2018
DOI: 10.1029/2017jb015039
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Surface Rupture Morphology and Vertical Slip Distribution of the 1959Mw7.2 Hebgen Lake (Montana) Earthquake From Airborne Lidar Topography

Abstract: The 1959 Mw ∼7.2 Hebgen Lake earthquake is among the largest continental normal faulting events recorded, as well as one of the earliest associated with a multifault rupture. Multimeter vertical slip was observed on three main, morphologically distinct strands: the Hebgen fault and southeastern section of the Red Canyon fault, which both follow sharp topographic rangefronts, and the Red Canyon fault Kirkwood Ridge section, which cuts steep topography in the footwall of the Hebgen fault. We augment early field,… Show more

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Cited by 26 publications
(25 citation statements)
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“…For profiles with heavy vegetation, we manually selected and removed profile points above the ground surface prior to defining footwall and hanging-wall surface projections. Because footwall fault exposures (preserved free faces) along the 1983 rupture are rare, we calculate VS rather than fault throw, which requires assumptions about near-surface fault dip (e.g., Johnson et al, 2018). Although slope steepness and fault dip can enhance the discrepancy between actual fault throw and measured VS (e.g., Mackenzie and Elliott, 2017), our VS measurements are likely ~80%-90% or greater of throw because steep (60°-90°; Crone et al, 1987) near-surface faults dip in the same direction as moderately (<15°) sloping geomorphic surfaces (Caskey, 1995).…”
Section: Vertical Separation Measurementsmentioning
confidence: 99%
See 1 more Smart Citation
“…For profiles with heavy vegetation, we manually selected and removed profile points above the ground surface prior to defining footwall and hanging-wall surface projections. Because footwall fault exposures (preserved free faces) along the 1983 rupture are rare, we calculate VS rather than fault throw, which requires assumptions about near-surface fault dip (e.g., Johnson et al, 2018). Although slope steepness and fault dip can enhance the discrepancy between actual fault throw and measured VS (e.g., Mackenzie and Elliott, 2017), our VS measurements are likely ~80%-90% or greater of throw because steep (60°-90°; Crone et al, 1987) near-surface faults dip in the same direction as moderately (<15°) sloping geomorphic surfaces (Caskey, 1995).…”
Section: Vertical Separation Measurementsmentioning
confidence: 99%
“…1). As one of the largest intraplate normal-faulting earthquakes recorded historically and an example of the complex rupture of a multisegment normal fault system (Haller and Crone, 2004), the Borah Peak earthquake rupture offers an important opportunity to relate spatial and temporal patterns of surface displacement to fault-rupture processes (e.g., Wesnousky, 2008;Nissen et al, 2014;Haddon et al, 2016;Delano et al, 2017;Personius et al, 2017;Johnson et al, 2018).…”
Section: ■ Introductionmentioning
confidence: 99%
“…Since the field measurements are usually collected across a very narrow aperture that does not extend beyond the immediate proximity of the fault scarp, they are not able to capture the total deformation accommodated across the wider fault zone. Similarly, Johnson et al (2018) estimated fault offset from the relative height difference in the LiDAR between the footwall and the hanging wall topography. While this method can capture some OFD, it is possible that a large proportion of OFD remains unaccounted for, perhaps due to surface modification (e.g., erosion).…”
Section: Qualitative and Quantitative Comparison Of The Oic Data With...mentioning
confidence: 99%
“…The beachball is the focal mechanism of the largest (M w 4.4) earthquake in the sequence. The red line is the surface rupture of the 1959 M w 7.2 Hebgen Lake earthquake (Johnson et al, 2018), black lines show regional faults, and the purple line is the boundary of the 2.1-Ma caldera. (b) A-A′ cross section with depth relative to sea level.…”
Section: Spatial Structure and Geometry Of Relocated Earthquakesmentioning
confidence: 99%
“…The V P /V S decrease we observe would require a porosity increase of~80%, which might be expected if there were increased damage in the northwestern segment of Cluster n (i.e., Cluster n-II) because of its closer proximity to the Hebgen Lake rupture zone. Johnson et al (2018) noted significant scarp height in the southeastern portion of the rupture zone, and because of the relatively low strain rates, it is plausible that the damage in the rupture zone has not yet had time to heal. The increased epicentral scatter in Cluster n-II is also consistent with a highly fractured region.…”
Section: Interpretation Of Observed V P /V S Ratiosmentioning
confidence: 99%