Javier Vallejos scite author profile

This paper describes a detailed study of the Modified Omori's law n(t) = K/(c ? t) p applied to 163 mining-induced aftershock sequences from four different mine environments in Ontario, Canada. We demonstrate, using a rigorous statistical analysis, that this equation can be adequately used to describe the decay rate of mining-induced aftershock sequences. The parameters K, p and c are estimated using a uniform method that employs the maximum likelihood procedure and the Anderson-Darling statistic. To estimate consistent decay parameters, the method considers only the time interval that satisfies power-law behavior. The p value differs from sequence to sequence, with most (98%) ranging from 0.4 to 1.6. The parameter K can be satisfactorily expressed by: K = jN 1 , where j is an activity ratio and N 1 is the measured number of events occurring during the first hour after the principal event. The average j values are in a well-defined range. Theoretically j B 0.8, and empirically j [ [0.3-0.5]. These two findings enable us to develop a real-time event rate re-entry protocol 1 h after the principal event. Despite the fact that the Omori formula is temporally self-similar, we found a characteristic time T MC at the maximum curvature point, which is a function of Omori's law parameters. For a time sequence obeying an Omori process, T MC marks the transition from highest to lowest event rate change. Using solely the aftershock decay rate, therefore, we recommend T MC as a preliminary estimate of the time at which it may be considered appropriate to re-enter an area affected by a blast or large event. We found that T MC can be estimated without specifying a p value by the expression: T MC = aN 1 b , where a and b are two parameters dependent on local conditions. Both parameters presented well-constrained empirical ranges for the sites analyzed: a [ [0.3-0.5] and b [ [0.5-0.7]. These findings provide concise and well-justified guidelines for event rate re-entry protocol development.

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Calibration and Verification of Two Bonded-Particle Models for Simulation of Intact Rock Behavior

Vallejos

Salinas

Delonca

et al. 2017

Int. J. Geomech.

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Application of Synthetic Rock Mass modeling to veined core-size samples

Vallejos

Suzuki

Brzovic³

et al. 2016

International Journal of Rock Mechanics and Mining Sciences

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Open pit mine planning considering geomechanical fundamentals

Parra

Morales

Vallejos

et al. 2017

International Journal of Mining, Reclamation and Environment

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Statistical analysis of the stability number adjustment factors and implications for underground mine design

Vallejos

Delonca

Fuenzalida

et al. 2016

International Journal of Rock Mechanics and Mining Sciences

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Geostatistical simulation to map the spatial heterogeneity of geomechanical parameters: A case study with rock mass rating

Pinheiro

Vallejos

Miranda

et al. 2016

Engineering Geology

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Javier Vallejos

Logistic regression and neural network classification of seismic records

Correlations between mining and seismicity for re-entry protocol development

Omori’s Law Applied to Mining-Induced Seismicity and Re-entry Protocol Development

Calibration and Verification of Two Bonded-Particle Models for Simulation of Intact Rock Behavior

Application of Synthetic Rock Mass modeling to veined core-size samples

Open pit mine planning considering geomechanical fundamentals

Statistical analysis of the stability number adjustment factors and implications for underground mine design

Geostatistical simulation to map the spatial heterogeneity of geomechanical parameters: A case study with rock mass rating

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