His primary scientific interests are in Condensed matter physics, Superconductivity, Nanotechnology, Carbon nanotube and Graphene. His Condensed matter physics study incorporates themes from Scattering and Photoemission spectroscopy. His Superconductivity study frequently links to other fields, such as Anisotropy.
His Nanotechnology research integrates issues from Optoelectronics and Oxide. His work is dedicated to discovering how Carbon nanotube, Chemical vapor deposition are connected with Analytical chemistry and other disciplines. His research in Graphene intersects with topics in Graphite and Transmission electron microscopy.
His primary areas of investigation include Condensed matter physics, Superconductivity, Antiferromagnetism, Magnetization and Doping. His Condensed matter physics study combines topics from a wide range of disciplines, such as Magnetic field and Anisotropy. His biological study spans a wide range of topics, including Angle-resolved photoemission spectroscopy and Phase, Phase diagram.
His work deals with themes such as Magnetic susceptibility, Spin-½, Spin and Ground state, which intersect with Antiferromagnetism. His study in Magnetization is interdisciplinary in nature, drawing from both Crystallography, Electron paramagnetic resonance and Paramagnetism. His Electronic structure research is multidisciplinary, incorporating perspectives in Photoemission spectroscopy and Electronic band structure.
His main research concerns Condensed matter physics, Superconductivity, Antiferromagnetism, Magnetization and Magnetism. Bernd Büchner combines subjects such as Ground state and Anisotropy with his study of Condensed matter physics. Bernd Büchner interconnects Spectroscopy, Spin valve, Spin, Liquid crystal and Electronic band structure in the investigation of issues within Superconductivity.
He focuses mostly in the field of Antiferromagnetism, narrowing it down to topics relating to Spintronics and, in certain cases, Topology. His studies examine the connections between Magnetization and genetics, as well as such issues in Electron paramagnetic resonance, with regards to Spins. The concepts of his Angle-resolved photoemission spectroscopy study are interwoven with issues in Fermi surface and Photoemission spectroscopy.
Condensed matter physics, Antiferromagnetism, Magnetism, Magnetization and Superconductivity are his primary areas of study. The various areas that Bernd Büchner examines in his Condensed matter physics study include Magnetic anisotropy, Magnetic field and Phase diagram. His Antiferromagnetism research incorporates themes from Electronic structure, Neutron diffraction, Quantum and Topological insulator.
His Electronic structure research includes elements of Photoemission spectroscopy and Density functional theory. As part of the same scientific family, Bernd Büchner usually focuses on Magnetization, concentrating on Relaxation and intersecting with Magnetic hysteresis. His studies deal with areas such as Phase transition, Doping and Liquid crystal as well as Superconductivity.
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Experimental realization of a three-dimensional Dirac semimetal.
Sergey Borisenko;Quinn Gibson;Danil Evtushinsky;Volodymyr Zabolotnyy.
Physical Review Letters (2014)
The electronic phase diagram of the LaO 1− x F x FeAs superconductor
H. Luetkens;H.-H. Klauss;M. Kraken;F. J. Litterst.
Nature Materials (2009)
Superconductivity without Nesting in LiFeAs
S. V. Borisenko;V. B. Zabolotnyy;D. V. Evtushinsky;T. K. Kim.
Physical Review Letters (2010)
Commensurate spin density wave in LaFeAsO: a local probe study.
H.-H. Klauss;H. Luetkens;R. Klingeler;C. Hess.
Physical Review Letters (2008)
Tunable Band Gap in Hydrogenated Quasi-Free-Standing Graphene
D. Haberer;D. V. Vyalikh;S. Taioli;B. Dora.
Nano Letters (2010)
Orbital-driven nematicity in FeSe
S. H. Baek;D. V. Efremov;J. M. Ok;J. S. Kim.
Nature Materials (2015)
Direct Low-Temperature Nanographene CVD Synthesis over a Dielectric Insulator
Mark H. Rümmeli;Alicja Bachmatiuk;Andrew Scott;Felix Börrnert.
ACS Nano (2010)
Atomic resolution imaging and topography of boron nitride sheets produced by chemical exfoliation.
Jamie H. Warner;Mark H. Rümmeli;Alicja Bachmatiuk;Bernd Büchner.
ACS Nano (2010)
Strength of the spin-fluctuation-mediated pairing interaction in a high-temperature superconductor
T. Dahm;V. Hinkov;S. V. Borisenko;A. A. Kordyuk.
Nature Physics (2009)
Magnon heat transport in (Sr,Ca,La) 14 Cu 24 O 41
C. Hess;C. Baumann;U. Ammerahl;B. Büchner.
Physical Review B (2001)
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