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Three dimensional Dirac semimetals.

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Format:
Book
Thesis/Dissertation
Author/Creator:
Zaheer, Saad, author.
Contributor:
Mele, E. J. (Eugene J.), degree supervisor.
University of Pennsylvania. Physics and Astronomy.
Language:
English
Subjects (All):
Condensed matter physics.
Astronomy.
Quantum physics.
Astrophysics.
Physics and Astronomy--Penn dissertations.
Penn dissertations--Physics and Astronomy.
Local Subjects:
Condensed matter physics.
Astronomy.
Quantum physics.
Astrophysics.
Physics and Astronomy--Penn dissertations.
Penn dissertations--Physics and Astronomy.
Genre:
Academic theses.
Physical Description:
1 online resource (146 pages)
Contained In:
Dissertation Abstracts International 76-05B(E).
Place of Publication:
[Philadelphia, Pennsylvania] : University of Pennsylvania ; Ann Arbor, MI : ProQuest, 2014.
System Details:
Mode of access: World Wide Web.
text file
Summary:
We extend the physics of graphene to three dimensional systems by showing that Dirac points can exist on the Fermi surface of realistic materials in three dimensions. Many of the exotic electronic properties of graphene can be ascribed to the pseudorelativistic behavior of its charge carriers due to two dimensional Dirac points on the Fermi surface. We show that certain nonsymmorphic spacegroups exhibit Dirac points among the irreducible representations of the appropriate little group at high symmetry points on the surface of the Brillouin zone. We provide a list of all Brillouin zone momenta in the 230 spacegroups that can host Dirac points.
We describe microscopic considerations necessary to design materials in one of the candidate spacegroups such that the Dirac point appears at the Fermi energy without any additional non-Dirac-like Fermi pockets. We use density functional theory based methods to propose six new Dirac semimetals: BiO 2 and SbO2 in the beta-cristobalite lattice (spacegroup 227), and BiCaSiO4, BiMgSiO4, BiAlInO 4, and BiZnSiO4 in the distorted spinels lattice (spacegroup 74). Additionally we derive effective Dirac Hamiltonians given group representative operators as well as tight binding models incorporating spin-orbit coupling.
Finally we study the Fermi surface of zincblende (spacegroup 216) HgTe which is effectively point-like at Gamma in the Brillouin zone and exhibits accidental degeneracies along a threefold rotation axis. Whereas compressive strain gaps the band structure into a topological insulator, tensile strain shifts the accidental degeneracies away from Gamma and enlarges the Fermi surface. States on the Fermi surface exhibit nontrivial spin texture marked by winding of spins around the threefold rotation axis and by spin vortices indicating a change in the winding number. This is confirmed by microscopic calculations performed in tensile strained HgTe and Hg0.5Zn 0.5 Te as well as k.p theory.
We conclude with a summary of recent work on the physics of Dirac semimetals especially after the observation of the topological Dirac semimetals Cd 3As2 and Na3Bi and outline topics for future research. Symmetry protected Dirac semimetals, on the other hand, have yet to be observed experimentally.
Notes:
Source: Dissertation Abstracts International, Volume: 76-05(E), Section: B.
Adviser: Eugene J. Mele.
Department: Physics and Astronomy.
Thesis Ph.D. University of Pennsylvania 2014.
Local Notes:
School code: 0175.
ISBN:
9781321480504
Access Restriction:
Restricted for use by site license.

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