A review on deformation-induced electromagnetic radiation detection: history and current status of the technique

Sharma, Sumeet K.; Chauhan, Vishal Singh; Sinapius, Michael

doi:10.1007/s10853-020-05538-x

Cited by 21 publications

(3 citation statements)

References 261 publications

(345 reference statements)

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“…Significant research on FEMR emissions from rocks and brittle materials has been conducted with experiments focused on low-frequency electromagnetic radiation using samples like concrete, Syracuse limestone, Carrara marble, and green Luserna granite [42][43][44][45] . They aimed to predict failure and resulting seismic activity by investigating the electrical emission phenomenon as a precursor to failure and seismic events.…”

Section: Femr Models and Generationmentioning

confidence: 99%

Fracture-induced Electromagnetic radiation (FEMR) predicting the Syrian-Turkey earthquake (Mw-6.3) on 20.2.2023: An insight on the Dead Sea transform activity

Das,

Frid,

Rabinovitch

et al. 2023

Preprint

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Observations of fracture-induced electromagnetic radiation (FEMR) were conducted along the Dead Sea Transform (DST) from Sodom to Jericho, coinciding with a magnitude (Mw) 6.3 aftershock earthquake (EQ) in the Turkey-Syrian region on February 20, 2023. The FEMR parameters ("hits," Benioff strain release, frequency, rise-time, energy) and associated crack dimensions were analyzed, focusing on trends leading up to the EQ. This study investigated the Benioff Strain plot and other parameters in three consecutive earthquake nucleation stages leading to the catastrophe. The first stage showed increased FEMR hits and frequency, decreased rise time (T'), and crack dimensions. In the second stage, FEMR hits and crack width decreased while other parameters continued to rise, accumulating the second-highest energy, likely due to high-stress drop. The third stage exhibited steadily increasing FEMR hits and energy and a notable increase in crack dimensions, suggesting an imminent macro failure event. The cyclic trend in FEMR hits indicates alternating periods of high activity and silence, potentially linked to stress changes during crack propagation. Taken shortly before the earthquake, these measurements offer valuable insights into how FEMR parameters vary before seismic events, bridging the gap between lab-scale studies of rock collapses under stress and large-scale failure phenomena.

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Section: Femr Models and Generationmentioning

confidence: 99%

Fracture-induced Electromagnetic radiation (FEMR) predicting the Syrian-Turkey earthquake (Mw-6.3) on 20.2.2023: An insight on the Dead Sea transform activity

Das,

Frid,

Rabinovitch

et al. 2023

Preprint

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show abstract

“…Lab experiments on various materials, such as chalk, rocks, glass, ceramics, granite, etc., have been conducted to understand FEMR responses, correlating them with physical parameters like crack dimensions, velocity, and frequency of crack propagation 32 – 41 . Notably, experiments focused on low-frequency electromagnetic radiation from rocks and brittle materials, including concrete, Syracuse limestone, Carrara marble, and green Luserna granite, aimed to predict failure and seismic activity by studying electrical emissions as precursors 42 – 45 .…”

Section: Introductionmentioning

confidence: 99%

Insights into the Dead Sea Transform Activity through the study of fracture-induced electromagnetic radiation (FEMR) signals before the Syrian-Turkey earthquake (Mw-6.3) on 20.2.2023

Das,

Frid,

Rabinovitch

et al. 2024

Sci Rep

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Observations of fracture-induced electromagnetic radiation (FEMR) were conducted along the Dead Sea Transform (DST) from Sodom to Jericho, coinciding with a magnitude (Mw) 6.3 aftershock earthquake (EQ) in the Turkey-Syrian region on February 20, 2023. The FEMR parameters (“hits,” Benioff strain release, frequency, rise-time, energy) and associated crack dimensions were analyzed, focusing on trends leading up to the EQ. This study investigated the Benioff Strain plot and other parameters in three consecutive earthquake nucleation stages leading to the catastrophe. The first stage showed increased FEMR hits and frequency, decreased rise time (T′), and crack dimensions. In the second stage, FEMR hits and crack width decreased while other parameters continued to rise, accumulating the second-highest energy, likely due to high-stress drop. The third stage exhibited steadily increasing FEMR hits and energy and a notable increase in crack dimensions, suggesting an imminent macro failure event. The cyclic trend in FEMR hits indicates alternating periods of high activity and silence, potentially linked to stress changes during crack propagation. Taken shortly before the earthquake, these measurements offer valuable insights into how FEMR parameters vary before seismic events, bridging the gap between lab-scale studies of rock collapses under stress and large-scale failure phenomena.

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“…Effective monitoring and early warning of coal and rock dynamic disasters is the key to disaster prevention and control. In the process of coal and rock fracture under load, the energy accumulated inside will partly be released in the form of electromagnetic energy [4][5][6], based on which, the electromagnetic radiation (EMR) method has been widely used in the field of coal and rock dynamic disaster prevention and control in coal mines [7][8][9].…”

Section: Introductionmentioning

confidence: 99%

Discrete characteristics of instantaneous frequency of EMR induced by coal and rock fracture

Lou

Jia

Wan

et al. 2023

Meas. Sci. Technol.

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To reveal the discrete characteristics of the instantaneous frequency of the electromagnetic radiation (EMR) waveform induced by coal and rock fracture, the uniaxial compression experiments for coal and rock samples were carried out, and the EMR signals with full waveform were acquainted and stored. The empirical wavelet transform (EWT) is used to filter and de-noise the EMR waveform, and then the short-time Fourier transform (STFT) is used to analyze the time-frequency characteristics of the waveform. The discrete characteristics of the instantaneous frequency with a larger amplitude and the relationship between the centroid frequencies and peak-to-peak values (Vpps) of the EMR waveforms are statistically analyzed. The results show that the centroid frequency of 0–100 kHz is negatively correlated with the Vpp, and the relationship between them shows a logarithm function relation. The instantaneous frequency of the EMR waveform of coal and rock fracture has significant discrete characteristics. In detail, for the rock sample, the instantaneous frequencies with relatively large amplitude are mainly 4.5 kHz, 19.5 kHz, 22.0 kHz, and 27.5 kHz; for the coal sample, the instantaneous frequencies are mainly 1.0 kHz, 4.5 kHz, 9.0 kHz, and 74.0 kHz. This discrete characteristic is determined by the natural properties and fracture characteristics of the sample. Compared with the homogeneous rock samples, the internal cracks of the coal samples are well developed and show strong anisotropy, resulting in the discrete characteristics of the instantaneous frequency being relatively weaker. The findings have certain guiding significance for optimizing the design of the EMR monitoring frequency band and improving the pertinence and accuracy of the monitoring and early warning for coal and rock dynamic disasters.

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A review on deformation-induced electromagnetic radiation detection: history and current status of the technique

Cited by 21 publications

References 261 publications

Fracture-induced Electromagnetic radiation (FEMR) predicting the Syrian-Turkey earthquake (Mw-6.3) on 20.2.2023: An insight on the Dead Sea transform activity

Fracture-induced Electromagnetic radiation (FEMR) predicting the Syrian-Turkey earthquake (Mw-6.3) on 20.2.2023: An insight on the Dead Sea transform activity

Insights into the Dead Sea Transform Activity through the study of fracture-induced electromagnetic radiation (FEMR) signals before the Syrian-Turkey earthquake (Mw-6.3) on 20.2.2023

Discrete characteristics of instantaneous frequency of EMR induced by coal and rock fracture

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