His main research concerns Scanning tunneling microscope, Oxide, Atomic physics, Condensed matter physics and Chemical physics. His Scanning tunneling microscope research incorporates elements of Crystallography and Adsorption. While the research belongs to areas of Oxide, Peter Varga spends his time largely on the problem of Corundum, intersecting his research to questions surrounding Single crystal, X-ray crystallography and Stereochemistry.
He has researched Atomic physics in several fields, including Interference and Sputtering. His research investigates the link between Condensed matter physics and topics such as Nanotechnology that cross with problems in Aluminum oxide and Metal. The concepts of his Chemical physics study are interwoven with issues in Heterogeneous catalysis, Lattice, Close-packing of equal spheres and Mineralogy.
Peter Varga mainly focuses on Scanning tunneling microscope, Atomic physics, Chemical physics, Crystallography and Sputtering. His study in Scanning tunneling microscope is interdisciplinary in nature, drawing from both Oxide and Adsorption. His Surface oxide study, which is part of a larger body of work in Oxide, is frequently linked to Vicinal, bridging the gap between disciplines.
His work in the fields of Atomic physics, such as Noble gas, overlaps with other areas such as Yield, Kinetic energy and Limiter. His work on Single crystal is typically connected to Ab initio quantum chemistry methods as part of general Crystallography study, connecting several disciplines of science. His Sputtering research is multidisciplinary, relying on both Projectile, Potential energy and Analytical chemistry.
Peter Varga focuses on Nanotechnology, Substrate, Scanning tunneling microscope, Analytical chemistry and Sputter deposition. His research on Substrate often connects related topics like Oxide. His study in Oxide is interdisciplinary in nature, drawing from both Corundum, Stereochemistry and Chemisorption.
In his study, which falls under the umbrella issue of Scanning tunneling microscope, Epitaxy and Nano- is strongly linked to Crystallography. His studies deal with areas such as Low-energy electron diffraction, Quantum tunnelling and Microscopy as well as Analytical chemistry. His work carried out in the field of Sputter deposition brings together such families of science as Pulsed laser deposition, Thermal deposition, Molecular physics and Metal.
Localized surface plasmon, Near and far field, Surface plasmon polariton, Optoelectronics and Electric field are his primary areas of study. His Localized surface plasmon research overlaps with Near-field optics, Field, Nanophotonics and Optics.
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Intrinsic defects on a TiO2(110)(1×1) surface and their reaction with oxygen: a scanning tunneling microscopy study
Ulrike Diebold;Jeremiah Lehman;Talib Mahmoud;Markus Kuhn.
Surface Science (1998)
Interaction of slow multicharged ions with solid surfaces
A. Arnau;F. Aumayr;P.M. Echenique;M. Grether.
Surface Science Reports (1997)
Structure of the ultrathin aluminum oxide film on NiAl(110).
Georg Kresse;Georg Kresse;Michael Schmid;Michael Schmid;Evelyn Napetschnig;Evelyn Napetschnig;Maxim Shishkin;Maxim Shishkin.
Two-dimensional oxide on Pd(111).
Edvin Lundgren;G Kresse;C Klein;Mikael Borg.
Physical Review Letters (2002)
Self-limited growth of a thin oxide layer on Rh(111).
Johan Gustafson;Anders Mikkelsen;Mikael Borg;Edvin Lundgren.
Physical Review Letters (2004)
POTENTIAL SPUTTERING OF LITHIUM FLUORIDE BY SLOW MULTICHARGED IONS
T. Neidhart;F. Pichler;F. Aumayr;H. P. Winter.
Physical Review Letters (1995)
Surface oxides on close-packed surfaces of late transition metals
Edvin Lundgren;Anders Mikkelsen;Jesper N Andersen;Georg Kresse.
Journal of Physics: Condensed Matter (2006)
Nanotemplate with holes: ultrathin alumina on Ni3Al(111).
M. Schmid;G. Kresse;A. Buchsbaum;E. Napetschnig.
Physical Review Letters (2007)
Atomic resolution by STM on ultra-thin films of alkali halides: experiment and local density calculations
W. Hebenstreit;J. Redinger;Z. Horozova;M. Schmid.
Surface Science (1999)
Adsorption sites and ligand effect for CO on an alloy surface: a direct view.
Y Gauthier;M. Schmid;S Padovani;Edvin Lundgren.
Physical Review Letters (2001)
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