227 research outputs found
Bulk Entanglement Spectrum Reveals Quantum Criticality within a Topological State
A quantum phase transition is usually achieved by tuning physical parameters
in a Hamiltonian at zero temperature. Here, we demonstrate that the ground
state of a topological phase itself encodes critical properties of its
transition to a trivial phase. To extract this information, we introduce a
partition of the system into two subsystems both of which extend throughout the
bulk in all directions. The resulting bulk entanglement spectrum has a
low-lying part that resembles the excitation spectrum of a bulk Hamiltonian,
which allows us to probe a topological phase transition from a single
wavefunction by tuning either the geometry of the partition or the entanglement
temperature. As an example, this remarkable correspondence between topological
phase transition and entanglement criticality is rigorously established for
integer quantum Hall states.Comment: 5 pages, 2 figures, 3 pages of Supplementary Materia
Majorana Fermion Surface Code for Universal Quantum Computation
We introduce an exactly solvable model of interacting Majorana fermions
realizing topological order with a fermion parity grading and
lattice symmetries permuting the three fundamental anyon types. We propose a
concrete physical realization by utilizing quantum phase slips in an array of
Josephson-coupled mesoscopic topological superconductors, which can be
implemented in a wide range of solid state systems, including topological
insulators, nanowires or two-dimensional electron gases, proximitized by
-wave superconductors. Our model finds a natural application as a Majorana
fermion surface code for universal quantum computation, with a single-step
stabilizer measurement requiring no physical ancilla qubits, increased error
tolerance, and simpler logical gates than a surface code with bosonic physical
qubits. We thoroughly discuss protocols for stabilizer measurements, encoding
and manipulating logical qubits, and gate implementations.Comment: 17 pages, 13 figure
Topological Crystalline Insulators and Dirac Octets in Anti-perovskites
We predict a new class of topological crystalline insulators (TCI) in the
anti-perovskite material family with the chemical formula ABX. Here the
nontrivial topology arises from band inversion between two quartets,
which is described by a generalized Dirac equation for a "Dirac octet". Our
work suggests that anti-perovskites are a promising new venue for exploring the
cooperative interplay between band topology, crystal symmetry and electron
correlation.Comment: Accepted as PRB Rapid Communication. 4 pages, 3 figures, 3 pages of
Supplementary Material. Typos fixe
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