Cenozoic tectonics of the western United States

The Cenozoic structures of the western United States are interpreted here as being products mostly of horizontal motion of the crust. The distribution of strike-slip faulting, tensional fragmentation of the brittle upper crust or rupturing of the entire continental crust, and compression define a pattern of northwestward motion increasing irregularly southwestward toward coastal California. Hans Becker, in 1934, and S. W. Carey, in 1958, are among those who have suggested such a tectonic system. The aggregate Cenozoic right-lateral displacement of Cretaceous and older rocks and structures by the northwest-trending strike-slip faults of coastal California is about 500 km. The greater part of this movement has occurred along the San Andreas fault, but many other faults share in it. At least six earthquakes within the past century have been accompanied by lateral displacements at the surface along faults of the San Andreas system. Successively greater offsets of successively older geologic terranes demonstrate continuing motion throughout Cenozoic time. Late Miocene materials have been displaced at least 160 km; Oligocene, at least 260 km. The present velocity of regional shear strain, about 6 cm/yr, demonstrated by geodetic resurveying in southern and central California, is about 8 times faster than the average needed to account for the total movement within the Cenozoic. The faults are in general associated with structures formed by oblique tension south of Los Angeles and with structures due to oblique compression north of that city. The opening of the Gulf of California and the Salton Trough by the oblique rifting of Baja California and the Peninsular Ranges away from mainland Mexico is the greatest of the tensional effects. The strike-slip faults may be confined to the crust. Earthquake foci extend no deeper than 16 km. The faults end to the south in the Gulf of California, whose crustal structure is oceanic. To the north, the San Andreas turns seaward as the north-facing Gorda scarp, west in line of which in deeper water is the south-facing Mendocino escarpment, produced apparently by an inactive left-lateral oceanic fault. The continental sliver of coastal and Baja California, west of the faults of the San Andreas system, may be drifting northwestward independently over the ocean floor and the mantle, and the leading point of the sliver may have been deflected westward when it hit the Mendocino scarp on the sea floor. East of this coastal movement system is the Basin and Range province, whose obvious Cenozoic structures are dominated by block faulting. The present ranges have formed mostly since early Miocene time, similar older ranges having been destroyed by erosion and deformation. The normal faulting, which is not associated within the region with any complementary tectonic compression, requires crustal extension as its basic cause. If the faults maintain their average 60° dips at depth, extension is half the dip-slip amount; but probably the major faults flatten downward, and the amount of extension about equals that of shallow dip-slip. Total Cenozoic extension in northern Nevada and Utah may have been 300 km. Concurrent volcanism much augmented the thinned and fragmented crust, and the volcanic terranes in turn have been fragmented by block faulting. Right-lateral strike-slip faults trend northwestward in lanes between normal-fault maintain blocks in the southwestern part of the Basin-Range province. Cenozoic displacements reach 50 km on the Las Vegas fault and 80 km on the Death Valley-Furnace Creek faults. Northeast of the strike-slip faults, ranges and basins trend north-northeastward in tension-gash orientation. Within the belt of lateral faulting, ranges undergoing active normal faulting mostly trend north-northwestward in oblique pull-apart orientation. The Sierra Nevada and Klamath Mountains have moved northwestward and rotated counterclockwise, thus moving away from the continental interior more in the north than in the south, and the extension distributed behind them has formed the Basin-Range province. The narrow block-fault Rio Grande valley system of New Mexico and southern Colorado is structurally and topographically similar to the rift valleys of East Africa and reflects localized crustal extension. The Idaho batholith, like the Sierra Nevada batholith, is drifting northwestward as an unbroken plate. Extension east of the Idaho batholith is taken up by normal-fault fragmentation in south-central Idaho and southwestern Montana, whereas extension south of the batholith has produced a rift through the continental crust, the Snake River Plain, filled deeply by lava. Seismic velocities indicate granitic crust to be lacking in at least the western part of the plain. Right-lateral faults of the Osburn system bound the batholithic plate on the north, and the motion they represent is taken up north of them by extension forming fault troughs. Integration of geologic and geophysical information shows that large regions of the Northwest are lava accumulations of continental crustal thickness, not old continental crust covered by lava. The volcanic terrane of northwestern Oregon and southwestern Washington forms new volcanic crust in a region which was oceanic before Cenozoic time. The volcanic terrane of southeastern Oregon, northeastern California, and northwestern Nevada fills an irregular tension rift through the Mesozoic continental crust. This rift resulted from the westward motion of the Klamath Mountains region, which was sundered from a position south of the Mesozoic terrane of northeastern Oregon and which was bent oroclinally as it moved westward in post-middle Eocene time. The Mesozoic terrane of northeastern Oregon pivoted away from the Idaho batholith to form a smaller orocline and left a triangular rift since filled by lava. Independent motion of continental crust over mantle and oceanic crust seems to be indicated. Inertial forces due to redistribution of rotational momentum among crustal fragments, mantle, and core may provide the motive power.

[1]  P. P. Orkild,et al.  Age of Basin and Range Normal Faults in Nevada Test Site and Nellis Air Force Range, Nevada , 1968 .

[2]  B. Bolt,et al.  THE CENTRAL CALIFORNIAN LARGE-SCALE SEISMIC ARRAY , 1967 .

[3]  J. H. Stewart Possible Large Right-Lateral Displacement Along Fault and Shear Zones in the Death Valley-Las Vegas Area, California and Nevada , 1967 .

[4]  L. A. Wright,et al.  Strata of Late Precambrian-Cambrian Age, Death Valley Region, California-Nevada , 1966 .

[5]  W. Ruddiman,et al.  Shaping of the Continental Rise by Deep Geostrophic Contour Currents , 1966, Science.

[6]  W. H. Taubeneck An evaluation of tectonic rotation in the Pacific Northwest , 1966 .

[7]  B. Troxel,et al.  TECTONICS OF DEATH VALLEY REGION, CALIFORNIA , 1966 .

[8]  B. Burchfiel,et al.  “PULL-APART” ORIGIN OF THE CENTRAL SEGMENT OF DEATH VALLEY, CALIFORNIA , 1966 .

[9]  C. Whitten,et al.  Surveys for crustal movement along the Hayward fault , 1966 .

[10]  G. Leech The Rocky Mountain Trench , 1966 .

[11]  E. Michael LARGE LATERAL DISPLACEMENT ON GARLOCK FAULT, CALIFORNIA, AS MEASURED FROM OFFSET FAULT SYSTEM , 1966 .

[12]  M. G. Bonilla,et al.  Tectonic creep in the Hayward fault zone, California , 1966 .

[13]  D. R. Shawe Strike-Slip Control of Basin-Range Structure Indicated by Historical Faults in Western Nevada , 1965 .

[14]  T. R. Lafehr Gravity, isostasy, and crustal structure in the southern Cascade Range , 1965 .

[15]  R. Nielsen RIGHT-LATERAL STRIKE-SLIP FAULTING IN THE WALKER LANE, WEST-CENTRAL NEVADA , 1965 .

[16]  L. C. Pakiser,et al.  Transcontinental crustal and upper‐mantle structure , 1965 .

[17]  C. R. Allen Transcurrent faults in continental areas , 1965, Philosophical Transactions of the Royal Society of London. Series A, Mathematical and Physical Sciences.

[18]  W. K. Hamblin Origin of “Reverse Drag” on the Downthrown Side of Normal Faults , 1965 .

[19]  M. N. Christensen Late Cenozoic Deformation in the Central Coast Ranges of California , 1965 .

[20]  R. Dott Mesozoic‐cenozoic tectonic history of the southwestern Oregon coast in relation to cordilleran orogenesis , 1965 .

[21]  B. K. Meade Horizontal crustal movements in the United States , 1965 .

[22]  A. Orange,et al.  Further deep resistivity measurements in the Pacific Northwest , 1965 .

[23]  M. Paterson,et al.  Experimental deformation of serpentinite and its tectonic implications , 1965 .

[24]  W. Ernst Mineral Parageneses in Franciscan Metamorphic Rocks, Panoche Pass, California , 1965 .

[25]  P. Dehlinger,et al.  Local travel-time curves and their geologic implications for the Pacific Northwest states , 1965 .

[26]  P. Nelson,et al.  Deep resistivity measurements in the Pacific Northwest , 1965 .

[27]  N. Watkins Paleomagnetism of the Columbia plateaus , 1965 .

[28]  G. Woollard The Bouguer Gravity Anomaly Map of the United States , 1965 .

[29]  B. Burchfiel Structural Geology of the Specter Range Quadrangle, Nevada, and its Regional Significance , 1965 .

[30]  R. E. Wallace,et al.  Geology of the Coeur d'Alene district, Shoshone County, Idaho , 1965 .

[31]  R. W. Bromery Aeromagnetic map of the Albany-Newport area, Oregon, and its geologic interpretation , 1965 .

[32]  D. Hopkins,et al.  Quaternary Geology and Archaeology of Alaska , 1965 .

[33]  Warren Hamilton Geology and petrogenesis of the Island Park caldera of rhyolite and basalt, eastern Idaho , 1965 .

[34]  G. D. Nicholls Basalts from the Deep Ocean Floor , 1965 .

[35]  Summary of the Phanerozoic time-scale: the Geological Society Phanerozoic time-scale 1964 , 1964, Geological Society Special Publication.

[36]  F. P. Shepard,et al.  Bathymetry and Faults of Gulf of California , 1964 .

[37]  R. L. Fisher,et al.  Structural History and Evolution of Gulf of California , 1964 .

[38]  G. B. Oakeshott Earthquakes in the San Andreas Fault Zone, Maricopa to Elizabeth Lake , 1964 .

[39]  C. R. Allen,et al.  Geophysical Framework of Northern End of Gulf of California Structural Province , 1964 .

[40]  Richard P. Phillips Seismic Refraction Studies in Gulf of California , 1964 .

[41]  T. N. V. Karlstrom,et al.  Surficial geology of Alaska , 1964 .

[42]  H. G. Schlicker,et al.  Geology of the central and northern parts of the Western Cascade Range in Oregon , 1964 .

[43]  C. R. Longwell,et al.  Middle and Lower Ordovician formations in southernmost Nevada and adjacent California , 1964 .

[44]  J. Eaton Crustal structure from San Francisco, California, to Eureka, Nevada, from seismic-refraction measurements , 1963 .

[45]  W. Hamilton OVERLAPPING OF LATE MESOZOIC OROGENS IN WESTERN IDAHO , 1963 .

[46]  D. Wise AN OUTRAGEOUS HYPOTHESIS FOR THE TECTONIC PATTERN OF THE NORTH AMERICAN CORDILLERA , 1963 .

[47]  J. Gilluly The tectonic evolution of the western United States , 1963, Quarterly Journal of the Geological Society of London.

[48]  W. Hamilton Columbia River Basalt in the Riggins quadrangle, western Idaho , 1963 .

[49]  H. Malde,et al.  Reconnaissance geologic map of west-central Snake River plain, Idaho , 1963 .

[50]  John B. Shepard San Gabriel Fault Zone: GEOLOGICAL NOTES , 1962 .

[51]  W. Hamilton LATE CENOZOIC STRUCTURE OF WEST-CENTRAL IDAHO , 1962 .

[52]  P. D. Snavely,et al.  Tertiary Geologic History of Western Oregon and Washington: ABSTRACT , 1962 .

[53]  G. Leech Structure of the Bull River Valley Near Latitude 49° 35' , 1962 .

[54]  George Smith Large Lateral Displacement on Garlock Fault, Califonia, as Measured from Offset Dike Swarm , 1962 .

[55]  J. C. Crowell Displacement Along the San Andreas Fault, California , 1962 .

[56]  A. J. Eardley Structural Geology of North America , 1962 .

[57]  P. C. Bateman Willard D. Johnson and the strike-slip component of fault movement in the Owens Valley, California, earthquake of 1872 , 1961 .

[58]  W. Hamilton Origin of the Gulf of California , 1961 .

[59]  R. E. Warren,et al.  HORIZONTAL DISPLACEMENTS IN THE FLOOR OF THE NORTHEASTERN PACIFIC OCEAN , 1961 .

[60]  J. G. Moore,et al.  The Independence dike swarm in eastern California , 1961 .

[61]  J. Cameron Earthquakes in the northern California coastal region (part I) , 1961 .

[62]  D. L. Peck Geologic map of Oregon west of the 121st meridian , 1961 .

[63]  H. W. Menard The East Pacific Rise. , 1960, Science.

[64]  R. Schmalz The Sea Off Southern California , 1960 .

[65]  D. Tocher The Alaska earthquake of July 10, 1958: Movement on the Fairweather fault and field investigation of southern epicentral region , 1960 .

[66]  C. R. Allen,et al.  AGUA BLANCA FAULT—A MAJOR TRANSVERSE STRUCTURE OF NORTHERN BAJA CALIFORNIA, MEXICO , 1960 .

[67]  R. Brown,et al.  Geology of the Port Angeles-Lake Crescent area, Clallam County, Washington , 1960 .

[68]  P. B. King,et al.  The evolution of North America , 1978 .

[69]  L. Grose,et al.  STRUCTURE AND PETROLOGY OF THE NORTHEAST PART OF THE SODA MOUNTAINS, SAN BERNARDINO COUNTY, CALIFORNIA , 1959 .

[70]  G. Eiby The structure of New Zealand from seismic evidence , 1959 .

[71]  G. A. Thompson Gravity measurements between Hazen and Austin, Nevada: A study of basin‐range structure , 1959 .

[72]  G. Shor,et al.  San Miguel, Baja California Norte, earthquakes of February, 1956: A field report , 1958 .

[73]  A. Roberts,et al.  Geology and coal resources of the Centralia-Chehalis district, Washington, with a section on microscopical character of the Centralia-Chehalis coal , 1958 .

[74]  D. B. Slemmons,et al.  Geological effects of the Dixie Valley-Fairview Peak, Nevada, earthquakes of December 16, 1954 , 1957 .

[75]  C. Whitten Geodetic measurements in the Dixie Valley Area , 1957 .

[76]  P. St.-Amand Geological and geophysical synthesis of the tectonics of portions of British Columbia, the Yukon Territory, and Alaska , 1957 .

[77]  F. P. Shepard Northward continuation of the San Andreas Fault , 1957 .

[78]  A. Cox Remanent Magnetization of Lower to Middle Eocene Basalt Flows from Oregon , 1957, Nature.

[79]  C. R. Allen San Andreas fault zone in San Gorgonio Pass, Southern California , 1957 .

[80]  C. Whitten Crustal movement in California and Nevada , 1956 .

[81]  A. C. Waters GEOMORPHOLOGY OF SOUTH-CENTRAL WASHINGTON, ILLUSTRATED BY THE YAKIMA EAST QUADRANGLE , 1955 .

[82]  T. Dibblee,et al.  San Andreas, Garlock, and Big Pine Faults, California , 1953 .

[83]  J. C. Crowell Probable Large Lateral Displacement on San Gabriel Fault, Southern California , 1952 .

[84]  Robert E. Wallace,et al.  STRUCTURE OF A PORTION OF THE SAN ANDREAS RIFT IN SOUTHERN CALIFORNIA , 1949 .

[85]  C. R. Longwell A TECTONIC MAP OF THE UNITED STATES. , 1944, Science.

[86]  K. Emery,et al.  Submarine Topography off the California Coast: Canyons and Tectonic Interpretation , 1942 .

[87]  P. Billingsley,et al.  Sierra Nevada tectonic pattern , 1940 .

[88]  C. D. Campbell,et al.  Mylonites from the San Andreas fault zone , 1935 .

[89]  E. Callaghan,et al.  The Earthquake of December 20, 1932, at Cedar Mountain, Nevada and Its Bearing on the Genesis of Basin Range Structure , 1934, The Journal of Geology.

[90]  J. Gilluly Basin Range Faulting Along the Oquirrh Range, Utah , 1928 .

[91]  H. S. Selden Geologic map of North America , 2022 .

[92]  D. J. Dwight Geology of the Pacific , 1850 .