the position and orientation of the central fault plane, the width of the shear band, and the spatial and mass distribution of fragments. The relative width of the shear band decreases as a power law of the system size, and the probability distribution of the angle of the central fault plane converges to around 30 degrees, representing an internal coefficient of friction of 0.7 or so. The mass of fragments is power law distributed, with an exponent that does not depend on scale, and is near that inferred for experimental and natural fault gouges. The fragments are in general angular, with a clear self-affine geometry. The consistency of this model with experimental and field results confirms the critical roles of preexisting heterogeneity, elastic interactions, and finite system size to grain size ratio on the development of shear bands and faults in porous media.

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Section: Simulation Of Uniaxial Compressionmentioning

confidence: 98%

Section: Introductionmentioning

confidence: 99%

Fragmentation and shear band formation by slow compression of brittle porous media

et al. 2016

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“…The record statistics (RS) of stochastic time series has attracted a great attention due to its relevance for weather, climate and earthquake research [50][51][52][53][54][55] . The RS analysis has proven very successful to reveal trends, correlations, and spatio-temporal clustering of events in complex evolving systems [50][51][52][53][54][55][56][57][58][59] . For fracture processes, here we demonstrate that the waiting time between consecutive record breakings, i.e.…”

Section: Record Statistics Of Bursts Signals the Onset Of Acceleratiomentioning

confidence: 99%

Record statistics of bursts signals the onset of acceleration towards failure

Kádár

Pál

Kun

2020

Sci Rep

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Forecasting the imminent catastrophic failure has a high importance for a large variety of systems from the collapse of engineering constructions, through the emergence of landslides and earthquakes, to volcanic eruptions. Failure forecast methods predict the lifetime of the system based on the time-to-failure power law of observables describing the final acceleration towards failure. We show that the statistics of records of the event series of breaking bursts, accompanying the failure process, provides a powerful tool to detect the onset of acceleration, as an early warning of the impending catastrophe. We focus on the fracture of heterogeneous materials using a fiber bundle model, which exhibits transitions between perfectly brittle, quasi-brittle, and ductile behaviors as the amount of disorder is increased. Analyzing the lifetime of record size bursts, we demonstrate that the acceleration starts at a characteristic record rank, below which record breaking slows down due to the dominance of disorder in fracturing, while above it stress redistribution gives rise to an enhanced triggering of bursts and acceleration of the dynamics. The emergence of this signal depends on the degree of disorder making both highly brittle fracture of low disorder materials, and ductile fracture of strongly disordered ones, unpredictable.

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“…In our previous studies, the model was used to investigate the uniaxial compression of cylindrical samples focusing on both the time evolution of the fracture process [14,15,20] and on the spatial structure of the emerging damage [21]. We demonstrated that the gradual cracking proceeds in bursts of beam breakings, analogous to sources of acoustic emissions or crackling noise of real experiments.…”

Section: Discrete Element Simulation Of Compressive Failurementioning

confidence: 99%

Effect of disorder on the spatial structure of damage in slowly compressed porous rocks

Kun

Pál

Вaргa

et al. 2018

Phil. Trans. R. Soc. A.

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Faults and damage zone properties control a range of important phenomena, from the hydraulic properties of underground reservoirs to the physics of earthquakes on a larger scale. Here, we investigate the effect of disorder of porous rocks on the spatial structure of damage emerging under compression. Model rock samples are numerically generated by sedimenting particles where the amount of disorder is controlled by the particle size distribution. To obtain damage bands with a sufficiently large length along axis, we performed simulations of ‘Brazilian’-type compression tests of cylindrical samples. As failure is approached, damage localization leads to the formation of two conjugate shear bands. The orientation angle of bands to the loading direction increases with disorder, implying a decrease in the internal coefficient of friction. The width of the damage band scales as a power law of the degree of disorder. Inside the damage band, the sample is crushed into a large number of pieces with a power law mass distribution. The shape of fragments undergoes a crossover at a disorder-dependent size from the isotropy of small pieces to the anisotropic flattened form of the large ones. The results provide important constraints in understanding the role of disorder in geological fractures. This article is part of the theme issue ‘Statistical physics of fracture and earthquakes’.

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Record-breaking events during the compressive failure of porous materials

Cited by 27 publications

References 39 publications

Fragmentation and shear band formation by slow compression of brittle porous media

Fragmentation and shear band formation by slow compression of brittle porous media

Record statistics of bursts signals the onset of acceleration towards failure

Effect of disorder on the spatial structure of damage in slowly compressed porous rocks

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