1,077 research outputs found
Dirac nodal line metal for topological antiferromagnetic spintronics
Topological antiferromagnetic (AFM) spintronics is an emerging field of
research, which exploits the N\'eel vector to control the topological
electronic states and the associated spin-dependent transport properties. A
recently discovered N\'eel spin-orbit torque has been proposed to electrically
manipulate Dirac band crossings in antiferromagnets; however, a reliable AFM
material to realize these properties in practice is missing. Here, we predict
that room temperature AFM metal MnPd allows the electrical control of the
Dirac nodal line by the N\'eel spin-orbit torque. Based on first-principles
density functional theory calculations, we show that reorientation of the
N\'eel vector leads to switching between the symmetry-protected degenerate
state and the gapped state associated with the dispersive Dirac nodal line at
the Fermi energy. The calculated spin Hall conductivity strongly depends on the
N\'eel vector orientation and can be used to experimentally detect the
predicted effect using a proposed spin-orbit torque device. Our results
indicate that AFM Dirac nodal line metal MnPd represents a promising
material for topological AFM spintronics
Friedel oscillations in graphene gapped by breaking \u3ci\u3eƤ\u3c/i\u3e and \u3ci\u3eT\u3c/i\u3e symmetries: Topological and geometrical signatures of electronic structure
The measurement of Friedel oscillations (FOs) is conventionally used to recover the energy dispersion of electronic structure. Besides the energy dispersion, the modern electronic structure also embodies other key ingredients such as the geometrical and topological properties; it is one promising direction to explore the potential of FOs for the relevant measurement. Here, we present a comprehensive study of FOs in substrate-supported graphene under off-resonant circularly polarized light, in which a valley-contrasting feature and topological phase transition occur due to the combined breaking of inversion (Ƥ) and time reversal (T) symmetries. Depending on the position of the Fermi level, FOs may be contributed by electronic backscattering in one single valley or two valleys. In the single-valley regime, the oscillation periods of FOs can be used to determine the topological phase boundary of electronic structure, while the amplitudes of FOs distinguish trivial insulators and topological insulators in a quantitative way. In the two-valley regime, the unequal Fermi surfaces lead to a beating pattern (robust two-wave-front dislocations) of FOs contributed by intravalley (intervalley) scattering. This study implies the great potential of FOs in characterizing topological and geometrical properties of the electronic structure of two-dimensional materials
Tunable two-dimensional Dirac nodal nets
Nodal-line semimetals are characterized by symmetry-protected band crossing lines and are expected to exhibit nontrivial electronic properties. Connections of the multiple nodal lines, resulting in nodal nets, chains, or links, are envisioned to produce even more exotic quantum states. In this work, we propose a feasible approach to realize tunable nodal-line connections in real materials. We show that certain space group symmetries support the coexistence of the planar symmetry-enforced and accidental nodal lines, which are robust to spin-orbit coupling and can be tailored into intricate patterns by chemical substitution, pressure, or strain. Based on first-principles calculations, we identify nonsymmorphic centrosymmetric quasi-one-dimensional compounds, K2SnBi and MX3 (M = Ti, Zr, Hf and X = Cl, Br, I), as materials hosting such tunable two-dimensional (2D) Dirac nodal nets. Unique Landau levels are predicted for the nodal-line semimetals with the 2D Dirac nodal nets. Our results provide a viable approach to realize the novel physics of the nodal-line connections in practice
Tunable two-dimensional Dirac nodal nets
Nodal line semimetals are characterized by symmetry-protected band crossing
lines and are expected to exhibit nontrivial electronic properties. Connections
of the multiple nodal lines, resulting in nodal nets, chains, or links, are
envisioned to produce even more exotic quantum states. In this work, we propose
a feasible approach to realize tunable nodal line connections in real
materials. We show that certain space group symmetries support the coexistence
of the planar symmetry enforced and accidental nodal lines, which are robust to
spin-orbit coupling and can be tailored into intricate patterns by chemical
substitution, pressure, or strain. Based on first-principles calculations, we
identify non-symmorphic centrosymmetric quasi-one-dimensional compounds,
KSnBi and MX (M = Ti, Zr, Hf and X = Cl, Br, I), as materials
hosting such tunable 2D Dirac nodal nets. Unique Landau levels are predicted
for the nodal line semimetals with the 2D Dirac nodal nets. Our results provide
a viable approach for realize the novel physics of the nodal line connections
in practice
Dirac Nodal Line Metal for Topological Antiferromagnetic Spintronics
Topological antiferromagnetic (AFM) spintronics is an emerging field of research, which exploits the N´eel vector to control the topological electronic states and the associated spin-dependent transport properties. A recently discovered N´eel spin-orbit torque has been proposed to electrically manipulate Dirac band crossings in antiferromagnets; however, a reliable AFM material to realize these properties in practice is missing. In this Letter, we predict that room-temperature AFM metal MnPd2 allows the electrical control of the Dirac nodal line by the N´eel spin-orbit torque. Based on first-principles density functional theory calculations, we show that reorientation of the N´eel vector leads to switching between the symmetryprotected degenerate state and the gapped state associated with the dispersive Dirac nodal line at the Fermi energy. The calculated spin Hall conductivity strongly depends on the N´eel vector orientation and can be used to experimentally detect the predicted effect using a proposed spin-orbit torque device. Our results indicate that AFM Dirac nodal line metal MnPd2 represents a promising material for topological AFM spintronics
Tunable two-dimensional Dirac nodal nets
Nodal-line semimetals are characterized by symmetry-protected band crossing lines and are expected to exhibit nontrivial electronic properties. Connections of the multiple nodal lines, resulting in nodal nets, chains, or links, are envisioned to produce even more exotic quantum states. In this work, we propose a feasible approach to realize tunable nodal-line connections in real materials. We show that certain space group symmetries support the coexistence of the planar symmetry-enforced and accidental nodal lines, which are robust to spin-orbit coupling and can be tailored into intricate patterns by chemical substitution, pressure, or strain. Based on first-principles calculations, we identify nonsymmorphic centrosymmetric quasi-one-dimensional compounds, K2SnBi and MX3 (M = Ti, Zr, Hf and X = Cl, Br, I), as materials hosting such tunable two-dimensional (2D) Dirac nodal nets. Unique Landau levels are predicted for the nodal-line semimetals with the 2D Dirac nodal nets. Our results provide a viable approach to realize the novel physics of the nodal-line connections in practice
Robust wavefront dislocations of Friedel oscillations in gapped graphene
Friedel oscillation is a well-known wave phenomenon, which represents the
oscillatory response of electron waves to imperfection. By utilizing the
pseudospin-momentum locking in gapless graphene, two recent experiments
demonstrate the measurement of the topological Berry phase by corresponding to
the unique number of wavefront dislocations in Friedel oscillations. Here, we
study the Friedel oscillations in gapped graphene, in which the
pseudospin-momentum locking is broken. Unusually, the wavefront dislocations do
occur as that in gapless graphene, which expects the immediate verification in
the current experimental condition. The number of wavefront dislocations is
ascribed to the invariant pseudospin winding number in gaped and gapless
graphene. This study deepens the understanding of correspondence between
topological quantity and wavefront dislocations in Friedel oscillations, and
implies the possibility to observe the wavefront dislocations of Friedel
oscillations in intrinsic gapped two-dimensional materials, e.g., transition
metal dichalcogenides.Comment: 5 pages, 3 figure
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