Dr. Alexey Petrunin
Developing innovative multidisciplinary approaches linking the dynamics of the Earth’s interior to a wide range of surface processes and observables (i.e., sedimentary basins dynamics, lithospheric deformation, multiphase heat-mass transfer, sedimentation, heat flow, GPS measurements, satellite and seismic data, etc.).
Developing numerical codes for the thermo-mechanical modeling of the Earth dynamics and surface processes acounting for the non-linear visco-elasto-plastic rheology, magma transport, surface erosion, fluid filtration, and free surface.
Tectonic deformations and crustal mass flux, lithospheric thermal state analysis, heat flow, rheology, interaction between the deep-mantle and surface processes, seismicity, long- and short-term lithospheric stress state analysis.
Numerical models developing with the use of finite elements (FEM), finite differences (FDM), finite volumes (FVM) and spectral (SM), and AI/ML methods.
Petrunin, A. G., Kaban, M. K., El Khrepy, S., Al‐Arifi, N. (2020): Mantle Convection Patterns Reveal the Mechanism of the Red Sea Rifting, Tectonics, 39, 2, e2019TC005829. https://doi.org/10.1029/2019TC005829
Rogozhina, I., A. G. Petrunin, A. P. M. Vaughan, B. Steinberger, J. V. Johnson, M. K. Kaban, R. Calov, F. Rickers, M. Thomas, and I. Koulakov (2016), Melting at the base of the Greenland ice sheet explained by Iceland hotspot history, Nature Geoscience, 9(5), 366–369, doi:10.1038/ngeo2689.
Kaban, M. K., W. D. Mooney, and A. G. Petrunin (2015), Cratonic root beneath North America shifted by basal drag from the convecting mantle, Nature Geoscience, 8(10), 797–800, doi:10.1038/ngeo2525.
Petrunin, A. G., I. Rogozhina, a. P. M. Vaughan, I. T. Kukkonen, M. K. Kaban, I. Koulakov, and M. Thomas (2013), Heat flux variations beneath central Greenland’s ice due to anomalously thin lithosphere, Nature Geoscience, 6, 746–750, doi:10.1038/ngeo1898.
Petrunin, A. G., M. K. Kaban, I. Rogozhina, and V. Trubitsyn (2013), Revising the spectral method as applied to modeling mantle dynamics, Geochemistry, Geophys. Geosystems, 14(9), 3691–3702, doi:10.1002/ggge.20226.
Petrunin A.G. , E. Meneses Rioseco and S.V. Sobolev (2012) Thermo-mechanical model reconciles contradictory geophysical observations at the Dead Sea Basin., Geochem. Geophys. Geosyst., v. 13, Q04011, 15 pp., doi:10.1029/2011GC003929
Sobolev, S. V., A. V. Sobolev, D. V. Kuzmin, N. A. Krivolutskaya, A. G. Petrunin, N. T. Arndt, V. A. Radko, and Y. R. Vasiliev (2011), Linking mantle plumes, large igneous provinces and environmental catastrophes, Nature, 477(7364), 312-316, doi:10.1038/nature10385.
Petrunin, A. G., and S. V. Sobolev (2008), Three-dimensional numerical models of the evolution of pull-apart basins, Physics of the Earth and Planetary Interiors, 171(1-4), 387-399, doi:10.1016/j.pepi.2008.08.017.
Petrunin, A.G., and S. V. Sobolev (2006), What controls thickness of sediments and lithospheric deformation at a pull-apart basin?, Geology, 34(5), 389, doi:10.1130/G22158.1.
Ongoing project (Co-PI):
Study of Earth dynamics with a constellation of potential field missions (MANTIS, SPP 1788). The project is designed around the ESA magnetic field satellite mission SWARM.
DFG personal grant (PI):
Evaluation of stress and strain rates in the lithosphere of Europe based on high resolution thermo-mechanical model coupled with mantle convection model.
Inverse and forward multiscale numerical modeling of the Alpine orogeny (IFMMALPO, SPP 2017).
As a PostDoc: