Rapid Characterization of the July 2019 Ridgecrest, California, Earthquake Sequence From Raw Seismic Data Using Machine‐Learning Phase Picker

Liu, Min; Zhang, Miao; Zhu, Weiqiang; Ellsworth, William L.; Li, Hongyi

doi:10.1029/2019gl086189

Cited by 89 publications

(74 citation statements)

References 34 publications

(56 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Among these STA/LTA picks, we picked 964 P arrivals and 1,062 S arrivals from the raw waveforms using a machine‐learning phase picker (Zhu & Beroza, 2019). Events were associated and preliminarily located using a grid search‐based earthquake association and location method (Liu et al, 2020; M. Zhang, Ellsworth, et al, 2019). The search space is discretized into uniform grids with a constant size of 0.01° × 0.01° × 2 km, and a minimum of 5 P picks and 10 P + S picks is required for each event.…”

Section: Methodsmentioning

confidence: 99%

Sequential Fault Reactivation and Secondary Triggering in the March 2019 Red Deer Induced Earthquake Swarm

Wang

et al. 2020

Geophysical Research Letters

Self Cite

View full text Add to dashboard Cite

Using data from nodal geophones and broadband seismometers, this study investigates the seismicity near Red Deer, Alberta, a region with increasing cases of hydraulic fracturing (HF)-induced earthquakes. A cluster of 417 events was detected, and their spatial distribution and focal mechanisms reveal a NE trending rupture area with two strike-slip fault planes. Reactivation of preexisting faults by pore pressure diffusion is likely responsible for the occurrence of the earthquake sequence following the M L 4.18 mainshock. The temporal sequence of reactivated fault orientations suggests apparent changes in the local stress field following the mainshock, which is also responsible for a remotely triggered cluster observed 1 month after the mainshock. This secondary triggering process enhances our understanding of the trailing effect of HF-induced seismicity. Plain Language Summary Since 2018, the Red Deer region in Alberta, Canada, has experienced an increasing number of earthquakes, most of which are associated with nearby hydraulic fracturing operations. In this study, we analyze data from a dense array of seismic sensors and regional seismometers to detect and locate events surrounding a hydraulic fracturing site near Red Deer from 4 March to 10 April 2019. The spatial distribution of the earthquakes defines a complex fault system that was activated at two different times. The results in this study signify stress changes in the shallow crust in connection with the 4.18 magnitude earthquake on 4 March 2019. Modifications to the regional stress regime are relatively long-lived, as suggested by the continued occurrences of smaller earthquakes 1 month after the mainshock.

show abstract

Section: Methodsmentioning

confidence: 99%

Sequential Fault Reactivation and Secondary Triggering in the March 2019 Red Deer Induced Earthquake Swarm

Wang

et al. 2020

Geophysical Research Letters

Self Cite

View full text Add to dashboard Cite

show abstract

“…Rapid progress in the application of machine learning methods to event detection, timing, association, and location is transforming the analysis of both natural and induced seismicity (Bergen et al, 2019; Mousavi et al, 2019). New machine learning algorithms for automatic detection and picking of P and S wave arrivals in continuous data are beginning to achieve results comparable to template matching and superior, in some cases, to traditional methods (Liu et al, 2020). For example, Park et al (2020) applied the PhaseNet picker (Zhu & Beroza, 2018) to the entire Guy‐Greenbrier, Arkansas, sequence to detect over 280,000 events (single station) and located almost 90,000 events, compared to fewer than 2000 reported by Horton (2012) using standard network procedures or 13,000 found by FAST.…”

Section: Interpretations and Research Questionsmentioning

confidence: 99%

Hydraulic Fracturing‐Induced Seismicity

Schultz

Skoumal

Brudzinski

et al. 2020

Reviews of Geophysics

Self Cite

228

176

View full text Add to dashboard Cite

Hydraulic fracturing (HF) is a technique that is used for extracting petroleum resources from impermeable host rocks. In this process, fluid injected under high pressure causes fractures to propagate. This technique has been transformative for the hydrocarbon industry, unlocking otherwise stranded resources; however, environmental concerns make HF controversial. One concern is HF‐induced seismicity, since fluids driven under high pressure also have the potential to reactivate faults. Controversy has inevitably followed these HF‐induced earthquakes, with economic and human losses from ground shaking at one extreme and moratoriums on resource development at the other. Here, we review the state of knowledge of this category of induced seismicity. We first cover essential background information on HF along with an overview of published induced earthquake cases to date. Expanding on this, we synthesize the common themes and interpret the origin of these commonalities, which include recurrent earthquake swarms, proximity to well bore, rapid response to stimulation, and a paucity of reported cases. Next, we discuss the unanswered questions that naturally arise from these commonalities, leading to potential research themes: consistent recognition of cases, proposed triggering mechanisms, geologically susceptible conditions, identification of operational controls, effective mitigation efforts, and science‐informed regulatory management. HF‐induced seismicity provides a unique opportunity to better understand and manage earthquake rupture processes; overall, understanding HF‐induced earthquakes is important in order to avoid extreme reactions in either direction.

show abstract

“…Based upon the observed surface ruptures and the satellite images, there are very complex surface ruptures during the 2019 Ridgecrest earthquakes, including the splay ruptures at the SE tip, conjugate ruptures at the NW tip, and the along‐strike variation of surface ruptures near the M w 7.1 epicenter (Figures S1 and S2 in the supporting information) (Barnhart et al, 2019; Brandenberg et al, 2019; Ross et al, 2019). The locations of aftershocks, which provide insights into the subsurface faulting, in general correlate with the mapped surface breaks (Lin, 2020; Liu et al, 2020; Ross et al, 2019; Shelly, 2020), yet apparent differences exist. For example, at the location where the NW rupture of M w 6.4 stopped and the M w 7.1 started, the aftershocks mostly lie along a narrow compact straight strip, while the surface breaks show along‐strike variations with significant offsets to the seismicity (Figure 1; see Figure S1 for a zoom‐in figure).…”

Section: Introductionmentioning

confidence: 98%

“…Both the foreshock (M w 6.4) and mainshock (M w 7.1) were followed by notable aftershocks, with more than 111,000 M L 0.5+ aftershocks within the first 21 days (Ross et al, 2019). The spatial distribution of aftershocks of the M w 6.4 event illuminates that it ruptured a conjugated fault system that forming an “L” shape (Ross et al, 2019; Lin, 2020; Liu et al, 2020; Shelly, 2020). The kinematic subevent and finite fault inversions provide additional evidence that the M w 6.4 event ruptured both the NW‐SE and NE‐SW trending faults (Chen et al, 2020; Feng et al, 2020; Jia et al, 2019; Liu et al, 2019; Ross et al, 2019), although only the NE‐SW trending rupture is captured by the InSAR optical image (Barnhart et al, 2019).…”

Section: Introductionmentioning

confidence: 99%

“…The kinematic subevent and finite fault inversions provide additional evidence that the M w 6.4 event ruptured both the NW‐SE and NE‐SW trending faults (Chen et al, 2020; Feng et al, 2020; Jia et al, 2019; Liu et al, 2019; Ross et al, 2019), although only the NE‐SW trending rupture is captured by the InSAR optical image (Barnhart et al, 2019). About 34 hr later, a Mw 7.1 event initialized near the NW end of the aftershock zone of the M w 6.4 event and ruptured bilaterally on a ~50 km NW‐SE striking fault (Barnhart et al, 2019; Chen et al, 2020; Goldberg et al, 2020; Lin, 2020; Liu et al, 2019; Liu et al, 2020; Ross et al, 2019; Shelly, 2020), with clear surface breaks observed by geological surveys and satellite observations (Brandenberg et al, 2019; Fielding et al, 2020; Ross et al, 2019). To the south, the aftershock zone splits into several subparallel strands that disappear near the NE‐SW striking Garlock fault.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Seismotectonics and Fault Geometries of the 2019 Ridgecrest Sequence: Insight From Aftershock Moment Tensor Catalog Using 3‐D Green's Functions

Wang

Zhan

2020

JGR Solid Earth

View full text Add to dashboard Cite

The 2019 Mw 7.1 Ridgecrest earthquake occurred on 6 July, preceded by the Mw 6.4 foreshock on 4 July 2019. These two earthquakes occurred close in space and time with partially overlapping surface ruptures and aftershock patterns, raising the question of the relationship between the two events. Geological surveys and satellite observations provide important constraints on the surface traces of faulting. However, the subsurface fault geometries, which are important for understanding the regional stress field, earthquake initiation, propagation, and termination, are not well resolved. In this study, moment tensor solutions for 256 earthquakes in the 2019 Ridgecrest sequence were determined by waveform inversion using 3‐D velocity model. The obtained moment tensor solutions show rotations of the stresses after mainshock, indicating the ratio of mainshock stress drop to the background stress to be 0.5–0.9. The obtained moment tensor catalog also facilitates a better understanding of the subsurface fault geometries, including (1) splay faults and antithetic faults in the northwest aftershock zone; (2) shallow flower structures near the Mw 7.1 epicenter; and (3) subparallel faults in the southeast aftershock zone. The aftershocks' studies suggest the very complex surface ruptures near the 2019 Ridgecrest Mw 7.1 epicenter are near‐surface features that linked to a simple large throughgoing fault at >5 km depth. We also found that the southeastern‐most aftershocks, which are located less than a kilometer from the Garlock fault trace, have significant different strike directions from that of the Garlock fault, indicating the central Garlock fault remains seismically quiet.

show abstract

Rapid Characterization of the July 2019 Ridgecrest, California, Earthquake Sequence From Raw Seismic Data Using Machine‐Learning Phase Picker

Cited by 89 publications

References 34 publications

Sequential Fault Reactivation and Secondary Triggering in the March 2019 Red Deer Induced Earthquake Swarm

Sequential Fault Reactivation and Secondary Triggering in the March 2019 Red Deer Induced Earthquake Swarm

Hydraulic Fracturing‐Induced Seismicity

Seismotectonics and Fault Geometries of the 2019 Ridgecrest Sequence: Insight From Aftershock Moment Tensor Catalog Using 3‐D Green's Functions

Contact Info

Product

Resources

About