Dietmar Müller
Müller, Dietmar 1959-
Müller, Dietmar
VIAF ID: 1276157100614772740005 (Personal)
Permalink: http://viaf.org/viaf/1276157100614772740005
Preferred Forms
- 100 0 _ ‡a Dietmar Müller
- 100 1 _ ‡a Müller, Dietmar
- 100 1 _ ‡a Müller, Dietmar ‡d 1959-
4xx's: Alternate Name Forms (3)
5xx's: Related Names (4)
- 551 _ _ ‡a Kiel ‡4 ortw ‡4 https://d-nb.info/standards/elementset/gnd#placeOfActivity
- 551 _ _ ‡a San Diego, Calif. ‡4 ortw ‡4 https://d-nb.info/standards/elementset/gnd#placeOfActivity
- 551 _ _ ‡a Sydney ‡4 ortw ‡4 https://d-nb.info/standards/elementset/gnd#placeOfActivity
- 510 2 _ ‡a University of Sydney ‡4 affi ‡4 https://d-nb.info/standards/elementset/gnd#affiliation ‡e Affiliation
Works
Title | Sources |
---|---|
Large fluctuations of shallow seas in low-lying Southeast Asia driven by mantle flow | |
The link between great earthquakes and the subduction of oceanic fracture zones | |
LithoPlates - a new deep-time reconstruction community service provided by the AusGeochem data platform | |
Long-term interaction between mid-ocean ridges and mantle plumes | |
Long-term Phanerozoic sea level change from solid Earth processes | |
Mantle dynamics of continentwide Cenozoic subsidence and tilting of Australia | |
Mantle plumes and their role in Earth processes | |
Marine geophysics. New global marine gravity model from CryoSat-2 and Jason-1 reveals buried tectonic structure. | |
Mesozoic/Cenozoic tectonic events around Australia | |
Middle Miocene tectonic boundary conditions for use in climate models | |
Miocene drainage reversal of the Amazon River driven by plate–mantle interaction | |
Modeling the Dynamic Landscape Evolution of a Volcanic Coastal Environment Under Future Climate Trajectories | |
Modelling thermal lithospheric thickness along the conjugate South Atlantic passive margins implies asymmetric rift initiation | |
Models of mantle convection incorporating plate tectonics: The Australian region since the Cretaceous | |
Multicore Parallel Tempering Bayeslands for Basin and Landscape Evolution | |
Multiobjective Bayesian optimization and joint inversion for active sensor fusion | |
No Evidence for Milankovitch Cycle Influence on Abyssal Hills at Intermediate, Fast, and Superfast Spreading Rates | |
Oblique rifting: the rule, not the exception | |
Ocean Basin Evolution and Global-Scale Plate Reorganization Events Since Pangea Breakup | |
Oceanic crustal carbon cycle drives 26-million-year atmospheric carbon dioxide periodicities. | |
Oceanic microplate formation records the onset of India–Eurasia collision | |
Oceanic Residual Topography Agrees With Mantle Flow Predictions at Long Wavelengths | |
On the Scales of Dynamic Topography in Whole-Mantle Convection Models | |
An open-source software environment for visualizing and refining plate tectonic reconstructions using high-resolution geological and geophysical data sets | |
Organization of the tectonic plates in the last 200Myr | |
Origin and evolution of the deep thermochemical structure beneath Eurasia | |
Origin of Indian Ocean Seamount Province by shallow recycling of continental lithosphere | |
Paleobathymetry reconstructions during the Mesozoic and uncertainties in oceanic gateway evolution | |
Paleophysiography of Ocean Basins | |
Papanin Ridge and Ojin Rise Seamounts (Northwest Pacific): Dual Hotspot Tracks Formed by the Shatsky Plume | |
Past and present seafloor age distributions and the temporal evolution of plate tectonic heat transport | |
Plate tectonics and Earth System Science | |
Post-extinction recovery of the Phanerozoic oceans and the rise of biodiversity hotspots | |
Potential encoding of coupling between Milankovitch forcing and Earth's interior processes in the Phanerozoic eustatic sea-level record | |
Potential links between continental rifting, CO2 degassing and climate change through time | |
Precipitation reconstruction from climate-sensitive lithologies using Bayesian machine learning | |
Predicting Sediment Thickness on Vanished Ocean Crust Since 200 Ma | |
Predicting the emplacement of Cordilleran porphyry copper systems using a spatio-temporal machine learning model | |
Provenance of plumes in global convection models | |
PyBacktrack 1.0: A Tool for Reconstructing Paleobathymetry on Oceanic and Continental Crust | |
Reconstructing seafloor age distributions in lost ocean basins | |
Reconstructing slab dip through deep time to explain pulses in kimberlite eruptions | |
A reconstruction of the Eurekan Orogeny incorporating deformation constraints | |
Response to Comment on "Major Australian-Antarctic Plate Reorganization at Hawaiian-Emperor Bend Time" | |
A review of machine learning in processing remote sensing data for mineral exploration | |
Revised plate motions relative to the hotspots from combined Atlantic and Indian Ocean hotspot tracks | |
Revision of Paleogene plate motions in the Pacific and implications for the Hawaiian-Emperor bend: REPLY | |
Ridge-spotting: A new test for Pacific absolute plate motion models | |
Ridge subduction sparked reorganization of the Pacific plate-mantle system 60-50 million years ago | |
The role of deep Earth dynamics in driving the flooding and emergence of New Guinea since the Jurassic | |
The role of oceanic plateau subduction in the Laramide orogeny | |
Sea-level fluctuations driven by changes in global ocean basin volume following supercontinent break-up | |
Seismic stratigraphy of the Adare Trough area, Antarctica | |
Semiautomatic fracture zone tracking | |
Sequestration and subduction of deep-sea carbonate in the global ocean since the Early Cretaceous | |
The shape of biodiversity through deep time: fossils vs. mechanistic models | |
Simulation of the Middle Miocene Climate Optimum | |
Some surface expressions of mantle convective instabilities | |
Subduction controls the distribution and fragmentation of Earth’s tectonic plates | |
Subduction history reveals Cretaceous slab superflux as a possible cause for the mid-Cretaceous plume pulse and superswell events | |
A suite of early Eocene | |
Supplemental Material: Deep-sea hiatuses track the vigor of Cenozoic ocean bottom currents | |
Supplemental Material: The carbonate compensation depth in the South Atlantic Ocean since the Late Cretaceous | |
Supplementary material to "A tectonic-rules based mantle reference frame since 1 billion years ago – implications for supercontinent cycles and plate-mantle system evolution" | |
Supplementary material to "Arc volcanism, carbonate platform evolution and palaeo-atmospheric CO<sub>2</sub>: Components and interactions in the deep carbon cycle" | |
Supplementary material to "Improving global paleogeography since the late Paleozoic using paleobiology" | |
Supplementary material to "Kinematics and extent of the Piemont-Liguria Basin – implications for subduction processes in the Alps" | |
Surrogate-assisted Bayesian inversion for landscape and basin evolution models | |
Tectonic environments of South American porphyry copper magmatism through time revealed by spatiotemporal data mining | |
The tectonic evolution of the Arctic since Pangea breakup: Integrating constraints from surface geology and geophysics with mantle structure | |
Tectonic evolution of Western Tethys from Jurassic to present day: coupling geological and geophysical data with seismic tomography models | |
The tectonic fabric of the ocean basins | |
Tectonic speed limits from plate kinematic reconstructions | |
Tectonostratigraphic development of the Upper Triassic to Middle Jurassic in the Hoop Area, Barents Sea: Implications for understanding ultra-condensed reservoir units | |
Topographic asymmetry of the South Atlantic from global models of mantle flow and lithospheric stretching | |
Towards community-driven paleogeographic reconstructions: integrating open-access paleogeographic and paleobiology data with plate tectonics | |
Tracing the global consumption of carbon at subduction zones over the last 230 million years | |
Vigorous deep-sea currents cause global anomaly in sediment accumulation in the Southern Ocean |