Fellow of the Geological Society of America
Geochemistry, Mineralogy, Pegmatite, Solidus and Crystallization are his primary areas of study. His Geochemistry research integrates issues from Leucogranite and Bearing. His studies deal with areas such as Tourmaline, Albite and Muscovite as well as Leucogranite.
His research integrates issues of Thermal diffusivity, δ13C, Partial melting and Magmatic water in his study of Mineralogy. Peter I. Nabelek usually deals with Pegmatite and limits it to topics linked to Fractional crystallization and Supercooling, Magma chamber, Felsic, Protolith and Continental crust. His Crystallization study integrates concerns from other disciplines, such as Hydrogen isotope, Fluid inclusions and Silicate.
His primary scientific interests are in Geochemistry, Mineralogy, Metamorphism, Metamorphic rock and Pegmatite. His research in Geochemistry intersects with topics in Leucogranite and Biotite. His Mineralogy research includes themes of Muscovite, Thermal diffusivity, Basalt and Crystallization.
While the research belongs to areas of Metamorphism, he spends his time largely on the problem of Partial melting, intersecting his research to questions surrounding Protolith. His work focuses on many connections between Metamorphic rock and other disciplines, such as Magmatic water, that overlap with his field of interest in Phlogopite. The Pegmatite study combines topics in areas such as Tourmaline, Fluid inclusions, Fractional crystallization and Continental crust.
The scientist’s investigation covers issues in Geochemistry, Range, Schist, Fluid inclusions and Quartz. His Geochemistry study frequently links to adjacent areas such as Recrystallization. His Range study combines topics in areas such as Petrology and Magma.
His work carried out in the field of Schist brings together such families of science as Mineralogy and Isotopes of oxygen. The various areas that Peter I. Nabelek examines in his Fluid inclusions study include Tourmaline and Inclusion. His research on Quartz often connects related topics like Pegmatite.
Peter I. Nabelek mainly focuses on Geochemistry, Victoria island, Mainland China, Supergroup and Basalt. In general Geochemistry, his work in Tourmaline is often linked to Intrusion linking many areas of study. His studies deal with areas such as Inclusion and Hydrothermal circulation, Fluid inclusions as well as Tourmaline.
Peter I. Nabelek performs multidisciplinary study in Victoria island and Sill in his work. His Recrystallization study integrates concerns from other disciplines, such as Metamorphism, Dolomite, Diagenesis and Calcite. His Isograd research covers fields of interest such as Isotope geochemistry, Mineralogy and Metamorphic rock.
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Temperature-dependent thermal diffusivity of the Earth’s crust and implications for magmatism
Alan G. Whittington;Anne M. Hofmeister;Peter I. Nabelek.
Iron, zinc, magnesium and uranium isotopic fractionation during continental crust differentiation: The tale from migmatites, granitoids, and pegmatites
Myriam Telus;Nicolas Dauphas;Frédéric Moynier;François L.H. Tissot.
Geochimica et Cosmochimica Acta (2012)
Contrasting fluid/rock interaction between the Notch Peak granitic intrusion and argillites and limestones in western Utah: evidence from stable isotopes and phase assemblages
P. I. Nabelek;T. C. Labotka;J. R. O'Neil;J. J. Papike.
Contributions to Mineralogy and Petrology (1984)
The generation and crystallization conditions of the Proterozoic Harney Peak Leucogranite, Black Hills, South Dakota, USA: Petrologic and geochemical constraints
P. I. Nabelek;P. I. Nabelek;C. Russ-Nabelek;J. R. Denison.
Contributions to Mineralogy and Petrology (1992)
Strain heating as a mechanism for partial melting and ultrahigh temperature metamorphism in convergent orogens: Implications of temperature-dependent thermal diffusivity and rheology
Peter I. Nabelek;Alan G. Whittington;Anne M. Hofmeister.
Journal of Geophysical Research (2010)
The influence of temperature-dependent thermal diffusivity on the conductive cooling rates of plutons and temperature-time paths in contact aureoles
Peter I. Nabelek;Anne M. Hofmeister;Alan G. Whittington.
Earth and Planetary Science Letters (2012)
The role of H2O in rapid emplacement and crystallization of granite pegmatites: resolving the paradox of large crystals in highly undercooled melts
Peter I. Nabelek;Alan G. Whittington;Mona Liza C. Sirbescu.
Contributions to Mineralogy and Petrology (2010)
Crustal melts below 400 °C
Mona Liza C. Sirbescu;Peter I. Nabelek.
Petrologic and thermal constraints on the origin of leucogranites in collisional orogens
Peter I. Nabelek;Mian Liu.
Transactions of The Royal Society of Edinburgh-earth Sciences (2004)
Stable isotope monitors
Peter I. Nabelek.
Reviews in Mineralogy & Geochemistry (1991)
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