Photons possess a quantum metric in momentum space that induces a nonlinear Hall effect for light in inhomogeneous media and nonlinear corrections to gravitational lensing from the interplay of position and momentum space geometry.
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P-wave orbital magnetism protected by combined translation and time-reversal symmetry is proposed to originate from loop-current-induced orbital textures in a 2D Dirac lattice model, measurable via orbital Hall conductivity.
Anisotropic electron-phonon coupling with screened Coulomb repulsion yields nodal gaps in PtBi2 surface superconductivity when bandwidth approximates phonon energy.
A tunable chain of Rydberg atoms in tweezers mediates both coherent and dissipative entanglement between two distant micro-electromechanical oscillators.
citing papers explorer
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Quantum Metric and Nonlinear Hall Effect of Photons
Photons possess a quantum metric in momentum space that induces a nonlinear Hall effect for light in inhomogeneous media and nonlinear corrections to gravitational lensing from the interplay of position and momentum space geometry.
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$P$-wave Orbital Magnetism
P-wave orbital magnetism protected by combined translation and time-reversal symmetry is proposed to originate from loop-current-induced orbital textures in a 2D Dirac lattice model, measurable via orbital Hall conductivity.
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Mechanism for Nodal Topological Superconductivity on PtBi$_2$ Surface
Anisotropic electron-phonon coupling with screened Coulomb repulsion yields nodal gaps in PtBi2 surface superconductivity when bandwidth approximates phonon energy.
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Entanglement of mechanical oscillators mediated by a Rydberg tweezer chain
A tunable chain of Rydberg atoms in tweezers mediates both coherent and dissipative entanglement between two distant micro-electromechanical oscillators.