Yakataga Gap, Alaska: Seismic History and Earthquake Potential

McCann, William R.; Pérez, Omar J.; Sykes, Lynn R.

doi:10.1126/science.207.4437.1309

Cited by 50 publications

(16 citation statements)

References 19 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…East of the Beringian margin, the transition to ocean‐continent subduction is characterized in the landward half of the fore arc by a region of positive residual free‐air gravity anomalies that is well correlated with the extensively studied Shumagin Islands seismic gap [ Sykes , ; Kelleher et al ., ; McCann et al ., ; Davies et al ., ; Boyd and Jacob , ]. This gap is likely associated with the transition in overthrusting plate structure and is defined by the absence of slip in the 1938 Mw 8.2 earthquake [ Johnson et al ., ] and 1957 Mw 8.7 Andreanof Islands earthquake [ Johnson et al ., ].…”

Section: Fore‐arc Structure: Trench‐parallel Fore‐arc Ridgesmentioning

confidence: 90%

Gravity anomalies, crustal structure, and seismicity at subduction zones: 2. Interrelationships between fore‐arc structure and seismogenic behavior

Bassett

Watts

2015

Geochem Geophys Geosyst

View full text Add to dashboard Cite

An ensemble-averaging technique is used to remove the long-wavelength topography and gravity field associated with subduction zones. Short-wavelength residual anomalies are attributed to the tectonic structure of subducting and overthrusting plates. A paired (positive-negative) fore-arc anomaly is observed consisting of a long (>1000 km), linear, trench-parallel ridge landward of the deep-sea-terrace basin. Ridges have amplitudes of 1500-3000 m and 160-240 mGal, wavelengths of 150-200 km, and high gravity anomaly to topography ratios (50-75 mGal km 21 ). The ridge crests correlate with the downdip limit of coseismic slip and strong interplate coupling and in Cascadia, the updip limit of tremor epicenters. The ridge crest may be interpreted as defining the boundary between the velocity-weakening and seismogenic region of the subduction interface and the downdip frictional transition zone. In Tonga-Kermadec, the Kuril Islands and Chile landward ridges are associated with extinct volcanic arcs. Paired anomalies are attributed to the preferential subduction erosion of the outer fore arc and a spatially varying combination of (a) lower crustal underplating beneath the inner fore arc, (b) the transformation of interseismic strain into permanent geologic strain via faulting, folding, or buckling of the inner fore arc, and (c) the relative trenchward migration of extinct volcanic arcs in regions operating with a net crustal deficit. Along-strike transitions in fore-arc morphology and seismogenic behavior are related to preexisting crustal structure of subducting and overthrusting plates. Fore arcs have the added potential of recording the time-integrated response of the upper plate to subduction processes, and fore-arc structure should be considered in tandem with seismological observations.

show abstract

Section: Fore‐arc Structure: Trench‐parallel Fore‐arc Ridgesmentioning

confidence: 90%

Gravity anomalies, crustal structure, and seismicity at subduction zones: 2. Interrelationships between fore‐arc structure and seismogenic behavior

Bassett

Watts

2015

Geochem Geophys Geosyst

View full text Add to dashboard Cite

show abstract

“…The Yakataga seismic gap (south coast of Alaska between 140øW and 144øW, Figure 1), the site of collision between the north-northwestward moving Yakutat block and the North American plate, is thought to have a high potential for a major thrust earthquake within the next 20 years [McCann et al, 1980' Jacob, 1984. The gap apparently last ruptured in a sequence of great earthquakes in September 1899.…”

Section: Introductionmentioning

confidence: 99%

“…vations in the preseismic interval might then be extrapolated to suggest that the Chugach-St. Elias fault or one of the subparallel imbricate thrusts represents the greatest seismic hazard in the Yakataga seismic gap. The previous rupture of the Yakataga seismic gap (September 3, 1899[McCann et al, 1980]) is not well enough described that the causative fault can be identified. The coast at Cape Yakataga (near station Furr inFigure 4) was uplifted about 1 m at the time of that earthquake[Tarr and Martin, 1912], but no significant tsunami was reported[Cox and Pararas-Carayannis, 1976].…”

mentioning

confidence: 97%

Deformation in the Yakataga Seismic Gap, southern Alaska, 1980–1986

Savage¹,

Lisowski²

1988

J. Geophys. Res.

View full text Add to dashboard Cite

A 60‐by‐40‐km trilateration network in the Yakataga seismic gap was surveyed in 1980, 1982, 1984, and 1986 with precise electro‐optical distance‐measuring equipment to measure strain accumulation. The overall deformation is roughly approximated by a 0.24±0.03 µstrain/yr N32°W±2.4° uniaxial contraction that is uniform in time. However, the spatial distribution of deformation shows some concentration of convergence in the neighborhood of the Chugach‐St. Elias fault and of right‐lateral shear across the Contact fault. A simple dislocation model of the plate interaction in the Yakataga gap fits the observed deformation reasonably well but seems to require that the motion of the Pacific plate relative to the North American plate be directed more nearly N36°W than N15°W, the generally accepted direction of relative motion for this location. However, the direction of plate motion inferred from the dislocation model depends upon details of the interaction at the plate boundary that may not have been modeled accurately. A nearby but smaller trilateration network at Icy Bay was surveyed in 1982, 1984, and 1986. This network spans the southwest corner of the rupture zone of the 1979 St. Elias earthquake. The deformation at Icy Bay consists of left‐lateral shear across a northeast trending zone. The relation of this deformation to strain accumulation in the Yakataga gap, postseismic relaxation associated with the 1979 earthquake, or rebound from the unloading associated with the rapid recession of the Guyot glacier is not understood.

show abstract

“…The Yakataga seismic gap (Figure 1), described in detail by McCann et al [1980], has been identified as a region with a high potential for a great earthquake within the next two decades [Jacob, 1984]. The gap is bounded on the west by the rupture area of the 1964 Alaska earthquake (Mw -9.2) and on the east by the 1958 earthquake (Mw = 7.7) on the Fairweather transform fault (Figure 1).…”

Section: Introductionmentioning

confidence: 99%

“…The St. Elias earthquake (Mw = 7.6) ruptured the eastern part of the Yakataga gap in February 1979 (Figure 1). At least part of the gap was previously ruptured in the sequence of great earthquakes that occurred near Yakutat in September 1899 [McCann et al, 1980;Thatcher and Plafker, 1977].…”

Section: Introductionmentioning

confidence: 99%

Strain accumulation in the Yakataga Seismic Gap, southern Alaska

Savage¹,

Lisowski²

1986

J. Geophys. Res.

View full text Add to dashboard Cite

Strain accumulation in the Yakataga seismic gap has been estimated from the deformation of a 60 km × 40 km trilateration network surveyed in 1979–1980, 1982, and 1984. The contraction in the approximate direction (N19°W) of plate convergence is 0.19 ± 0.04 μstrain/yr, and there is a minor (0.07 ± 0.04 μstrain/yr) orthogonal extension. A significant right‐lateral shear (0.09 ± 0.02 μstrain/yr) occurs across a vertical plane striking N71°E. A simple dislocation representation of the plate interaction model proposed by Lahr and Plafker for the Yakataga seismic gap quantitatively accounts for the observed N19°W contraction and qualitatively accounts for the right‐lateral shear, the two strains being associated with the normal and transverse components, respectively, of the oblique convergence between the Yakutat block and the North American plate. The measurements are consistent with strain accumulation building up to a great thrust earthquake in the Yakataga gap. In addition, there is a suggestion of right‐lateral shear strain accumulation across the Contact fault, but the interval over which data are available is probably too short to prove such accumulation.

show abstract

Yakataga Gap, Alaska: Seismic History and Earthquake Potential

Cited by 50 publications

References 19 publications

Gravity anomalies, crustal structure, and seismicity at subduction zones: 2. Interrelationships between fore‐arc structure and seismogenic behavior

Gravity anomalies, crustal structure, and seismicity at subduction zones: 2. Interrelationships between fore‐arc structure and seismogenic behavior

Deformation in the Yakataga Seismic Gap, southern Alaska, 1980–1986

Strain accumulation in the Yakataga Seismic Gap, southern Alaska

Contact Info

Product

Resources

About