Puget Sound faults

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The Puget Sound faults under the heavily populated Puget Sound region (Puget Lowland) of Washington state form a regional complex of interrelated seismogenic (earthquake-causing) geologic faults. These include (from north to south, see map) the:

General background

Earthquake sources and hazard

The Puget Sound region (Puget Lowland[1]) of western Washington contains the bulk of the population and economic assets of the state, and carries seven percent of the international trade of the United States.[2] All this is at risk of earthquakes from three sources:[3]

  • A great subduction earthquake, such as the magnitude M 9 1700 Cascadia earthquake, caused by slippage of the entire Cascadia subduction zone, from approximately Cape Mendocino in northern California to Vancouver Island in British Columbia.
  • Intraslab (Benioff zone) earthquakes, such as the M 6.7 2001 Nisqually earthquake, caused by slippage or fracturing on a small part of the subducting plate at a depth of around 50 km (31 miles).
  • Relatively shallow crustal earthquakes, generally less than 25 km (16 miles) deep, caused by stresses and faulting in the near-surface crustal structures. The energy released depends on the length of the fault; the faults here are believed capable of generating earthquakes as great as M 6 or 7.
File:OFR 99-311 fig48.gif
Concentration of mid-crustal (10–20 km deep) seismicity in the Puget Lowland. (Fig. 48 from USGS OFR 99-311)

While the great subduction events release much energy (around magnitude 9), that energy is spread over a large area, and largely centered near the coast. The energy of the somewhat smaller Benioff earthquakes is likewise diluted over a relatively large area. The largest intra-crustal earthquakes have about the same total energy (which is about one-hundredth of a subduction event), but since they re closer to the surface they will cause more powerful shaking, and, therefore, more damage.

One study of seismic vulnerability of bridges in the Seattle – Tacoma area[4] estimated that an M 7 earthquake on the Seattle or Tacoma faults would cause nearly as much damage as a M 9 subduction earthquake. Because the Seattle and Tacoma faults run directly under the biggest concentration of population and development in the region, more damage would be expected, but all the faults reviewed here may be capable of causing severe damage locally, and disrupting the regional transportation infrastructure, including highways, railways, and pipelines. (Links with more information on various hazards can be found at Seattle Fault.)

The Puget Sound region is not just potentially seismic, it is actively seismic. Mapping from the Pacific Northwest Seismic Network shows that the bulk of the earthquakes in western Washington are concentrated in four places: in two narrow zones under Mt. Saint Helens and Mt. Rainier, along the DDMFZ, and under Puget Sound between Olympia and approximately the Southern Whidbey Island Fault.[5] The southern limit nearly matches the southern limit of the glaciation; possibly the seismicity reflects rebound of the upper crust after being stressed by the weight of the glacial ice.

Discovery

Thick glacial and other deposits, heavy vegetation, urban development, and a topography of sharp relief and rapid erosion obscures the surface expression of faults in this region, and has hindered their discovery.[6] The first definite indications of most of these faults came from gravitational mapping in 1965,[7] and their likely existence noted on mapping in 1980 and 1985.[8] As of 1985 only the Saddle Mountain Faults had been shown to have Holocene activity (since the last ice age, about 12,000 years ago).[9] Not until 1992 was the first of the lowland faults, the Seattle Fault, confirmed to be an actual fault with Holocene activity, and the barest minimum of its history established.[10]

Discovery of faults has been greatly facilitated with the development of LIDAR, a technique that can generally penetrate forest canopy and vegetation to image the actual ground surface with an unprecedented accuracy of approximately one foot (30 cm). An informal consortium of regional agencies has coordinated LIDAR mapping of much of the central Puget Lowland, which has led to discovery of numerous fault scarps which are then investigated by trenching (paleoseismology).[11] Marine seismic reflection surveys on Puget Sound where it cuts across the various faults have provided cross-sectional views of the structure of some of these faults, and an intense, wide-area combined on-shore/off-shore study in 1998 (Seismic Hazards Investigation in Puget Sound, or SHIPS)[12] resulted in a three-dimensional model of much of the subsurface geometry. Aeromagnetic surveys,[13] seismic tomography,[14] and other studies have also contributed to locating and understanding these faults.

Geological setting

File:Tectonic forces in Cascadia.png
Simplified view of tectonic forces affecting Washington. The Olympic Mountains (the lobe of grey "accretionary complex" rock sliding past the south end of Vancouver Island), having failed to subduct, are being pressed against the basement rock ("fixed block") of the North Cascades, which has been accreted on to the North American craton. This is blocking a stream of terranes that have been flowing northward in the trough above the subduction zone. As a result, Washington is crumpling in a series of folds (dotted lines show synclines and anticlines) and faults, and Oregon is rotating in a manner similar to a jack-knifing trailer. Folding has exposed patches of Crescent Formation basalt ("mafic crust", black). (USGS[15])

The ultimate driver of the stresses that cause earthquakes are the motions of the tectonic plates: material from the Earth's mantle rises at spreading centers, and moves out as plates of oceanic crust which eventually are subducted under the more buoyant plates of continental crust. Western Washington lies over the Cascadia subduction zone, where the Juan de Fuca Plate is subducting towards the east (see diagram, right). This is being obliquely overridden by the North American plate coming out of the northeast, which has formed a bend in the subducting plate and in the forearc basin above it. This bend has distorted the subducting slab into an arch that has lifted the Olympic Mountains and prevented them from subducting.[16] For the past 50 million years or so (since the early Eocene epoch) these have been thrust by subduction up against the North Cascades ("fixed block" in the diagram), which sit on the North American Plate. This forms a pocket or trough – what one local geologist calls the "big hole between the mountains"[17] – between the Cascades on the east and the Olympic Mountains and Willapa Hills on the west. This pocket is catching a stream of terranes (crustal blocks about 20 to 30 km thick[18]) which the Pacific plate is pushing up the western edge of North America, and in the process imparting a bit of clockwise rotation to southwestern Washington and most of Oregon; the result has been characterized as a train wreck.[19] These terranes were covered by the basalts of the Crescent Formation (part of Siletzia). Folding and faulting has exposed these basalts in some places (black areas in diagram); the intervening basins have been filled by various sedimentary formations, some of which have been subsequently uplifted. Glacially deposited and shaped fill covers most of the lower elevations of Puget Sound. This is the Puget Lowland. The principal effects of this complex interplay of forces on the near-surface crust underlying the Puget Lowland are:

  • The basement rock of the Crescent Formation is being forced up on the southern, eastern, and northern flanks of the Olympic Mountains, and at various folds (wrinkles).
  • Some upper-crustal formations (such as the Western and Eastern Melange Belts, see map) have been pushed onto the older (pre-Tertiary) basement of the North Cascades.
  • There is a general north or northeast directed compression within the Lowland causing folds, which eventually break to become dip-slip (vertical movement) thrust or reverse faults.
  • Some strike-slip (horizontal) movement is expected along the peripheral faults (such as Southern Whidbey Island and Saddle Mountain faults).

Further complicating this is a feature of unknown structure and origin, the Olympic-Wallowa Lineament (OWL). This is a seemingly accidental alignment of topographic features that runs roughly east-southeast from the north side of the Olympic Peninsula to the Wallowa Mountains in northeastern Oregon. It aligns with the West Coast fault and Queen Charlotte Fault system of strike-slip fault zones (similar to the San Andreas Fault in California) on the west side of Vancouver Island, but does not itself show any significant or through-going strike-slip movement. It is of interest here because the various strands of the Seattle Fault change orientation where they appear to cross the OWL,[20] and various other features, such as the Rosedale monocline and Olympia structure, and a great many local topographical features, have parallel alignments. It may also be the original location of the Darrington—Devils Mountain Fault (the dashed line "X" at the top of the following map).[21] The OWL appears to be a deep-seated structure over which the shallower crust of the Puget Lowland is being pushed, but this remains speculative.

Uplift and basin pattern

File:Puget Lowland basins and faults.png
Bouguer gravity anomaly map of the Puget Sound region showing basins and uplifts, and principal faults and folds, over outline of Puget Sound, Hood Canal, and east end of Strait of Juan de Fuca. Blue and green generally indicate basins (with lower density sedimentary rock), red is generally uplifted basalt of the Crescent Formation. Unlabeled lines northwest of Everet Basin = Strawberry Point & Utsalady Point faults; E-F = Seattle Fault zone; C-D = Tacoma Fault zone; A = Olympia Fault; Doty Fault is east-west dashed line just north of Chehalis Basin; curved dashed line = Hood Canal Fault; Dewatto Lineament (western flank of Seattle uplift) runs south from "D", Saddle Mountain Faults are due west. (Modified from Pratt et al. 1997, plate 1.) Aeromagnetic anomalies are generally conformable.[22]

Most of these "faults" are actually zones of complex faulting at the boundaries between sedimentary basins (synclines) and crustal uplifts (anticlines). There is a general pattern where most of these faults partition a series of basins and uplifts, each about 20 km wide. From the north these are (see the map at right):

  • Devils Mountain Fault zone (including Strawberry Point and Utsalady Point faults)
∪ Everett Basin
  • Southern Whidbey Island Fault (SWIF)
∩ "Uplift of unknown origin" (Port Ludlow)
  • Kingston arch (Lofall Fault[23])
∪ Seattle Basin
  • Seattle Fault zone (approx. lines E-F)
∩ Seattle Uplift
  • Tacoma Fault Zone (approx. line C)
∪ Tacoma Basin
  • Olympia fault (approx. line A)
∩ Black Hills Uplift
  • Doty Fault / Scammon Creek Fault (dashed lines)[24]
∪ Chehalis Basin

The Hood Canal Fault (and its possible extensions) and Saddle Mountain faults to the west are believed to form the western boundary to all this. On the east, the Devils Mountain Fault connects with the south striking Darrington Fault (not shown) which runs to the OWL, and the Southern Whidbey Island Fault extends via the Rattlesnake Mountain Fault Zone (dashed line) to the OWL. South of the OWL a definite eastern boundary has not been found, with some indications it is indefinite. (E.g., the Olympia Fault is aligned with and appears to be the northernmost member of a set of faults between Olympia and Chehalis that may extend to the Columbia River, and there has been a suggestion that the Tacoma Fault may connect with the White River—Naches River fault on the east side of the Cascades.[25])

The uplift and basin pattern is continued to the west and southwest by the Grays Harbor Basin, Willapa Hills Uplift, and Astoria Basin,[26] but it is not known if these are bounded by faults in the same manner as in the Puget Sound region.

Structural models

Thrust sheet hypothesis

It is believed that all of these faults, folds, basins, and uplifts are related. According to the preeminent model, the "Puget Lowland thrust sheet hypothesis",[27] these faults, etc., occur within a sheet of crust about 14 to 20 km deep that has separated from and is being thrust over deeper crustal blocks. Most of this thrust sheet consists of the Crescent Formation (corresponding to the Siletz River volcanics in Oregon and Metchosin Formation on Vancouver Island), a vast outpouring of volcanic basalt from the Eocene epoch (about 50 million years ago), with an origin variously attributed to a seamount chain, or continental margin rifting (see Siletzia).[28] This "basement" rock is covered with sedimentary deposits similar to the Chuckanut Formation, and more recent (typically Miocene) volcanic deposits. The Seattle uplift, and possibly the Black Hills uplift, consist of Crescent Formation basalt that was exposed when it was forced up a ramp of some kind. This ramp could be either in the lower crustal blocks, or where the thrust sheet has split and one part is being forced over the next.[29] Faults and folds may develop where the thrust sheet is being bent, or where the leading edge is thrust over softer, weaker sedimentary deposits, and breaks off and slumps.

If, as this model suggests, the various faults are interconnected within the thrust sheet, there is a possibility that one earthquake could trigger others.[30] This prospect is especially intriguing as a possible explanation of a cluster of seismic events around 1100 years ago.[31]

Seismotectonic modeling

In the previous study seismicity, surface geology, and geophysical data were modeled in order to examine the fault structuring of the upper crust. Another model (of Stanley, Villaseñor & Benz 1999, USGS Open-File Report 99-0311) – not so much in competition with the first as complementing it – used seismic and other data to create a 3-D tectonic model of the whole crust; this was then analyzed using finite element methods to determine regional geodynamic characteristics.

A principal finding is that "[c]rustal seismicity in the southern Puget Sound region appears to be controlled by a key block of Crescent Formation occurring just south of the Seattle fault."[32] More particularly, the concentration of seismicity under Puget Sound south of the Seattle Fault is attributed to uplift of that block, bounded by the Seattle, Tacoma, and Dewatto faults on the north, south, and west (the eastern boundary is not determined), creating the Seattle Uplift.[33] And it is suggested that the Great Seattle Quake of approximately 1,100 years ago, and other coseismic events in southern Puget Sound around that time, were a single event that affected this entire block, with a magnitude of around 8, possibly triggered by an earthquake deeper in the crust.[34]

Very little is known about the structure of the deep crust (below about 30 km or 19 miles), though this and other seismic tomography studies (such as Ramachandran 2001) provide tantalizing glimpses.

For the following reviews the primary source of information is the U.S. Geological Survey's Quaternary fault and fold database (QFFDB), which includes details of discovery, a technical description, and bibliography for each fault; a specific link is provided (where available) at the end of each section.

Devils Mountain Fault

File:Straight Creek Fault.gif
Puget Lowland and other areas divided from the "North Cascade Crystalline Core" by the Straight Creek Fault. The green colored area on the left has been pushed north, the purple area ("HH Melange") on the Darrington—Devils Mountain Fault originally being at or southwest of the Olympic Wallowa Lineament. (Fig. 1 from USGS I-2538, modified.)

The Devils Mountain Fault (DMF) runs about 125 km (75 miles) from the town of Darrington in the Cascade foothills due west to the northern tip of Whidbey Island, and on towards Victoria, British Columbia, where the DMF is believed to join the Leech River fault system at the southern end of Vancouver Island. At Darrington it is seen to connect with the Darrington Fault, which runs nearly south 110 km to converge with the Straight Creek Fault (SCF), and then to turn near Easton to align with the Olympic-Wallowa Lineament; together these are known as the Darrington—Devils Mountain Fault Zone (DDMFZ).

The Devils Mountain Fault separates two similar but distinctive ensembles of Mesozoic (pre-Tertiary, before the dinosaurs died) or older rock. On the north is the Helena—Haystack mélange (HH mélange, purple in the diagram at right), on the south the Western and Eastern mélange belts (WEMB, blue). There are some interesting relationships here. E.g., HH mélange rock has been found in Manastash Ridge, 110 km to the south (look for the small sliver of purple near the bottom of the diagram). Also, the sedimentary Chuckanut Formation (part of the NWCS, green) north of the DMF correlates to the Suak and Roslyn Formations just north of Manastash Ridge. All this is explained by right-lateral strike-slip motion on the Straight Creek Fault, which initiated about 50 to 48 Ma (millions of years ago). This is just after the terrane carrying the Olympic Mountains came into contact with the North American continent. These mélanges may have been off-shore islands or seamounts that were caught between the Olympic terrane and the North American continent, and were pushed up (obducted) onto the latter. Other similar rock has been found at the Rimrock Lake Inlier (bottom of diagram), in the San Juan Islands, and in the Pacific Coast Complex along the West Coast Fault on the west side of Vancouver Island. It appears the entire DDMFZ and Leech River fault system was pushed onto the early continental margin from an original alignment along the OWL. This is an important observation because the Strawberry Point, Utsalady Point, Southern Whidbey Island, and various other unnamed faults lying between the DDMFZ and the OWL – all of which converge at the western end of the DDMFZ – seem to be intermediate versions of the DDMFZ.[35]

Movement on the southern segment of the DDMFZ that converges with the SCF – the Darrington Fault – was, as on the SCF itself, right-lateral. And like the SCF, strike-slip motion died out between 44 and 41 MA (due to plutonic intrusions). But the western segment – the Devils Mountain Fault – has left-lateral movement. This is because the Olympic terrane is moving (relative to North America) northeast; its continued clockwise rotation is akin to a giant wheel rolling up the western side of the North Cascade crystalline core. The geology also suggests that the DMF is moving obliquely up a ramp that rises to the east,[36] possibly an ancient coastal shore.

The Devils Mountain Fault is seismically active, and there is evidence of Holocene offsets. If the entire 125 km length ruptured in a single event the resulting earthquake could be as large as magnitude 7.5. However, there are indications that the fault is segmented, which might limit rupturing and earthquake magnitude.[37]

Strawberry Point and Utsalady Point faults

Strands of the east-striking Devils Mountain Fault cross the northern tip of Whidbey Island at Dugualla Bay and north side of Ault Field (Whidbey Island Naval Air Station). Just four miles (6 km) south the city of Oak Harbor straddles several stands of the Utsalady Point Fault (UPF) as they head roughly east-southeast towards Utsalady Point at the north end of Camano Island. And in between these two the Strawberry Point Fault (SPF) skirts the south side of Ault Field, splits into various strands that bracket Strawberry Point, and then disappear (possibly ending) under the delta of the Skagit River. Both the SPF and UPF are said to be oblique-slip transpressional; that is, the faults show both horizontal and vertical slip as the crustal blocks are pressed together. These faults also form the north and south boundaries of uplifted pre-Tertiary rock, suggesting that the faults come together at a lower level, much like one model of the Seattle and Tacoma faults, but at a smaller scale. Marine seismic reflection surveys on either side of Whidbey Island extend the known length of these faults to at least 26 and 28 km (about 15 miles). The true length of the UPF is likely twice as long, as it forms the southern margin of an aeromagnetic high that extends another 25 km to the southeast.[38] Trenching on the UPF (at a scarp identified by LIDAR) shows at least one and probably two Holocene earthquakes of magnitude 6.7 or more, the most recent one between AD 1550 to 1850, and possibly triggered by the 1700 Cascadia earthquake.[39] These earthquakes probably caused tsunamis, and several nearby locations have evidence of tsunamis not correlated with other known quakes.

While there is a bit of uplifted pre-Tertiary rock between the SPF and UPF, this does not truly fit the uplift and basin pattern described above because of the small scale (2 km wide rather than around 20), and because the uplift here is entirely like a wedge being popped out between two nearly vertical faults, rather than being forced over a ramp such as is involved with the Seattle and Tacoma faults. Nor does this uplift delineate any significant basin between it and the Devils Mountain Fault.[40] On the basis of marine seismic reflection surveying in the Strait of Juan de Fuca it has been suggested that the DMF, SPF, and UPF are structurally connected (at least in the segment crossing Whidbey Island).[41]

Southern Whidbey Island Fault

File:Southern Whidbey Island fault-1.png
Location and known extent (prior to 2004) of Southern Whidbey Island Fault (SWIF). Also shown: Devils Mountain, Strawberry Point, and Utsalady Point faults (crossing northern Whidbey Island), Seattle Fault zone, southern part of Rattlesnake Mountain Fault Zone, Tokul Creek Fault (striking NNE from RMFZ). This map is approximately one-quarter the scale of the map below. (USGS[42])

The Southern Whidbey Island Fault (SWIF) is a significant terrane boundary manifested as an approximately four mile wide zone of complex transpressional faulting with at least three strands.[43] Marine seismic reflection surveys show it striking northwest across the eastern end of the Strait of Juan de Fuca.[44] Just south of Victoria, British Columbia it intersects the west-striking Devils Mountain Fault (reviewed above), and either merges with it,[45] or crosses (and possibly truncates) it to connect with the Leech River Fault.[46] The Leech River Fault has been identified as the northern edge of the Crescent Formation (aka Metchosin Formation, part of the Siletzia terrane that underlies much of western Washington and Oregon).[47] Seismic tomography studies show that this portion of the SWIF marks a strong contrast of seismic velocities, such as is expected of Crescent Formation basalts in contact with the metamorphic basement rocks of the Cascades geologic province to the east.[48]

To the southeast the SWIF passes through Admiralty Inlet (past Port Townsend) and across the southern part of Whidbey Island, crossing to the mainland between Mukilteo and Edmonds. This section of the SWIF forms the southwestern side of the Everett Basin[49] (see map), which is notably aseismic in that essentially no shallow (less than 12 km deep) earthquakes have occurred there, or on the section of the SWIF adjoining it, in the first 38 years of instrumental recording.[50] Yet it is also notable that "most seismicity in the northern Puget Sound occurs along and southwest of the southern Whidbey Island fault at typical depths of 15–27 km within the lower part of the Crescent Formation."[51]

The contrast of seismic velocities seen to the northwest is lacking in this section, suggesting that it is not the Coast Range—Cascade contact.[52] The significance of this — whether the edge of the Crescent Formation (and implicitly of the Siletz terrane) turns southward (discussed below), or the metamorphic basement is supplanted here by other volcanic rock — is not known. It has been suggested that a corresponding change in the character of the SWIF may reflect a change in the direction of regional crustal strain.[53] Prior to 2000 prominent aeromagnetic anomalies strongly suggested that the fault zone continued southeast, perhaps as far as the town of Duvall, but this was uncertain as the SWIF is largely concealed, and the faint surface traces generally obliterated by urban development. Since 2000 studies of LIDAR and high-resolution aeromagnetic data have identified scarps near Woodinville which trenching has confirmed to be tectonically derived and geologically recent.[54]

Subsequent mapping shows the SWIF wrapping around the eastern end of the Seattle Basin to merge with the Rattlesnake Mountain Fault Zone (RMFZ); the RMFZ, despite the approximately 15° bend and different context, is now believed to be the southern extension of the SWIF.[55] Reckoned between Victoria and approximately Fall City the length of the SWIF is around 150 km (90 miles).[56]

It has been suggested that the SWIF might extend past its intersection with the RMFZ (with only peripheral strands turning to join the RMFZ) to cross the Cascades and eventually merge with or cross the Olympic-Wallowa Lineament;[57] a study of regional features suggests such a pattern.[58] But detailed mapping just past the intersection shows only a complex and confused pattern of faulting, with no indication that there is, or is not, through-going faulting.[59] Mapping of areas further east that might clarify the pattern is not currently planned.[60]

Paleoseismological studies of the SWIF are scant. One study compared the relative elevation of two marshes on opposite sides of Whidbey Island, and determined that approximately 3,000 years ago an earthquake of M 6.5—7.0 caused 1 to 2 meters of uplift.[61] Another study identified an unusually broad band of scarps passing between Bothell and Snohomish, with several scarps in the vicinity of King County's controversial Brightwater regional sewage treatment plant showing at least four and possibly nine events on the SWIF in the last 16,400 years.[62] Such seismic hazards were a major issue in the siting of the plant, as it is tucked between two active strands, and the influent and effluent pipelines cross multiple zones of disturbed ground.[63]

Rattlesnake Mountain Fault Zone

File:Snoqualmie Valley faults.png
Simplified geologic map of the Snoqualmie Valley (east of Seattle) from North Bend to Duvall, showing various strands of the Rattlesnake Mountain Fault (RMF), and the Snoqualmie Valley (SVF), Griffin Creek (GCF), and Tokul Creek (TCF) faults. The stream NNE of Carnation lies in the Cherry Creek Fault Zone. Southeastern limit of Southern Whidbey Island Fault at Duvall (3), other faults south of I-90 not shown. Tiger Mountain is the uplifted "Evc" formations southeast of Issaquah, between I-90 and Hwy. 18. (Figure 2 from DGER Geological Map GM-73)

Rattlesnake Mountain is a prominent NNW trending ridge just west of North Bend (about 25 miles east of Seattle). It is coincident with, and possibly a result of uplift on, the Rattlesnake Mountain Fault Zone (RMFZ), a band of at least eleven faults that show both dip-slip (vertical) and right-lateral strike-slip motion.[64] (See the adjacent map. In the map above these are represented by the pair of dotted lines at the lower right. A different mountain and fault zone of the same name are located near Pasco; see QFFDB Fault #565)

The southern end of Rattlesnake Mountain is truncated at the Olympic-Wallowa Lineament (OWL), and the faults turn easterly to merge with the OWL.[65] The northern end of the mountain falls off where it crosses the eastern end of the Seattle Fault, which in turn terminates at the RMFZ; Rattlesnake Mountain forms the eastern edge of the Seattle Uplift.[66]

The RMFZ continues NNW past Fall City and Carnation, where strands of the RMFZ have been mapped making a gentle turn of 15 to 20° west to meet the Southern Whidbey Island Fault zone (SWIF, discussed above); the RMFZ is therefore considered to be an extension of the SWIF.[67] The relationship between these two fault zones is not entirely clear. Slippage along the SWIF would be expected to continue east-southeast until it merged with the OWL, but instead appears to be taking a shortcut ("right step") along the RMFZ.[68] This is where the SWIF encounters the edge of the Western and Eastern Melange Belts (remnants of a mid-Cretaceous subduction zone[69]); the RMFZ is where the Seattle Uplift is being forced against the Western Melange belt[70]

To the north the Melange Belt is manifested as the Rogers Belt, a zone of low-amplitude folding stretching from Monroe to Mount Vernon; the apparent western edge of this zone is on-strike with the RMFZ. South of Monroe the folds of the Rogers Belt are obscured by subsequent volcanic formations, but other faults parallel to the RMFZ (e.g., the Snoqualmie Valley and Johnson's Swamp fault zones) extend the general trend of NNW faulting as far as Monroe.[71]

    (Rattlesnake Mountain Fault Zone not included in QFFDB.)

Coast Range Boundary Fault

The Coast Range Boundary Fault (CRBF) is hypothesized, expected on the basis of tectonic considerations, which may correlate in part with one or more currently known faults, or may involve as yet undiscovered faulting. Simply put, the basement rock on the west side of Puget Sound does not match the basement rock on the east side. West of Puget Sound the tectonic basement of the Coast Range geologic province is the approximately 50 million year (Ma) old marine basalts of the Crescent Formation, part of the Siletzia terrane that underlies western Washington and Oregon. East of Puget Sound the basement of the Cascades province is various pre-Tertiary (older than 65 Ma) metamorphic rock. Somewhere between Puget Sound and Cascades foothills these two geological provinces come into contact.[72] As the juxtaposition of various disparate tectonic structures in northwest Washington requires significant strike-slip movement, it is further expected that this contact will be a major fault.[73]

The northern end of the Crescent Formation (aka Metchosin Formation) has been identified as the east-west trending Leech River Fault on the southern tip of Vancouver Island.[74] This turns and runs just south of Victoria, nearly in-line with the SWIF. Seismic tomography studies show a change in seismic velocities across the northern end of the SWIF, suggesting that this is also part of the Coast Range—Cascade contact. It therefore seems reasonable that the rest of the SWIF (and its apparent extension, the RMFZ) follows the Coast Range—Cascade contact, and (these faults being active) constitutes the CRBF.

One problem with this is that the parts of the SWIF east of Puget Sound do not show the velocity contrasts that would indicate contrasting rock types.[75] Another problem with the SWIF/RMFZ as CRBF is that a large westward step is required to connect from the RMFZ to the Saint Helens Zone (SHZ; see map), whereas the RMFZ turns easterly to align with the OWL.[76] This last problem is partly solved because there is a locus of seismicity, and presumably faulting, extending from the northern end of the SHZ to the northern end of the Western Rainier Zone (see Fig. 48), along the edge of a formation known as the Southern Washington Cascades Conductor.[77]

However, gravity and other data suggest that near the southern tip of Whidbey Island the Crescent Formation contact may turn away from the SWIF, and may even be reentrant under north Seattle,[78] forming the northwestern side of the Seattle Basin, and possibly connecting with the recently reported "Bremerton trend" of faulting running from the southern end of Hood Canal, through Sinclair Inlet (Bremerton), and across Puget Sound.[79] Or the Crescent margin may simply (and quietly) just run south-southeast under Seattle to the WRZ.[80] Other seismic tomography has tantalizingly suggested three north-striking strands under Seattle, and a fourth just east of Lake Washington.[81] Although there is no direct evidence for any major north-striking faults under Seattle, this prospect appears to be endorsed by the geological community.[82]

How the CRBF might run north of Seattle (specifically, north of the OWL, which Seattle straddles) is unknown, and even questioned, as there is no direct evidence of such a fault.[83] There is an intriguing view from Stanley, Villaseñor & Benz (1999) (see Fig. 64, on-line) that the edge of the Crescent Formation offsets west along the Seattle Fault, with the Seattle Basin resulting from a gap between the main part of Siletiza and a northern block that has broken away.

Cherry Creek Fault Zone

The Cherry Creek fault zone (CCFZ) was discovered in 2010 while mapping the area at the north end of the Rattlesnake Mountain fault zone (RMFZ).[84] From a point just north of Carnation the eastern edge of the CCFZ (here it is about three-quarters of a mile wide) can be traced up Harris Creek, crossing the upper reach of Cherry Creek, eventually reaching the town of Sultan. Here the main strand on the western edge merges with the Sultan River Fault under the Sultan River.[85] It is projected to extend past Lake Chaplain, and perhaps to the east end of Mount Pilchuck.[86] It is deemed a "major active or potentially active" structure.[87]

In the crowded field of active or potentially active fault zones that have been discovered in the lower Snoqualmie Valley, the Cherry Creek fault zone is particularly notable because east of Duvall[88] it passes through a hotspot of active seismicity, including the 1996 ML 5.3 Duvall earthquake.[89] Offsets in the east-west oriented Monroe Fault (south side of the Skykomish River), earthquake focal mechanisms, and kinematic indications show that the CCFZ is a left-lateral strike-slip fault, possibly with some oblique motion (up on the eastern side).[90]

The CCFZ appears to be related to the parallel Tokul Creek fault zone to the south; both appear to be conjugate faults[91] to the northwest-trending SWIF.[92] The Tokul Creek Fault (TCF) strikes NNE from Snoqualmie, aligned with a possible offset of the Western Melange Belt[93] and with a valley that cuts through to the Skykomish River; it is now believed to be of regional significance.[94]

Rogers Belt

In the northeast corner of the Puget Lowland, running from approximately Sultan (just east of Monroe) to a point on the Devils Mountain Fault (DMF) just short of Mount Vernon, is a belt about 15 miles wide of strikingly parallel drainages, indicating a strong albeit subdued pattern of topographical folding.[95] Observing this, some parallel gravity gradients, and a "very active zone of minor seismicity", William Rogers inferred a "fault or other major structural feature".[96] This feature is the Western Melange Belt (part of the blue area in the map above), metamorphosed sediments that accumulated in a Late Jurassic—Cretaceous oceanic trench.[97]

The Bellingham Bay—Chaplain fault zone was first mapped by Cheney in 1976 as running from near Chaplain Lake (north of Sultan) NNW past Bellingham Bay. Doubts on the connectivity of these faults led to abandonment of this name in 1986[98] when Cheney mapped the Mount Vernon fault (MVF) from near Sultan northwest past Lummi Island (west side of Bellingham Bay, visible at the top of the map), crossing the Devils Mountain Fault (DMF, part of the Darrington—Devils Mountain Fault Zone) near Mount Vernon. South of the DMF Cheney also mapped the Lake Chaplain Fault, parallel and just east of the MVF, from Granite Falls to Lake Chaplain.

In the 2014 mapping of the Lake Chaplain Quadrangle[99] the Woods Lake Fault corresponds closest to the mapped position of the southern end of Cheney's Mount Vernon Fault.[100] However, the Woods Creek Fault (WCF) just to the west, striking 330° from Sultan to the southern tip of Lake Roesiger, appears to be the more significant fault, and better aligned with Mount Vernon. The Lake Chaplain Fault is shown as an oblique-slip fault (right-lateral strike-slip movement that drops on the east side) that impinges the northeastern corner of Lake Chaplain, then turns south to merge with the Woods Lake Fault at Woods Lake. The Lake Chaplain Thrust Fault continues on-strike to the SSE, bracketing the southern portion of the lake. All of these faults appear to terminate against the left-lateral NNE striking Sultan River Fault at the western margin of the Cherry Creek Fault Zone (CCFZ).[101]

Mapping in 2006 revealed the right-lateral McMurray Fault Zone (MFZ) just south of the DMF near Lake McMurray, suspected of being a major bounding fault.[102] This is located on a topographical lineament that aligns with Mount Vernon to the north and the Woods Creek Fault to the south. Additional faulting was found that indicates a broad zone of faulting, similar to what has been found north of Sultan. The interaction of the MFZ and adjacent Mount Washington Fault Zone with the DMF is complex, with hints of northward extensions; the geological structure to the north has yet to be adequately mapped.

The strongly expressed topographical lineaments of the Rogers Belt pose a perplexing problem, as they show no definite offset where they are bisected by the left-lateral oblique-slip Devils Mountain Fault. The alternative, that younger faulting in the Rogers Belt has offset the DMF — Cheney argued that the MVF had offset the DMF 47 km. to the north, past Lummi Island — is contrary to the prevailing consensus that the DMF is not offset.[103] A similar situation occurs in the south where topographical lineaments and faulting appear to align across the Cherry Creek Fault Zone.

Seattle Fault

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Main article: Seattle Fault

The Seattle Fault is a zone of complex thrust and reverse faults – between lines E and F on the map – up to 7 km wide and over 70 km long that delineates the north edge of the Seattle Uplift. It stands out in regard of its east-west orientation, depth to bedrock, and hazard to an urban population center.[104] It is the most studied fault in the region; it will be treated in somewhat greater detail.

File:Seattle Fault location.png
Approximate location of the Seattle Fault, showing eastern junction with SWIF and RMFZ. Western extension uncertain past Blue Hills uplift (marked "OP"). (Excerpt from DGER Geological Map GM-52.)

The Seattle Fault was first identified in 1965[105] but not documented as an active fault until 1992 with a set of five articles establishing that about 1100 years ago (AD 900—930) an earthquake of magnitude 7+ uplifted Restoration Point and Alki Point, dropped West Point (the three white triangles in the Seattle Basin on the map), caused rockslides in the Olympics, landslides into Lake Washington, and a tsunami on Puget Sound.[106] It extends as far east as (and probably terminates at) the Rattlesnake Mountain Fault Zone (RMFZ; the southern extension of the SWIF) near Fall City. This seems geologically reasonable, as both the SWIF and RMFZ appear to be the contact between Tertiary Crescent Formation basement of Puget Sound on the west and the older Mesozoic (pre-Tertiary) mélange belt basement rocks under the Cascades on the east.[107]

Structure

File:Seattle uplift 17D.png
Cross-section of one model of the Seattle uplift. Models differ on the nature of the ramp and details of the faults. (From Johnson et al. 2004a, figure 17D.)

The Seattle Fault is the most studied of the regional faults, which has led to several models of its structure, which may also be relevant to other faults. In the wedge model of Pratt et al. (1997) a slab of rock – mainly basalts of the Crescent Formation – about 20 km thick is being pushed up a "master ramp" of deeper material; this forms the Seattle Uplift. The Seattle fault zone is where the forward edge of the slab, coming to the top of the ramp, breaks and slips into the Seattle Basin. In this model the Tacoma fault zone is primarily the result of local adjustments as the slab bends upward at the bottom of the ramp.

The passive roof duplex model of Brocher et al. (2001),[108] relying on seismic tomography data from the "Seismic Hazards Investigation in Puget Sound" (SHIPS) experiment, retains the thrusting slab and master ramp concepts, but interprets the Tacoma fault as a reverse fault (or back thrust) that dips north towards the south dipping Seattle fault (see diagram); as a result the Seattle Uplift is being popped up like a horst.

While these models vary in some details, both indicate that the Seattle Fault itself is capable of a magnitude 7.5 earthquake.[109] But if the Seattle Fault should break in conjunction with other faults (discussed above), considerably more energy would be released, on the order of ~M 8.[110]

Question of western termination

Determination of the western terminus of the Seattle Fault has been problematic, and has implications for the entire west side of the Puget Lowland. Initially it was not specified, and rather vaguely indicated to be west of Restoration Point (i.e., west of Puget Sound).[111] An early view was that "the Seattle Fault appears to be truncated by the Hood Canal fault ... and does not extend into the Olympic Mountains".[112] This seems reasonable enough, as Hood Canal is a prominent physiographic boundary between the Olympic Mountains and Puget Lowlands, and believed to be the location of a major fault.[113] Subsequent authors were confident enough to trace the fault west of Bremerton to just north of Green Mountain (the northwestern corner of the Blue Hills uplift – see "E" on the map – a topographically prominent exposure of uplifted basalt) and just short of Hood Canal;[114] but reluctant to map the fault further west as the distinctive aeromagnetic lineament used to locate the Seattle Fault dies out just west of Bremerton.[115]

Studies of the Seattle Fault west of Bremerton have revealed a complexity of geological structure and faulting.[116] Several studies show that the southernmost strand of the SF, once past Green Mountain, turns southwest, towards the Saddle Mountain and Frigid Creek faults.[117] However, the Saddle Mountain fault zone is not quite reciprocally aligned,[118] trending more northerly to where it encounters west-east trending faults (including the Hamma Hamma fault zone) that appear to be a westward extension of the Seattle Fault zone.[119] This trend extends further north where the Pleasant Harbor lineament appears to terminate other westward extensions of the SFZ.[120] Other studies have faults extending NW or WNW from the SF towards Dabob Bay;[121] these are now recognized as part of the Dabob Bay fault zone.[122] While some coherency is developing, the story is not complete: identified faults do not yet account for much of the region's seismicity.[123]

An emerging view is that the Dewatto fault marks the western edge of the relatively rigid Seattle Uplift (see map). Accommodation of strain (displacement) between the Seattle Fault and the Saddle Mountain deformation zone is likely distributed across the more pliable sediments of the Dewatto Basin; this, and the greater depth to the Crescent Formation, may account for the subdued expression of the Seattle Fault west of Green Mountain.[124]

Tacoma Fault Zone

File:Tacoma fault zone.png
Tacoma fault zone, with multiple southeast-striking strands, and part of the Olympia fault.(USGS[125])

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Main article: Tacoma Fault

The Tacoma Fault (at right, and also between lines C and D on the Uplift and basin map, above) just north of the city of Tacoma, Washington has been described as "one of the most striking geophysical anomalies in the Puget Lowland".[126] The western part is an active east–west striking north dipping reverse fault that separates the Seattle Uplift and the Tacoma Basin, with approximately 30 miles (50 km) of identified surface rupture. It is believed capable of generating earthquakes of at least magnitude 7, and there is evidence of such a quake approximately 1,000 years ago, possibly the same earthquake documented on the Seattle Fault 24 miles (38 km) to the north.[127] This is likely not coincidental, as it appears that the Tacoma and Seattle faults converge at depth (see diagram above) in a way that north-south compression tends to force the Seattle Uplift up, resulting in dip-slip movement on both fault zones.[128]

The Tacoma Fault was first identified by Gower, Yount & Crosson (1985) as a gravitational anomaly ("structure K") running east across the northern tip of Case and Carr Inlets, then southeast under Commencement Bay and towards the town of Puyallup. Not until 2001 was it identified as a fault zone,[129] and only in 2004 did trenching reveal Holocene activity.[130]

Interpretation of the eastern part of the Tacoma Fault is not entirely settled.[131] Most authors align it with the strong gravitational anomaly (which typically reflects where faulting has juxtaposed rock of different density) and topographical lineament down Commencement Bay. This follows the front of the Rosedale monocline, a gently southwest-tilting formation that forms the bluffs on which Tacoma is built.

On the other hand, the contrasting character of the east-striking and southeast-striking segments is unsettling, and the change of direction somewhat difficult to reconcile with the observed fault traces. Especially as seismic reflection data[132] shows some faulting continuing east across Vashon Island and the East Passage of Puget Sound (the East Passage Zone, EPZ) towards Federal Way and an east-striking anticline. Whether the faulting continues eastward is not yet determined. The EPZ is active, being the locale of the 1995 M 5 Point Robinson earthquake.[133]

There is evidence that the Tacoma Fault connects with the White River River Fault (WRF) via the EPZ and Federal Way, under the Muckleshoot Basin (see map),[134] and thence to the Naches River Fault. If so, this would be a major fault system (over 185 km long), connecting the Puget Lowland with the Yakima Fold Belt on the other side of the Cascades, with possible implications for both the Olympic—Wallowa Lineament (which it parallels) and geological structure south of the OWL.

File:Tacoma Fault and Basin.png
Excerpt from Bouguer gravity anomaly map (above), showing approximate locations of the Seattle Fault zone (line E), Seattle Uplift (red, and adjoining yellow border), parts of the Tacoma Fault Zone (green; the pair of green lines mark the Rosedale Monocline), Tacoma Basin (light blue), Dewatto Basin (northwestern portion of Tacoma Basin at C), Dewatto lineament/fault (vertical black bar at D), city of Belfair at white triangle.

Scarps associated with Holocene uplift of the Tacoma fault have been traced westward to Prickett Lake (southwest of Belfair, see map).[135] The Tacoma fault was initially suspected of following a weak magnetic anomaly west to the Frigid Creek fault,[136] but is now believed to connect with a steep gravitational, aeromagnetic, and seismic velocity gradient that strikes north towards Green Mountain (Blue Hills uplift). This is the Dewatto lineament, believed to result from an east-dipping low-angle thrust fault where the western flank of the Seattle Uplift has been pushed into the northwestern corner of the Tacoma Basin. It appears that the Seattle Uplift is acting as a rigid block, with the Tacoma, Dewatto, and Seattle faults being the southern, western, and northern faces. This may explain why the Seattle and Tacoma faults seem to have ruptured at nearly the same time.[137]

Dewatto Lineament

The western flank of the Seattle Uplift forms a strong gravitational, aeromagnetic, and seismic velocity gradient known as the Dewatto lineament.[138] It arises from the contrast between the denser and more magnetic basalt of the Crescent Formation that has been uplifted to the east, and the glacial sediments that have filled the Dewatto basin to the west.[139] The Dewatto linement extends from the western end of the Tacoma fault (see map immediately above) northward towards Green Mountain at the western end of the Seattle fault.

Kinematic analysis suggests that if shortening (compression) in the Puget Lowland is directed to the northeast (i.e., parallel to Hood Canal and the Saddle Mountain deformation zone) and thus oblique to the Dewatto lineament, it should be subject to both strike-slip and dip-slip forces, implying a fault.[140] Recent geophysical modeling suggests that the Dewatto lineament is the expression of a blind (concealed), low-angle, east-dipping thrust fault, named the Dewatto fault.[141] (Originally named the Tahuya Fault.[142]) This reflects westward thrusting of the Seattle Uplift into the Dewatto basin, a northwestern extension of the Tacoma basin. This interpretation suggests that the Seattle Uplift acts as a rigid block, and possibly explains the kinematic linkage by which large earthquakes may involve ruptures on multiple faults: the Seattle, Dewatto, and Tacoma faults represent the northern, western, and southern faces of a single block.[143] Such interconnection also suggests a capability for larger earthquakes (> M 7 for the Seattle Fault); the amount of increased risk is unknown.[144]

Hood Canal Fault

File:Hood Canal fault.png
Excerpt from main map showing the putative Hood Canal Fault (dashed line) running up Hood Canal and Dabob Bay, the Dabob Bay Fault Zone (DBFZ), Saddle Mountain faults (SM), and western end of the Seattle Fault zone (approximate).

Hood Canal marks an abrupt change of physiography between the Puget Lowland and the Olympic Mountains to the west. Based on this and geophysical anomalies it was inferred that there is a major, active strike-slip fault zone running from the south end of Hood Canal, up Dabob Bay, and continuing north on land.[145] This is conformable with some regional tectonic interpretations[146] that put a major terrane boundary between the Olympics and the Puget Lowland, and imply a connection (either via the Discovery Bay Fault, or closer to Port Townsend) to the various faults in the Strait of Juan de Fuca. This boundary would be the contact where northward movement of the basement rock of the Puget Lowland against the Olympic Peninsula is accommodated; it would be expected to be a significant seismological zone.

However, the Hood Canal fault has been "largely inferred"[147] due to a paucity of evidence, including lack of definite scarps and any other signs of active seismicity. A 2001 study[148] using high-resolution seismic tomography questioned its existence. Though a recent study[149] interpreted a different variety of tomographic data as showing the Hood Canal fault, other mapping has "found no convincing evidence for the existence of this fault",[150] considers it doubtful,[151] depicted it "with low level of confidence",[152] or omits it entirely.[153] For these reasons this is now a questioned fault, and is indicated on the map as a dashed line.

A new view is developing that the regional tectonic boundary is not under Hood Canal, but just to the west, involving the Saddle Mountain fault zone (discussed below) and associated faults. This is supported by geologically recent scarps and other signs of active faulting on the Saddle Mountain faults, and also discovery of a geophysical lineament running through Pleasant Harbor (south of Brinnon) that appears to truncate strands of the Seattle Fault.[154] In this view Hood Canal is only a syncline (dip) between the Olympic Mountains and the Puget Lowland, and such faults as have been found there are local and discontinuous, ancillary to the main zone of faulting to the west.[155] North of the Seattle Fault accommodation of regional movement may be along the newly discovered northwest-striking Dabob Bay Fault Zone.[156]

Saddle Mountain Faults

File:Saddle Mountain faults.png
In red: Saddle Mountain faults (west and east) extension to the southwest inferred from aeromagnetic and LIDAR evidence, Dow Mountain fault (offset by SM east), and Frigid Creek fault.

The Saddle Mountain Faults ("East" and "West", and not to be confused with a different Saddle Mountains Fault in Adams county, eastern Washington[157]), are a set of northeast trending reverse faults on the south-east flank of the Olympic Mountains near Lake Cushman first described in 1973 and 1975.[158] Vertical movement on these faults has created prominent scarps that have dammed Price Lake and (just north of Saddle Mountain) Lilliwaup Swamp. The mapped surface traces are only 5 km long, but LIDAR-derived imagery shows longer lineaments, with the traces cutting Holocene alluvial traces. A recent (2009) analysis of aeromagnetic data[159] suggests that it extends at least 35 km, from the latitude of the Seattle Fault (the Hamma Hamma River) to about 6 km south of Lake Cushman. Other faults to the south and southeast – the Frigid Creek Fault and (to the west) Canyon River Fault – suggest an extended zone of faulting at least 45 km long. Although the southwest striking Canyon River Fault is not seen to directly connect with the Saddle Mountain faults, they are in general alignment, and both occur in a similar context of Miocene faulting (where Crescent Formation strata has been uplifted by the Olympics) and a linear aeromagnetic anomaly.[160] The Canyon River Fault is a major fault in itself, associated with a 40 km long lineament and distinct late Holocene scarps of up to 3 meters.[161]

Although these faults are west of the Hood Canal Fault (previously presumed to be the western boundary of the Puget Lowland), new studies are revealing that the Saddle Mountain and related faults connect with the Seattle fault zone.[162] Trench studies indicate major earthquakes (in the range of M 6. to 7.8) on the Saddle Mountain faults [163] at nearly the same time (give or take a century) as the great quake on the Seattle Fault about 1100 years ago (900—930 AD).[164] Such quakes pose a serious threat to the City of Tacoma's dams at Lake Cushman,[165] located in the fault zone,[166] and to everyone downstream on the Skokomish River. The Canyon River Fault is believed to have caused a similar-sized earthquake less than 2,000 years ago;[167] this is a particular hazard to the Wynoochee Dam (to the west). The history and capabilities of the Frigid Creek Fault are not known.

Olympia Structure

The Olympia structure – also known as the Legislature fault[168] – is an 80 km long gravitational and aeromagnetic anomaly that separates the sedimentary deposits of the Tacoma Basin from the basalt of the Black Hills Uplift (between lines A and B on the map). It is not known to be seismic – indeed, there is very little seismicity south of the Tacoma Basin as far as Chehalis[169] – and not even conclusively established to be a fault.

This structure is shown in the gravitational mapping of 1965, but without comment.[170] Gower, Yount & Crosson (1985), labelling it "structure L", mapped it from Shelton (near the Olympic foothills) southeast to Olympia (pretty nearly right under the state Legislature), directly under the town of Rainier, to a point due east of the Doty Fault, and apparently marking the northeastern limit of a band of southeast striking faults in the Centralia-Chehalis area. They interpreted it as "simple folds in Eocene bedrock", though Sherrod (1998) saw sufficient similarity with the Seattle Fault to speculate that this is a thrust fault. Pratt et al. (1997), while observing the "remarkable straight boundaries that we interpret as evidence of structural control",[171] refrained from calling this structure a fault. (Their model of the Black Hills Uplift is analogous with their "wedge" model of the Seattle Uplift, discussed above, but in the opposite direction. If entirely analogous, then "roof duplex" might also apply, and the Olympia Fault would be a reverse fault similar to the Tacoma Fault.)

Aeromagnetic mapping in 1999 showed a very prominent anomaly[172] (such as typically indicates a contrast of rock type); that, along with paleoseismological evidence of a major Holocene earthquake, has led to a suggestion that this structure "may be associated with faulting".[173] One reason for caution is that a detailed gravity survey was unable to resolve whether the Olympia structure is, or is not, a fault.[174] Although no surface traces of faulting have been found in either the Holocene glacial sediments or the basalts of the Black Hills,[175] on the basis of well-drilling logs a fault has been mapped striking southeast from Offut Lake (just west of Rainier); it appears to be in line with the easternmost fault mapped in the Centralia—Chehalis area.[176]

A marine seismic reflection study[177] found evidence of faulting at the mouth of Budd Inlet, just north of the Olympia structure, and aligning with faint lineaments seen in the lidar imagery. These faults are not quite aligned with the Olympia structure, striking N75W (285°) rather than N45W (315°). It is uncertain how these faults relate to the structure, and whether they are deep-seated faults, or fractures due to bending of the shallow crust.

It has been speculated that the OS might connect with the seismically active Saint Helens Zone (discussed below), which would imply that the OS is both locked and being stressed, raising the possibility of a major earthquake.[178] Alternately, the OS appears to coincide with a gravitational boundary in the upper crust that has been mapped striking southeast to The Dalles on the Columbia River,[179] where there is a swarm of similarly striking faults.[180]

That Olympia and the south Sound are at risk of major earthquakes is shown by evidence of subsidence at several locations in southern Puget Sound some 1100 years ago.[181] What is unknown is whether this was due to a great subduction earthquake, to the noted earthquake on the Seattle Fault about that time, or to an earthquake on a local fault (e.g., the Olympia structure); there is some evidence that there were two earthquakes over a short time period. Subsidence dated to between AD 1445 and 1655 has been reported in Mud Bay (just west of Olympia).[182]

   (Not included in QFFDB.)

Doty Fault

File:Centralia-Chehalis District faults GM-34.jpg
Excerpt from Geologic Map GM-34, showing faults in the Centralia—Chehalis Coal District, Lewis County, Washington. Doty—Salzer Creek Fault runs east-west between Centralia and Chehalis (black squares). Map available on-line. Click on image for enlargement.

The Doty Fault – the southernmost of the uplift-and-basin dividing faults reviewed here, and located just north of the Chehalis Basin – is one of nearly a dozen faults mapped in the Centralia—Chehalis coal district in 1958.[183] While the towns of Centralia and Chehalis in rural Lewis County may seem distant (about 25 miles) from Puget Sound, this is still part of the Puget Lowland, and these faults, the local geology, and the underlying tectonic basement seem to be connected with that immediately adjacent to Puget Sound. And though the faults in this area are not notably seismogenic, the southeast striking faults seem to be en echelon with the Olympia structure (fault?), and headed for the definitely active Saint Helens Zone; this appears to be a large-scale structure. The Doty fault particularly seems to have gained prominence with geologists since it was associated with an aeromagnetic anomaly,[184] and a report in 2000 credited it capable of a magnitude 6.7 to 7.2 earthquake.[185] The prospect of a major earthquake on the Doty Fault poses a serious hazard to the entire Puget Sound region as it threatens vital economic lifelines: At Chehalis there is but a single freeway (Interstate 5) and a single rail line connecting the Puget Sound region with the rest of the west coast; the only alternate routes are very lengthy.[186]

The Doty fault has been mapped from the north side of the Chehalis airport due west to the old logging town of Doty (due north of Pe Ell), paralleled most of that distance by its twin, the Salzer Creek Fault, about half a mile to the north. Both of these are dip-slip (vertical) faults; the block between them has been popped up by compressive forces. The Doty Fault appears to terminate against, or possibly merge with, the Salzer Creek Fault at Chehalis; the Salzer Creek Fault is traced another seven miles east of Chehalis. The length of the Doty Fault is problematical: the report in 2000 gave it as 65 km (40 miles), but without comment or citation.[187] Such a length would be comparable to the length of the Seattle or Tacoma faults, and capable of an earthquake of M 6.7. But it does not appear that there have been studies of the deeper structure of these faults, or whether there has been any recent activity.

The Doty—Salzar Creek Fault does not fully fit the regional pattern of basins and uplifts bounded by faults described above. It does bound the north side of the Chehalis basin, but the south boundary of the Black Hills Uplift is more properly the southeast striking Scammon Creek Fault that converges with the Doty—Salzar Creek Fault just north of Chehalis.[188] In the acute angle between these is located the minor Lincoln Creek uplift, the Doty Hills, and an impressive chunk of uplifted Crescent basalt (reddish area at west edge of the map). The SE striking Scammon Creek Fault seems to be terminated by the Salzer Creek Fault (the exact relationship is not clear), with the latter continuing east for another seven miles. Yet the former is only the first of at least six more parallel southeast striking faults, which do cross the Salzer Creek Fault. These faults are: the Kopiah Fault (note the curious curve), Newaukum Fault, Coal Creek Fault, and three other unnamed faults. Just past them is the parallel Olympia Structure, which as a geophysical lineament has been traced to a point due east of Chehalis;[189] these would seem to be related somehow, but the nature of that relationship is not yet known.

Though these faults have been traced for only a little ways, the southeast striking anticlines they are associated with continue as far as Riffe Lake, near Mossyrock. They are also on-strike with a swarm of faults on the Columbia River, bracketing The Dalles. As all of these are thrust and reverse faults, they probably result from northeast directed regional compression.[190] These faults also cross the Saint Helens Zone (SHZ), a deep, north-northwest trending zone of seismicity that appears to be the contact between different crustal blocks.[191] How they might be connected is unknown.

What makes the Doty—Salzer Fault (and the short Chehalis Fault striking due east from Chehalis) stand out from the many other faults south of Tacoma is its east-west strike; the significance of this is not known.

   (Not included in QFFDB. See Snavely et al. 1958 and Geologic Map GM-34 for details.)

Saint Helens Zone, Western Rainier Zone

File:OFR 99-311 fig48.gif
Mid-crustal (10–20 km deep) seismicity in western Washington. (Fig. 48 from USGS OFR 99-311)

The most striking concentrations of mid-crustal seismicity in western Washington outside of Puget Sound are the Saint Helens Zone (SHZ) and Western Rainier Zone (WRZ) at the southern edge of the Puget Lowland (see seismicity map, right).[192] Indeed, it is mainly by their seismicity that these faults are known and have been located, neither showing any surface faulting.[193] The SHZ and WRZ lie just outside the topographical basin that constitutes the Puget Lowland (see image), do not participate in the uplift and basin pattern, and unlike the rest of the faults in the Puget Lowland (which are reverse or thrust faults reflecting mostly compressive forces) they appear to be strike-slip faults; they reflect a geological context distinctly different from the rest of the Puget Lowland. In particular, to the southeast of Mount St. Helens and Mount Rainier they reflect a regional pattern of NNW oriented faulting, including the Entiat Fault in the North Cascades and the Portland Hills and related faults around Portland (see QFFDB fault map). Yet the SHZ and WRZ may be integral to the regional geology of Puget Sound, possibly revealing some deep and significant facets, and may also present significant seismic hazard.

File:Southern Washington Cascades conductor.png
The Southern Washington Cascades Conductor (SWCC, yellow) located at depth approximately between Mount St. Helens (MSH), Mount Adams (MA), Goat Rocks (GR), Mount Rainier (MR), and Riffe Lake, with a lobe extending towards Tiger Mountain (TM). Also shown: Entiat Fault, Straight Creek Fault (inactive, southern continuation unknown), Southern Whidbey Island Fault, Rattlesnake Mountain Fault Zone, Olympic-Wallowa Lineament, White River/Naches River fault, Rimrock Lake Inlier (outlined in green), surface outcrops of the Crescent Formation (outlined in brown), Olympia Structure, Portland Hills fault zone.

The WRZ and SHZ are associated with the southern Washington Cascades conductor (SWCC), a formation of enhanced electrical conductivity[194] lying roughly between Riffe Lake and Mounts St. Helens, Adams, and Rainier, with a lobe extending north (outlined in yellow, right). This formation, up to 15 km thick, is largely buried (from one to ten kilometers deep), and known mainly by magnetotellurics and other geophysical methods.[195] The southwestern boundary of the SWCC, where it is believed to be in near vertical contact with the Eocene basalts of the Crescent Formation, forms a good part of the 90 km (56 mile) long SHZ. On the eastern side, where the SWCC is believed to be in contact with pre-Tertiary terranes accreted to the North American craton, matters are different. While there is a short zone (not shown) of fainter seismicity near Goat Rocks (an old Pliocene volcano[196]) that may be associated with the contact, the substantially stronger seismicity of the WRZ is associated with the major Carbon River—Skate Mountain anticline.[197] This anticline, or uplifted fold, and the narrower width of the northern part of the SWCC, reflects an episode of compression of this formation. Of great interest here is that both the northern lobe of the SWCC and the Carbon River anticline are aligned towards Tiger Mountain (an uplifted block of the Puget Group of sedimentary and volcanic deposits typical of the Puget Lowland) and the adjacent Raging River anticline (see map). The lowest exposed strata of Tiger Mountain, the mid-Eocene marine sediments of the Raging River formation, may be correlative with the SWCC.[198]

Does the SHZ extend north? Though the Olympia Structure (a suspected fault) runs towards the SHZ, and delineates the northern edge of an exposed section of the Crescent Formation, it appears to be an upper crustal fold, part of a pattern of folding that extends southeast to cross the Columbia River near The Dalles, and unrelated to the mid and lower crustal SHZ.[199] It has been speculated that the SHZ might extend under the Kitsap Peninsula (central Puget Sound), possibly involved with a section of the subducting Juan de Fuca plate that is suspected of being stuck. The implications of this are not only "the possibility of a moderate to large crustal earthquake along the SHZ", but that the tectonics under Puget Sound are more complicated than yet understood, and may involve differences in the regional stress patterns not reflected in current earthquake hazard assessments.[200]

Deeper structure

Mount St. Helens and Mount Rainier are located where their associated fault zones make a bend (see map, above).[201](Mt. Rainier is offset because the faults are deep and the conduits do not rise quite vertically.) These bends are located where they intercept a "subtle geological structure"[202] of "possible fundamental importance",[203] a NNE striking zone (line "A" on the map) of various faults (including the Tokul Creek Fault NNE of Snoqualmie) and early-Miocene (about 24 Ma) volcanic vents and intrusive bodies (plutons and batholiths) extending from Portland to Glacier Peak;[204] it also marks the change in regional fault orientation noted above. This MSH-MR-GP lineament is believed to reflect a "long-lived deep-seated lithospheric flaw that has exerted major control on transfer of magma to the upper crust of southern Washington for approximately the last 25 [million years]";[205] it has been attributed to the geometry of the subducting Juan de Fuca plate.[206]

A parallel line ("B") about 15 miles (25 kilometers) to the west corresponds to the western limit of a zone of seismicity stretching from the WRZ to southwest of Portland. Curiously, the extension of line "B" north of the OWL is approximately the eastern limit of Puget Sound seismicity, the rest of southwestern Washington and the North Cascades being relatively aseismic (see the seismicity map, above).[207] This line may also mark the northwestern boundary of the SWCC.[208] North of the RMFZ it follows a topographical lineament that can be traced to Rockport (on Hwy. 20);[209] it includes the Cherry Creek Fault Zone NNE of Carnation, location of the 1965 Duvall earthquake.[210] Between the Cherry Creek and parallel Tokul Creek faults is a contact between formations of the Western Melange Belt.[211] The zone between these two lines, reflecting changes in regional structure, seismicity, fault orientation, and possibly the underlying lithospheric structure, appears to be a major structural boundary in the Puget Lowland.

Also intersecting at Mount St. Helens is a NE (045°) trending line (red) of Pleistocene (about 4 Ma) plug domes and a topographic lineament (followed in part by Highway 12).[212] This line is the southernmost of a band of NE trending faults and topographical lineaments that extend from the Oregon coast into the North Cascades. A similar line aligns with the termination of the WRZ, SHZ, and Gales Creek Fault Zone (northwest of Portland), with faulting along the upper Nehalem River on the Oregon coast,[213] and a topographical contrast at the coast (between Neahkahnie Mountain and the lower Nehalem River valley) distinct enough to be seen on the seismicity map above (due west of Portland). Other similar lineaments (such as from Astoria to Glacier Peak) align with various topographical features and changes in fault orientation. These lineaments have been associated with possible zones of faulting in the crust and subducting plate.[214]

These features suggest that the southern Puget Lowland is influenced by the deep crust and even the subducting Juan de Fuca plate, but the details and implications are not yet known.

Other faults

Actual

There are numerous other faults (or fault zones) in the Puget Lowland, and around its edges, sketchily studied and largely unnamed. These are usually fairly short, and not believed to be significantly seismogenic. However, most seismic activity is not associated with any known fault.[215] Seismicity sometimes occurs in zones, such as has been observed under Mercer Island, or from downtown Seattle towards Kirkland[216] but whether particular zones reflect undiscovered faults, or might be the source of damaging earthquakes, is generally unknown. Ongoing mapping is revealing more faults. E.g., mapping along the Rattlesnake Mountain Fault Zone has revealed a complex network of active or potentially active faults across (and likely beyond) the lower Snoqualmie Valley, including the Cherry Creek Fault Zone, scene of the 1996 M 5.3 Duvall earthquake.[217]

The San Juan Island and Leach River faults crossing the southern end of Vancouver Island are significant and undoubtably connected with the Darrington—Devils Mountain and Southern Whidbey Island faults, and certainly of particular interest to the residents of Victoria, B.C.. But their significance to the Puget Sound area is unknown.

The Little River Fault (see the QFFDB, Fault 556) is representative of an extensive zone of faults along the north side of the Olympic Peninsula and in the Strait of Juan de Fuca (likely connected with the fault systems at the south end of Vancouver Island, see fault database map), but these lie west of the crustal blocks that underlie the Puget Lowland, and again their possible impact on the Puget Sound region is unknown. One of these faults, the Sequim Fault Zone (striking east from the town of Sequim), crosses Discovery Bay (and various possible extensions of the Hood Canal Fault) and bounds the Port Ludlow Uplift ("uplift of unknown origin" on the map); it appears to extend to the Southern Whidbey Island Fault.[218]

An Everett Fault, running east-northeast along the bluffs between Mukilteo and Everett – that is, east of the SWIF and at the southern edge of the Everett Basin – has been claimed, but this does not appear to have been corroborated.[219]

A Lofall Fault has been reported on the basis of marine seismic reflection surveying,[220] but has not been confirmed by trenching. This fault seems to be associated with the Kingston arch anticline, and part of the uplift and basin pattern, but shortened because of the geometry of the SWIF. It is not notably seismogenic.

Although the largely unstudied White River Fault (WRF) appears to lie just outside the Puget Lowland, it may actually connect under the Muckleshoot Basin to the East Passage Zone and the Tacoma Fault (map).[221] This would pose significantly greater seismic hazard than currently recognized, especially as the White River Fault is believed to connect with the Naches River Fault that extends along Highway 410 on the east side of the Cascades towards Yakima.

The Straight Creek Fault is a major structure in the North Cascades, but has not been active for over 30 million years.[222] Various other faults in the North Cascades are older (being offset by the Straight Creek Fault) and are unrelated to the faults in Puget Sound.

Conjectured

A Puget Sound Fault running down the center of Puget Sound (and Vashon Island) was once proposed,[223] but seems to have not been accepted by the geological community. A Coast Range Boundary Fault (CRBF, discussed above) was inferred on the basis of differences in the basement rock to the west and east of Puget Sound (the Crescent Formation—Cascadia core contact), and arbitrarily mapped at various locations including Lake Washington; north of the OWL this is now generally identified, with the Southern Whidbey Island Fault.[224] Where it might run south of Seattle is not known; an argument has been made that it runs beneath Seattle[225] but this is still conjectural.

Study of surface deformation suggests possible unmapped faults near Federal Way, running between Sumner and Steilacoom, and south of Renton.[226]

See also

Notes

  1. "The Puget Lowland is a north-south-trending structural basin that is flanked by Mesozoic and Tertiary rocks of the Cascade Range on the east and by Eocene rocks of the Olympic Mountains on the west." Barnett et al. 2010, p. 2, and see Figure 1. The Georgia Basin to the north is structurally related, but topographically demarcated by the Chuckanut Mountains near Bellingham.
  2. Ballantyne, Pierepiekarz & Chang 2002, p. 2.
  3. Bucknam, Hemphill-Haley & Leopold 1992, p. 1611; Fisher et al. 2005, p. 8; Karlin & Abella 1996, p. 6138.
  4. Ballantyne, Pierepiekarz & Chang 2002, p. 11
  5. Stanley, Villaseñor & Benz 1999, figures 46—50. See the maps.
  6. Harding & Berghoff 2000, p. 2.
  7. Daneš et al. 1965.
  8. Gower 1980; Gower, Yount & Crosson 1985.
  9. Barnett et al. 2010, p. 1
  10. Adams 1992.
  11. Haugerud et al. 2003; Harding & Berghoff 2000; Nelson et al. 2003, p. 1369; Sherrod et al. 2004; Johnson et al. 2004b, p. 2299.
  12. Brocher et al. 2001.
  13. Blakely & Wells Weaver1999; Blakely et al. 2002.
  14. Calvert & Fisher 2001.
  15. Parsons et al. 1999, figure 5a.
  16. Brandon & Calderwood 1990.
  17. Troost, The Origin of Puget Sound.
  18. Pratt et al. 1997, p. 27,471.
  19. Stanley, Villaseñor & Benz 1999, p. 43.
  20. Blakely et al. 2002
  21. Tabor 1994, pp. 217, 230.
  22. See Lamb et al. (2012, figures 2A and 2BA).
  23. Because of the geometry of the SWIF and the Kingston arch, the "uplift of unknown origin" between them is smaller, and the fault separating the uplift from the arch (the Lofall Fault, discovered relatively recently by Brocher et al. 2001, p. 13,557) is shorter; it is not notably seismogenic.
  24. Strictly speaking the southern edge of the Black Hills Uplift would be the southeast striking Scammon Creek Fault that converges with the east striking Doty Fault at Chehalis. In the angle between these is located the minor Lincoln Creek uplift, the Doty Hills, and, further west, an impressive chunk of Crescent basalt. If the pattern is continued to the southwest, along cross-section A-A' in Pratt's figure 11 (and missing the mapped trace of the Doty Fault), then the next basin is at Grays Harbor (not shown here). The Doty Fault/Chehalis Basin sequence follows the cross-section X-X' shown on the map.
  25. Blakely et al. 2009b; Blakely et al. 2011, §5.2.1.
  26. See Stanley et al. 1996, figure 2.
  27. Pratt et al. 1997.
  28. Babcock et al. 1992, p. 6799.
  29. Pratt et al. 1997, see figure 2; Johnson et al. 2004a, see figure 17.
  30. Pratt et al. 1997, p. 27,486.
  31. Logan et al. 1998.
  32. Stanley, Villaseñor & Benz 1999, p. 46, and see figure 64.
  33. Pratt et al. 1997, §4.2; Brocher et al. 2001, §6.2
  34. Stanley, Villaseñor & Benz 1999, pp. 45, 46.
  35. Tabor 1994, p. 230.
  36. Hayward et al. 2006
  37. Geologic Map GM-61 (McMurray).
  38. QFFDB Fault 573.
  39. Johnson et al. 2004b, p.2313.
  40. Geologic Map GM-59 (Oak Harbor and Crescent Harbor).
  41. Hayward et al. 2006, p.444.
  42. Blakely & Sherrod 2006.
  43. QFFDB Fault 572; Johnson et al. 1996.
  44. Johnson et al. 1996.
  45. Brocher et al. 2001, §5.10.
  46. Clowes et al. 1987; Johnson et al. 1996, p. 336.
  47. Clowes et al. 1987.
  48. Brocher et al. 2001, §5.10. This contact is the Coast Range Boundary Fault, discussed below.
  49. Johnson et al. 1996, Fig. 1; Barnett et al. 2010, Map 5, on-line.
  50. Sherrod et al. 2008, paragraph 11.
  51. Johnson et al. 1996, p. 351.
  52. Brocher et al. 2001, §5.10.
  53. Sherrod et al. 2008, par. 71.
  54. Blakely et al. 2004 (USGS OFR 04-1204); Sherrod et al. 2005 (USGS OFR 05-1136); Sherrod et al. 2008; Liberty & Pape 2008.
  55. GM-67, pp. 11, 12 (Fall City); GM-73 (North Bend); Dragovich et al. 2010a (Carnation).
  56. Sherrod et al. 2008, paragraphs 75, 78, & 84; Geologic Map GM-67.
  57. Sherrod et al. 2008, §6.3, par. 78.
  58. Blakely et al. 2011. Their preferred interpretation is that the SWIF is right-offset along the RMFZ (par. 71). See fig. 22.
  59. Dragovich et al. 2012 (Lake Joy).
  60. The long-range mapping plan area and current status of planned mapping can be seen at Washington State DNR.
  61. Kelsey & Sherrod 2001, p. 2.
  62. Sherrod et al. 2005, pp. 15, 2.
  63. For the County's interpretation of the geological hazard and anticipated impacts of a major earthquake, see the Environmental Impact Statements.
  64. GM-73 (North Bend).
  65. Geologic Map GM-73, pp. 29–30.
  66. Geologic Maps GM-67 (Fall City) and GM-73, p. 31.
  67. Dragovich et al. 2010a (Carnation), p. 2; Dragovich et al. 2011 (Monroe), p. 2.
  68. Blakely et al. 2011, par. 71.
  69. Geological Map GM-52, pp. 5, 6.
  70. GM-73, Figures 3B and 3C, and throughout. Whether RMFZ is also the Crescent-Cascade contact, and thereby the Coast Range Boundary Fault, depends on whether the Crescent Formation reaches this far. Gravity studies (Finn 1990, p. 19,538) suggest not, or at least not near the surface. The situation at depth is not known. There is a suggestion of a décollement about 18 km down, (GM-73, p. 31), but at a similar décollement further south (under the SWCC) the underlying basement is believed to be pre-Tertiary.
  71. Dragovich et al. 2011.
  72. Johnson et al. 1996, p. 340: "must occur".
  73. Johnson et al. 1996, p. 336.
  74. Johnson et al. 1996, p. 336, and see fig. 1.
  75. Brocher et al. 2001, §5.10.
  76. GM-73, p. 30 and map. There is some evidence for a décollement (horizontal separation) at about 18 km depth, and it is possible that the surface patterns of faulting do not reflect faulting or structure below the décollement. See GM-73, p. 31 and preceding figures.
  77. The SWCC appears to be Tertiary marine sediments, not the pre-Tertiary metamorphic rock of the Cascades province; this would seem to make it part of the Coast Range province, with the Coast Range—Cascade contact further east. However, the SWCC is relatively shallow (no more than 15 km deep), and likely is draped over pre-Tertiary bedrock. (See Stanley et al. 1996, Fig. 5.) The Crescent Formation is expected to be in contact with the pre-Tertiary rock along the SHZ at depth.
  78. Finn 1990, p. 19,538. This constraint might not apply at depth.
  79. Mace & Keranen 2012.
  80. Johnson, Potter & Armentrout 1994; Johnson et al. 1996.
  81. Snelson et al. 2007, Figures 6 & 7.
  82. As indicated in GM-50 and the location maps of Brocher et al. 2001, Van Wagoner et al. 2002, Johnson et al. 2004a, Snelson et al. 2007, and Ramachandran 2012.
  83. There is a preliminary report of aeromagnetic and gravity mapping placing the eastern edge of the Siletz terrane under Lake Washington. See Anderson et al. 2011 (abstract).
  84. Dragovich et al. 2010a (Carnation).
  85. Dragovich et al. 2013 (Sultan); Dragovich et al. 2014 (Lake Chaplain).
  86. Dragovich et al. 2013 (Sultan) map, and figure 1 in pamphlet.
  87. Dragovich et al. 2014, p. 2.
  88. Where it intersects the northwest-trending Johnsons Swamp fault zone, easternmost member of the RMFZ.
  89. Dragovich et al. 2013, p. 19 and figure D1 (Sultan). Additional details in Dragovich et al. 2010b (supplement), and see map of epicenters in Dragovich et al. 2012, plate 2 (Lake Joy).
  90. Dragovich et al. 2013, p. 19 (Sultan).
  91. Conjugate faults are secondary faults that branch off from opposite sides of a strike-slip fault at approximately the same angle. Here, the Cherry Creek and Tokul Creek faults zones on the east side of the RMFZ are conjugate to the SWIF on the west side.
  92. Dragovich et al. 2010a, p. 2 (Carnation); Dragovich et al. 2012, App. H (Lake Joy).
  93. GM-52, Fig. 1.
  94. Dragovich et al. 2012, p. 2, Appendix H (Lake Joy).
  95. Interstate 5 runs nearly due north from Everett to Mount Vernon, except for a stretch southeast of Conway that parallels one of these low-amplitude folds. In some places, such as along the South Fork of the Stillaguamish River between Arlington and Granite Falls, there are also contrasting geological contacts. Geologic Map GM-50.
  96. Rogers 1970, p. 55.
  97. Frizzell et al. 1987; Dragovich et al. 2015, pp. 13–14, 17–18.
  98. Cheney 1987.
  99. Dragovich et al. 2014 (MS 2014-01, Lake Chaplain).
  100. Cheney 1987, Figure 4.
  101. Locations of some previously mapped faults have been adjusted on the latest map. Dragovich et al. 2015 (MS 2015-01, Lake Roesiger).
  102. GM-61, p. 10.
  103. Dragovich et al. 1998 (OFR 98-5, Bow and Alger) p. 44.
  104. Liberty 2009, p. 3.
  105. Daneš et al. 1965, pp. 5576–5577, and figure 5.
  106. See Adams 1992, and additional references at Seattle Fault.
  107. Geologic Map GM-67 (Fall City), p. 11; Geologic Map GM-73 (North Bend), pp. 9, 12.
  108. And further amplified by Brocher, Blakely & Wells 2004 and Johnson et al. 2004a.
  109. ten Brink, Song & Bucknam 2006, p. 588.
  110. Stanley, Villaseñor & Benz 1999, p. 46.
  111. Bucknam, Hemphill-Haley & Leopold 1992, see figure 1.
  112. Johnson, Potter & Armentrout 1994, p. 74.
  113. Daneš et al. 1965, pp. 5577–5579; Yount & Gower 1991, p. 9.
  114. Johnson et al. 1999, figure 6; Brocher et al. 2001, figure 1; Blakely et al. 2002, figures 1, 2, and 3. Curiously, Johnson et al. (1999), having failed to find any definite indications of a fault zone in seismic-reflection profiles in Hood Canal, claimed (p. 1048) that "the Seattle fault does not extend west as far as Hood Canal" (emphasis added).
  115. Blakely et al. 2002, figures 2 and 3; Liberty 2009, p. 6.
  116. Polenz et al. 2012, pp. 6–7 (Brinnon); Contreras et al. 2012b, p. 1 (Eldon).
  117. Haeussler & Clark 2000 (Wildcat Lake); Brocher et al. 2001, p. 13,556; Contreras et al. 2012a, pp. 1, 3–4 (Holly).
  118. The Frigid Creek fault seems more directly aligned with this southwestward extension of the Seattle Fault, but such a connection seems to be as yet unremarked by geologists.
  119. Contreras et al. 2012b, p. 14 (Eldon).
  120. Polenz et al. 2012, p. 7 (Brinnon). See also Lamb et al. 2012.
  121. Haug 1998; Van Wagoner et al. 2002, para. 69.
  122. Blakely et al. 2009a, p. 14; Polenz et al. 2013 (Seabeck). See figure 1 for overview.
  123. Mace & Keranen 2012, para. 3.
  124. Lamb et al. 2012, p. 925.
  125. Nelson et al. 2008 (SIM 3060)
  126. Brocher et al. 2001, §6.1.
  127. Sherrod et al. 2004, p. 11.
  128. Johnson et al. 2004a, §5 and figure 17.
  129. Brocher et al. 2001.
  130. Sherrod et al. 2004. See also Brocher et al. 2001, §6.1 (p. 13,558).
  131. The QFFDB, citing lack of consensus, ignores the eastern part.
  132. Brocher et al. 2001; Johnson et al. 2004a, see figure 4, and compare the differences in cross-sections A-A' (west) and B-B' (east) in figure 17.
  133. Brocher et al. 2001, §6.3.
  134. Blakely et al. 2009b (abstract); Carley, Liberty & Pratt 2007 (abstract); Liberty 2007, figure 3; Blakely et al. 2011, §5.2.1, and see Fig. 22. Alternately, the Tacoma Fault may be only a splay, with the main part of the WRF fault continuing WNW past Kent and Bremerton (Washington Narrows).
  135. Sherrod et al. 2003.
  136. Lamb et al. 2012 p. 925.
  137. Lamb et al. 2012, p. 925.
  138. Johnson et al. 2004a, figures 2A and 2B; Brocher et al. 2001, figure 6.
  139. Lamb et al. 2012.
  140. Johnson et al. 2004a, para. 75-77, figure 18.
  141. Lamb et al. 2012, p. 928, and see figure 8c.
  142. Lamb et al. 2009a.
  143. Lamb et al. 2012, pp. 928, 916.
  144. Lamb et al. 2012, p. 928.
  145. Daneš et al. 1965, p. 5579; Yount & Gower 1991, pp. 9, 10; QFFDB Fault 552.
  146. E.g., Pratt et al. 1997.
  147. QFFDB Fault 552.
  148. Van Wagoner et al. 2002, §4.1.9.
  149. Ramachandran 2012, §3.5.
  150. Contreras et al. 2010, p. 4 (Lilliwuap).
  151. Polenz et al. 2013, p. 1 (Seabeck).
  152. Contreras et al. 2012b, p. 16 (Eldon). See also Polenz et al. 2010b, p. 23 (supplement).
  153. Polenz et al. 2012, p. 7 (Brinnon).
  154. Polenz et al. 2012, p. 7 (Brinnon). A possible extension of this lineament appears in the Eldon Quadrangle geological map. Contreras et al. 2012b, p. 1.
  155. Blakely et al. 2009a, p. 14; Contreras et al. 2012b, pp. 1, 16 (Eldon). See Lamb et al. 2012, figure 8c for a conjectural cross-section view.
  156. Blakely et al. 2009a, Fig. 11c; Polenz et al. 2013, p. 1 (Seabeck).
  157. See QFFDB Fault 562a and Fault 562b
  158. Carson 1973; Carson & Wilson 1974.
  159. Blakely et al. 2009a, p. 1.
  160. Blakely et al. 2009a, pp. 13–15, and figure 4.
  161. Walsh & Logan 2007 (OFR 2007-1).
  162. Blakely et al. 2009a; Lamb et al. 2009a; Lamb et al. 2012; Contreras et al. 2012b, pp. 1, 15 (Eldon).
  163. Witter & Givler 2005, p. 16; Blakely et al. 2009a, pp. 1, 15.
  164. Figure 64 of Stanley, Villaseñor & Benz 1999 (USGS OFR 99-0311) shows additional dates of various co-seismic events. See also Logan et al. 1998.
  165. See Cushman Dam No. 1 and Cushman Dam No. 2.
  166. Witter & Givler 2005, p. 1, and see Figure 2.
  167. Walsh & Logan 2007.
  168. Sherrod 1998, pp. 99, 131, and figure 4-19.
  169. Stanley, Villaseñor & Benz 1999 (OFR 99-311), figures 46—50. See seismic maps.
  170. Daneš et al. 1965, figures 3 and 4.
  171. Pratt et al. 1997, p.27,472.
  172. Blakely, Wells & Weaver 1999 (OFR 99-514). Download the map and see the aeromagnetic anomaly. Additional aeromagnetic and gravitational imagery of the Olympia and other structures available on the Summit Lake geological map.
  173. Sherrod 2001, p. 1308.
  174. Magsino et al. 2003.
  175. E.g., Logan & Walsh 2004 (Summit Lake map). More recently it has been suspected that a natural berm across the delta of the Skokomish River may be due to faulting, which could implicate the OS as an active fault. But the researchers are not yet ready to assert that. Polenz et al. 2010a (Skokomish); Polenz et al. 2010b.
  176. Geologic Map GM-56 (East Olympia).
  177. Clement 2004; Clement et al. 2010.
  178. Weaver & Smith 1983, pp. 10,376, 10,380.
  179. Blakely & Jachens 1990, plate 2.
  180. See QFFDB 580, "Faults near The Dalles".
  181. Sherrod 1998; Sherrod 2001, p. 1308 and generally.
  182. Logan & Walsh 2004 (Summit Lake map).
  183. Snavely et al. 1958.
  184. Finn & Stanley 1997, p. 4; Finn 1999, p. 330.
  185. Wong et al. 2000, Table 1, p. 7.
  186. See report from the Washington State Department of Transportation for the economic costs when flooding closed the freeway for just several days.
  187. Wong et al. 2000, Table 1, p. 7. 40 miles would include the combined Doty—Salzer Creek fault plus a 15 mile extension west to South Bend, on Willapa Bay. Finn (1990), without identifying it, associated the Doty Fault with notable gravity and aeromagnetic anomalies (Plates 1 and 2) that extend towards Willapa Bay.
  188. Pratt et al. 1997, Plate 1.
  189. Gower, Yount & Crosson 1985 (Map I-1613).
  190. Geologic Map GM-34 (Southwest Quadrant).
  191. Weaver, Grant & Shemata 1987.
  192. Stanley, Villaseñor & Benz 1999, figures 46—49; Stanley et al. 1996, p. 5.
  193. Weaver & Smith 1983; Stanley, Finn & Plesha 1987, p. 10,179; Stanley et al. 1996, pp. 6—7.
  194. Several possible explanations of the enhanced conductivity have been considered; Eocene marine sediments containing brine are most likely (Stanley, Finn & Plesha 1987, pp. 10,183—10,186). Egbert & Booker (1993) discuss evidence that the conductivity anomaly may be broader than shown here, and suggest it is a remnant of an "early Cenozoic subduction zone which is analogous to the present-day Olympic Peninsula." (p. 15,967)
  195. Stanley, Finn & Plesha 1987; Stanley et al. 1996, pp. 6—7.
  196. Stanley et al. 1996, p. 6.
  197. Stanley et al. 1996, p. 4
  198. Vine 1962, pp. 7–8; Stanley & Johnson 1993, p. 3; Stanley et al. 1996, figure 13, pp. 15—16. If the Carbon River and Raging River anticlines are related, and the SWCC and Raging River formations correlative, the RMFZ would be the eastern edge of the SWCC. That the fault strands of the RMFZ turn easterly, and seismicity jumps from a fault contact to an anticline, suggests there is more to learn about the OWL/WR-NR zone.
  199. Geologic Map GM-53, (Washington State).
  200. Weaver & Smith 1983, pp. 10,383, and 10,371. See also p. 10,376, and figure 8.
  201. Weaver, Grant & Shemata 1987, pp. 10,170, 10,176; Stanley et al. 1996, p. 16.
  202. Weaver, Grant & Shemata 1987, p. 10,175.
  203. Evarts, Ashley & Smith 1987, p. 10,166.
  204. Tabor & Crowder (1969, p. 60, and see figure 60) (possibly relying on an earlier writer) reported a "zone of basaltic dikes and cinder cones that trends north-northeast" (NNE), including Mount Rainier and Mount St. Helens "to the southwest". Evarts, Ashley & Smith (1987, p. 10,166) state that "Mount Rainier and Glacier Peak are aligned along the projection of this trend," described as NNE, or "roughly N25E". While MR does bear nearly N25E from MSH, calculation from latitude and longitude shows the MSH—GP bearing to be more accurately N21E; lining up all three volcanoes would require a slight bowing of the lineament. However, features near MSH (such as Yale Lake and Spirit Lake) bear N20E, not aligned with MR. It is more likely that MR, in rising to the surface, has "drifted" off of the underlying lineament. This NNE striking lineament should not be confused with other lineaments striking N50°E. See Evarts, Ashley & Smith 1987, p. 10,166, Weaver, Grant & Shemata 1987, p. 10,175, and Hughes, Stoiber & Carr 1980, figure 1.
  205. Evarts, Ashley & Smith 1987, p.10,166.
  206. Hughes, Stoiber & Carr 1980, p. 16; Guffanti & Weaver 1988, p. 6523.
  207. Stanley et al. 1996, p. 5; Stanley, Villaseñor & Benz 1999, "Seismicity Patterns", and figures 46—49. The location and orientation of line "B" as shown here is approximate.
  208. The apparent gap north of Riffe Lake is possibly due to obscuration by volcanic deposits of the Northcraft Formation. Stanley et al. 1996, p. 4 and figure 3.
  209. Along part of the Sultan River and the west end of Blue Mountain, the east sides of Mount Pilchuck, Three Fingers, and Whitehorse Mountain, and (north of Darrington and the DDMF) the west side of North Mountain and part of the North Fork of the Stillaguamish River. North of Hwy 20 it is paralleled by Lake Shannon.
  210. However, according to Stanley, Villaseñor & Benz (1999, p. 34) the Duvall earthquake was on a fault striking 350°. This suggests the quake was actually on the cross-cutting Cherry Valley fault, the northern most member of the RMFZ, and possibly an extension of the Griffin Creek fault. Dragovich et al. 2010a, p. 2.
  211. Geological map GM-52 (Tectonic elements).
  212. Evarts, Ashley & Smith 1987, p. 10,166.
  213. Olbinski 1983, pp. 149—151.
  214. Hughes, Stoiber & Carr 1980, p. 15.
  215. Rogers (2002, p. 145): "... there is little evidence of fault planes aligning with spatial trends of epicentres. Instead, most crustal seismicity seems to be occurring on random faults, all responding to the same regional stress."
  216. Yelin 1982. See also Map view of quakes in western Washington at PNSN.
  217. For details see references for Cherry Creek Fault Zone.
  218. Brocher et al. 2001, p. 13,557.
  219. Molinari & Burk 2003 (abstract).
  220. Brocher et al. 2001, p. 13,557.
  221. Blakely et al. 2009b (abstract); Carley, Liberty & Pratt 2007 (abstract); Blakely et al. 2011, §5.2.1, and see Fig. 22. Or it might continue WNW in association with a topographical lineament extending from Lake Meridian (Kent) past Southworth, the Washington Narrows (entrance to Dyes Inlet), the western end of the Seattle Fault, and the southern tip of the Toandos Peninsula.
  222. Vance & Miller 1994.
  223. Johnson 1984; Johnson et al. 1999.
  224. Johnson et al. 1996, pp. 336, 341, 348; Geologic Map GM-67 (Fall City).
  225. Snelson et al. 2007, p. 1442.
  226. Finnegan et al. 2008.

References

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External links

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