Dataset Identification:
Resource Abstract:
- description: This part of DS 781 presents data for faults for the geologic and geomorphic map of the Offshore of Salt Point
map area, California. The vector data file is included in "Faults_OffshoreSaltPoint.zip," which is accessible from
http://pubs.usgs.gov/ds/781/OffshoreSaltPoint/data_catalog_OffshoreSaltPoint.html. The onshore part of the Offshore of Salt
Point map area is cut by the northwest-trending San Andreas Fault, the right-lateral transform boundary between the North
American and Pacific tectonic plates. The San Andreas extends extends into the offshore about 5 km south of the map area near
Fort Ross, and about 50 km north of the map area on the east flank of Point Arena. The coast between Fort Ross and Point Arena,
the northwesternmost exposed section west of the San Andreas Fault, is known as the "Gualala Block" (fig. 1) on
the basis of its distinctive geology, which has been widely used to develop paleogeographic reconstructions of coastal California
that restore as much as 150 to 180 km of right-lateral slip on the combined San Andreas and San Gregorio Fault systems (see,
for example, Wentworth, (1968); Wentworth and others (1998); Jachens and others (1998); Dickinson and others (2005); Burnham
(2009). The Gualala Block is underlain by a thick (as much as 9 to 11 km, in aggregate), discontinuous Upper Cretaceous to
Miocene stratigraphic section (summarized in Wentworth and others, 1998), however only the Eocene and Paleocene German Rancho
Formation (unit Tgr) is exposed onshore and is inferred to form seafloor bedrock outcrops in the Offshore of Salt Point map
area. The German Rancho Formation consists of sandstone, mudstone, and conglomerate interpreted as deep-water, submarine-fan
deposits. The western boundary of the Gualala Block lies offshore. Using seismic-reflection data, McCulloch (1987; his fig.
14) mapped a shore-parallel fault about 3 to 5 km offshore, which Dickinson and others (2005) subsequently named the Gualala
Fault. Jachens and others (1998) evaluated aeromagnetic and gravity data across this zone and modeled this structure as a
steep fault within the Salinian basement block, characterized by 3 to 5 km of right-lateral offset. In contrast, Dickinson
and others (2005) consider the Gualala fault a Late Miocene strand of the San Andreas fault, separating Salinian and Franciscan
basement rocks, with minimum right-lateral slip of 70 km. Our analysis of deeper industry seismic-reflection data within California
State Waters shows the Gualala fault as a steep, northeast-dipping structure. Shallower seismic-reflection crossing the Gualala
fault reveal a thick late(?) Pleistocene section characterized by recent faulting and gentle asymmetric folding. Hence, the
Gualala fault appears to be a recently active "blind" structure that has deformed young sediments. Our mapping also
documents a more nearshore zone of deformation that we refer to as the "east Gualala deformation zone." This zone
extends through the central and southern parts of the Offshore of Salt Point map area and is similarly charcterized by steep
faults and gentle folds that deform inferred late Pleistocene strata. This section of the San Andreas Fault onland has an
estimated slip rate of about 17 to 25 mm/yr (Bryant and Lundberg, 2002). The devastating Great 1906 California earthquake
(M 7.8) is thought to have nucleated on the San Andreas Fault about 100 kilometers south of this map area offshore of San
Francisco (e.g., Bolt, 1968; Lomax, 2005), with the rupture extending northward through the onshore part of the Offshore of
Salt Point map area to the south flank of Cape Mendocino (Lawson, 1908; Brown and Wolfe, 1972). Emergent marine terraces along
the coast in the Offshore of Salt Point map area record recent contractional deformation associated with the San Andreas Fault
system. Prentice and Kelson (2006) reported uplift rates of 0.3 to 0.6 mm/yr for a nearby late Pleistocene terrace (exposed
at Fort Ross, about 5 km south of the map area) and this recent uplift must also have affected the nearshore and inner shelf,
at least as far west as the Gualala fault. Faults were primarily mapped by interpretation of seismic reflection profile data
(see field activity S-8-09-NC). The seismic reflection profiles were collected between 2007 and 2010. References Cited Bolt,
B.A., 1968, The focus of the 1906 California earthquake: Bulletin of the Seismological Society of America, v. 58, p. 457-471.
Brown, R.D., Jr., and Wolfe, E.W., 1972, Map showing recently active breaks along the San Andreas Fault between Point Delgada
and Bolinas Bay, California: U.S. Geological Survey Miscellaneous Investigations Map I-692, scale 1:24,000. Bryant, W.A.,
and Lundberg, M.M., compilers, 2002, Fault number 1b, San Andreas fault zone, North Coast section, in Quaternary fault and
fold database of the United States: U.S. Geological Survey website, accessed April 4, 2013 at http://earthquakes.usgs.gov/hazards/qfaults.
Burnham, K., 2009, Predictive model of San Andreas Fault system paleogeography, Late Cretaceous to early Miocene, derived
from detailed multidisciplinary conglomerate correlations: Tectonophysics 464, p. 195-208. Dickinson, W.R., Ducea, M., Rosenberg,
L.I., Greene, H.G., Graham, S.A., Clark, J.C., Weber, G.E., Kidder, S., Ernst, W.G., and Brabb, E.E., 2005, Net dextral slip,
Neogene San Gregorio-Hosgri Fault Zone, coastal California: Geologic evidence and tectonic implications: Geological Society
of America Special Paper 391, 43 p. Jachens, R.C., Wentworth, C.M., and McLaughlin, R.J., 1998, Pre-San Andreas location of
the Gualala Block inferred from magnetic and gravity anomalies, in Elder, W.P., ed., Geology and tectonics of the Gualala
block, northern California: Pacific Section, Society of Economic Paleontologists and Mineralogists, Book 84, p. 27-53. Lawson,
A.C., ed., 1908, The California earthquake of April 18, 1906, Report of the State Earthquake Investigation Commission: Carnegie
Institution of Washington Publication 87, v. 1, 1451 p. and atlas. Lomax, A., 2005, A reanalysis of the hypocentral location
and related observations for the Great 1906 California earthquake: Bulletin of the Seismological Society of America, v. 95,
p. 861-877. McCulloch, D.S., 1987, Regional geology and hydrocarbon potential of offshore central California, in Scholl, D.W.,
Grantz, A., and Vedder, J.G., eds., Geology and Resource Potential of the Continental Margin of Western North America and
Adjacent Oceans€”Beaufort Sea to Baja California: Houston, Texas, Circum-Pacific Council for Energy and Mineral
Resources, Earth Science Series, v. 6., p. 353-401. Prentice, C.S., and Kelson, K.I., 2006, The San Andreas fault in Sonoma
and Mendocino counties, in Prentice, C.S., Scotchmoor, J.G., Moores, E.M., and Kiland, J.P., eds., 1906 San Francisco Earthquake
Centennial Field Guides: Field trips associated with the 100th Anniversary Conference, 18-23 April 2006, San Francisco, California:
Geological Society of America Field Guide 7, p. 127-156, Wentworth, C.M., 1968, Upper Cretaceous and lower Tertiary strata
near Gualala, California, and inferred large right slip on the San Andreas fault, in Dickinson, W.R., and Grantz, A., eds.
Proceedings of conference on geologic problems of San Andreas fault system: Stanford University Publications, Geological Sciences,
v. 11, p. 130-143. Wentworth, C.M., Jones, D.L., and Brabb, E.E., 1998, Geology and regional correlation of the Cretaceous
and Paleogene rocks of the Gualala block, California, in Elder, W.P., ed., Geology and tectonics of the Gualala block, northern
California: Pacific Section, Society of Economic Paleontologists and Mineralogists, Book 84, p. 3-26.; abstract: This part
of DS 781 presents data for faults for the geologic and geomorphic map of the Offshore of Salt Point map area, California.
The vector data file is included in "Faults_OffshoreSaltPoint.zip," which is accessible from http://pubs.usgs.gov/ds/781/OffshoreSaltPoint/data_catalog_OffshoreSaltPoint.html.
The onshore part of the Offshore of Salt Point map area is cut by the northwest-trending San Andreas Fault, the right-lateral
transform boundary between the North American and Pacific tectonic plates. The San Andreas extends extends into the offshore
about 5 km south of the map area near Fort Ross, and about 50 km north of the map area on the east flank of Point Arena. The
coast between Fort Ross and Point Arena, the northwesternmost exposed section west of the San Andreas Fault, is known as the
"Gualala Block" (fig. 1) on the basis of its distinctive geology, which has been widely used to develop paleogeographic
reconstructions of coastal California that restore as much as 150 to 180 km of right-lateral slip on the combined San Andreas
and San Gregorio Fault systems (see, for example, Wentworth, (1968); Wentworth and others (1998); Jachens and others (1998);
Dickinson and others (2005); Burnham (2009). The Gualala Block is underlain by a thick (as much as 9 to 11 km, in aggregate),
discontinuous Upper Cretaceous to Miocene stratigraphic section (summarized in Wentworth and others, 1998), however only the
Eocene and Paleocene German Rancho Formation (unit Tgr) is exposed onshore and is inferred to form seafloor bedrock outcrops
in the Offshore of Salt Point map area. The German Rancho Formation consists of sandstone, mudstone, and conglomerate interpreted
as deep-water, submarine-fan deposits. The western boundary of the Gualala Block lies offshore. Using seismic-reflection data,
McCulloch (1987; his fig. 14) mapped a shore-parallel fault about 3 to 5 km offshore, which Dickinson and others (2005) subsequently
named the Gualala Fault. Jachens and others (1998) evaluated aeromagnetic and gravity data across this zone and modeled this
structure as a steep fault within the Salinian basement block, characterized by 3 to 5 km of right-lateral offset. In contrast,
Dickinson and others (2005) consider the Gualala fault a Late Miocene strand of the San Andreas fault, separating Salinian
and Franciscan basement rocks, with minimum right-lateral slip of 70 km. Our analysis of deeper industry seismic-reflection
data within California State Waters shows the Gualala fault as a steep, northeast-dipping structure. Shallower seismic-reflection
crossing the Gualala fault reveal a thick late(?) Pleistocene section characterized by recent faulting and gentle asymmetric
folding. Hence, the Gualala fault appears to be a recently active "blind" structure that has deformed young sediments.
Our mapping also documents a more nearshore zone of deformation that we refer to as the "east Gualala deformation zone."
This zone extends through the central and southern parts of the Offshore of Salt Point map area and is similarly charcterized
by steep faults and gentle folds that deform inferred late Pleistocene strata. This section of the San Andreas Fault onland
has an estimated slip rate of about 17 to 25 mm/yr (Bryant and Lundberg, 2002). The devastating Great 1906 California earthquake
(M 7.8) is thought to have nucleated on the San Andreas Fault about 100 kilometers south of this map area offshore of San
Francisco (e.g., Bolt, 1968; Lomax, 2005), with the rupture extending northward through the onshore part of the Offshore of
Salt Point map area to the south flank of Cape Mendocino (Lawson, 1908; Brown and Wolfe, 1972). Emergent marine terraces along
the coast in the Offshore of Salt Point map area record recent contractional deformation associated with the San Andreas Fault
system. Prentice and Kelson (2006) reported uplift rates of 0.3 to 0.6 mm/yr for a nearby late Pleistocene terrace (exposed
at Fort Ross, about 5 km south of the map area) and this recent uplift must also have affected the nearshore and inner shelf,
at least as far west as the Gualala fault. Faults were primarily mapped by interpretation of seismic reflection profile data
(see field activity S-8-09-NC). The seismic reflection profiles were collected between 2007 and 2010. References Cited Bolt,
B.A., 1968, The focus of the 1906 California earthquake: Bulletin of the Seismological Society of America, v. 58, p. 457-471.
Brown, R.D., Jr., and Wolfe, E.W., 1972, Map showing recently active breaks along the San Andreas Fault between Point Delgada
and Bolinas Bay, California: U.S. Geological Survey Miscellaneous Investigations Map I-692, scale 1:24,000. Bryant, W.A.,
and Lundberg, M.M., compilers, 2002, Fault number 1b, San Andreas fault zone, North Coast section, in Quaternary fault and
fold database of the United States: U.S. Geological Survey website, accessed April 4, 2013 at http://earthquakes.usgs.gov/hazards/qfaults.
Burnham, K., 2009, Predictive model of San Andreas Fault system paleogeography, Late Cretaceous to early Miocene, derived
from detailed multidisciplinary conglomerate correlations: Tectonophysics 464, p. 195-208. Dickinson, W.R., Ducea, M., Rosenberg,
L.I., Greene, H.G., Graham, S.A., Clark, J.C., Weber, G.E., Kidder, S., Ernst, W.G., and Brabb, E.E., 2005, Net dextral slip,
Neogene San Gregorio-Hosgri Fault Zone, coastal California: Geologic evidence and tectonic implications: Geological Society
of America Special Paper 391, 43 p. Jachens, R.C., Wentworth, C.M., and McLaughlin, R.J., 1998, Pre-San Andreas location of
the Gualala Block inferred from magnetic and gravity anomalies, in Elder, W.P., ed., Geology and tectonics of the Gualala
block, northern California: Pacific Section, Society of Economic Paleontologists and Mineralogists, Book 84, p. 27-53. Lawson,
A.C., ed., 1908, The California earthquake of April 18, 1906, Report of the State Earthquake Investigation Commission: Carnegie
Institution of Washington Publication 87, v. 1, 1451 p. and atlas. Lomax, A., 2005, A reanalysis of the hypocentral location
and related observations for the Great 1906 California earthquake: Bulletin of the Seismological Society of America, v. 95,
p. 861-877. McCulloch, D.S., 1987, Regional geology and hydrocarbon potential of offshore central California, in Scholl, D.W.,
Grantz, A., and Vedder, J.G., eds., Geology and Resource Potential of the Continental Margin of Western North America and
Adjacent Oceans€”Beaufort Sea to Baja California: Houston, Texas, Circum-Pacific Council for Energy and Mineral
Resources, Earth Science Series, v. 6., p. 353-401. Prentice, C.S., and Kelson, K.I., 2006, The San Andreas fault in Sonoma
and Mendocino counties, in Prentice, C.S., Scotchmoor, J.G., Moores, E.M., and Kiland, J.P., eds., 1906 San Francisco Earthquake
Centennial Field Guides: Field trips associated with the 100th Anniversary Conference, 18-23 April 2006, San Francisco, California:
Geological Society of America Field Guide 7, p. 127-156, Wentworth, C.M., 1968, Upper Cretaceous and lower Tertiary strata
near Gualala, California, and inferred large right slip on the San Andreas fault, in Dickinson, W.R., and Grantz, A., eds.
Proceedings of conference on geologic problems of San Andreas fault system: Stanford University Publications, Geological Sciences,
v. 11, p. 130-143. Wentworth, C.M., Jones, D.L., and Brabb, E.E., 1998, Geology and regional correlation of the Cretaceous
and Paleogene rocks of the Gualala block, California, in Elder, W.P., ed., Geology and tectonics of the Gualala block, northern
California: Pacific Section, Society of Economic Paleontologists and Mineralogists, Book 84, p. 3-26.
Citation
- Title Faults--Offshore of Salt Point Map Area, California.
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- creation Date
2018-05-20T00:09:03.703921
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2018-08-06T23:56:10Z
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on a transform by Damian Ulbricht. Run on 2018-08-06T23:56:10Z
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