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Earth, J. (2021).
Resolving sedimentology, stratigraphic architecture and evolution of deep-water systems in two structurally complex areas: the Upper Cretaceous Pigeon Point Formation, California, and the Oligocene Molasse Basin, Austria
.
A comparison of the Upper Cretaceous Pigeon Point Formation, northern California, and the Gold Beach Terrane, southwest Oregon, USA: Unrelated stratigraphic sequences or parts of a single now-dismembered Cretaceous basinal sequence.
. (2020).
Characterizing the Orosirian Earth System
. (2020).
From Forearc to Transform: Sedimentary Record of Changing Tectonic Setting in the Central California and Eastern Zealandia Continental Margins
. (2020).
Sedimentology of proximal and distal deep-water deposits: Syn-rift deposits of the Burqan Formation, Saudi Arabia and slurry-flow deposits of the Wilcox Formation, Gulf of Mexico and the Tyee Formation, Oregon
. (2019).
Sedimentology, stratigraphy, and provenance at Bolsa Point, Pigeon Point Formation, California, USA
. (2019).
AlKawai, . (2018).
The impact of the allochthonous salt and overpressure development on the petroleum system evolution in the thunder horse mini-basin, Gulf of Mexico.
.
Sickmann, . (2018).
Understanding provenance signatures in active margin settings: Modern central California and the Magallanes-Austral Foreland Basin, southern Patagonia
.
Hernandez, . (2017).
Sedimentology and depositing setting of deep-water deposits of the Pennsylvanian Jackfork Group, Arkansas and the Paleogene Wilcox Formation, Mexico
.
Nieminski, . (2017).
SEDIMENTOLOGY, STRATIGRAPHIC ARCHITECTURE, AND PROVENANCE OF DEEP-WATER SYSTEMS: NEOPROTEROZOIC ZERRISSENE GROUP, NAMIBIA AND NEOGENE EAST COAST BASIN, NEW ZEALAND
.
Kremer, . (2017).
Transversely-sourced mass-transport deposits and stratigraphicevolution of a foreland submarine channel system: Deep-water tertiary strata of the Austrian Molasse Basin
.
Harrington, . (2017).
Using sedimentology and provenance studies to determine depositional relationships between three structural belts of the ca. 3.22 GA Fig Tree Group, Barberton Greenstone Belt, South Africa
.
Gungor, . (2016).
Sedimentology and stratigraphy of a part of the Upper Cretaceous Pigeon Point Formation, San Mateo County, California
.
Shumaker, . (2016).
Sedimentology, seismic geomorphology, and provenance investigations of deep-water deposits: Taranaki Basin, New Zealand
.
Insights into the growth and decay of orogenic wedges from foreland basin successions
. (2015).
Sharman, . (2014).
PROVENANCE, PALEOGEOGRAPHY, AND MASS-MOVEMENT OF DEEPWATER DEPOSITIONAL SYSTEMS IN ARC-ADJACENT BASINS: THE CRETACEOUS-PALEOGENE CALIFORNIA FOREARC AND UPPER MIOCENE MOHAKATINO FORMATION, NEW ZEALAND
.
Burgreen, . (2014).
The influence of convergent margin structure on deep-water stratigraphic architecture, pore pressure evolution, and source rock maturation in the East Coast Basin, New Zealand
.
Rotzien, . (2013).
Pliocene Pico and Repetto Formations, Ventura Basin, California; Sedimentology, Stratigraphy, and Provenance of the upper Mount Messenger Formation, Taranaki Basin, New Zealand.
.
Masalimova, . (2013).
Stratigraphic architecture and flow dynamics of deep-water turbidite deposits: the Miocene lower Mount Messenger Formation in the Taranaki Basin in New Zealand, and the Oligocene Puchkirchen Formation in the Molasse Basin in Austria
.
Depositional architecture of deep-water slope systems: Examples from the Quaternary Lucia Chica channel system
. (2012).
Fosdick, . (2011).
Linking orogenic deformation, exhumation, and basin evolution in the Patagonian Andes 7and Magallanes Basin, southermost South America
.
Stright, . (2011).
Multiscale modeling of deep-water channel deposits: An interdisciplinary study integrating geostatistics, geology and geophysics, the Cretaceous Cerro Toro Formation
.
Mitchell, . (2011).
Subduction complex uplift and exhumation and its influence on Maastrichtian forearc stratigraphy in the Great Valley Basin, northern San Joaquin Valley, California
.
Multi-scale architectural evolution and flow property characterization of channelized turbidite systems
. (2010).
Temeng, . (2009).
Distributary channel development of the Newport submarine canyon-channel system, southern California Borderland
.
Armitage, . (2009).
High-resolution architectural evolution of depositional elements in deep-marine slope environments: The Quaternary Niger Delta slope
.
Romans, . (2008).
Controls on distribution, timing, and evolution of turbidite systems in tectonically active settings: The Cretaceous Tres Pasos Formation, southern Chile
.
Covault, . (2008).
Development of turbidite architecture on tectonically active continental margins: Multiscale investigation of the Quaternary California Borderland
.
Offshore Red River Fault and slope sediments in northern South China Sea: Implications for Paleoceanography and uplift of the Tibet Plateau
. (2007).
Stright, . (2006).
Coupled Geological Modeling and History Matching of Fine-Scale Curvilinear Flow Barriers and Large Scale Facies Bodies
.
Hubbard, . (2006).
Deep-water foreland basin axial channels and associated sediment gravity flow deposits, Oligocene Molasse Basin, Upper Austria, and Cretaceous Magallanes Basin, Chile
.
Sedimentology and architecture of Upper Eocene deep-water deposits, Talara Basin, NW Peru
. (2005).
Fildani, . (2004).
Analysis of two arc-associated basins and onset of their deep-water stages: Magallanes Basin, Chile, and Talara Basin, Peru
.
Crane, . (2004).
Depositional history of the Upper Cretaceous Cerro Toro Formation, Silla Syncline, Magallanes Basin, Chile
.
Shultz, . (2004).
Stratigraphic architecture of two deep-water depositional systems: The Tres Pasos formation, Chilean Patagonia, and the Stevens Sandstone, Elk Hills
.
Architecture and depositional controls of deep-water deposits as imaged by near-surface 3-D seismic data, Niger Delta, Nigeria
. (2003).
Sylvester, . (2001).
Facies, architecture, and bed-thickness structure of turbidite systems: Examples from the East Carpathian flysch, Romania, and the Great Valley Group, California
.
Felix, . (2001).
Two-dimensional turbidity current model
.
Combining rock physics and sedimentology for seismic reservoir characterization of North Sea turbidite systems
. (2000).
A study of deep-water deposition: Constraints on the sedimentation mechanics of slurry flows and high concentration turbidity currents
. (1999).
Anderson, . (1998).
Facies architecture of two Paleogene structurally-controlled turbidite systems, central California
.
Mason, . (1998).
Internal facies architecture of a sand-rich, deep-water depositional system: The Rocks Sandstone, Reliz Canyon Formation, northern Santa Lucia Range, Monterey County, California M.S. thesis, Stanford University, 100 p.
.
Stites, . (1998).
Rock physics, sedimentology and petrography of a turbidity current deposit: An interdisciplinary approach
.
Basin-fill architecture and forearc tectonics, Cretaceous Great Valley Group, Sacramento basin, northern California
. (1997).
Aspects of the deposition and depositional architecture of the Upper Miocene Stevens deep-water depositional system, southern San Joaquin Basin, Kern County, California
. (1995).
Analysis of vertical cyclicity patterns in two sediment gravity flow sequences
. (1994).
Analysis of bed thickness and grain size patterns in a turbidite section from the Great Valley Sequence, Cache Creek, Northern California
. (1992).
Numerical simulation of turbidity current flow and sedimentation
. (1992).
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