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Curvature shapes chiral transport and entanglement in fermions

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Research area:Physics and AstronomyBlack Holes and Theoretical PhysicsFermion

What the study found

The study found that spacetime curvature in AdS2 and AdS2 black hole backgrounds can produce strongly asymmetric, or chiral, wave propagation for Dirac fermions. The authors report that this propagation is confined within an inhomogeneous Lieb-Robinson cone, a bound on how fast information spreads in a system.

Why the authors say this matters

The authors conclude that their results provide a causality-respecting framework linking curvature and horizons to transport and entanglement in 1+1-dimensional fermionic matter. The study suggests that real-time charge and current correlators can serve as diagnostics of chiral transport.

What the researchers tested

The researchers studied the real-time chiral dynamics of Dirac fermions in AdS2 and AdS2 black hole backgrounds. They examined how the curvature-generated spin connection acts as an effective magnetic field and a position-dependent chiral chemical potential, and they analyzed entanglement entropy, charge correlators, and current correlators in a finite inhomogeneous chain.

What worked and what didn't

The paper reports that front velocities decrease as fermion mass and horizon radius increase. Entanglement entropy grows inside the causal cone and then saturates, which the abstract attributes to screening and dephasing in the finite inhomogeneous chain. In dipole-dipole collision, the central bipartite entropy rises when inward Lieb-Robinson fronts intersect, forming a bright ridge in the local entanglement profile; charge and current correlators peak at front arrival.

What to keep in mind

The abstract describes results for Dirac fermions in AdS2 and AdS2 black hole backgrounds, so the scope is limited to that setting. It also notes saturation in a finite inhomogeneous chain, and it does not describe additional limitations beyond the available summary.

Key points

Spacetime curvature in AdS2 backgrounds produces strongly asymmetric chiral wave propagation for Dirac fermions.
The propagation is confined within an inhomogeneous Lieb-Robinson cone.
Front velocities decrease as fermion mass and horizon radius increase.
Entanglement entropy grows inside the causal cone and then saturates due to screening and dephasing in a finite inhomogeneous chain.
Charge and current correlators peak when the transport front arrives.

Disclosure

Research title:: Curvature shapes chiral transport and entanglement in fermions
Authors:: Kazuki Ikeda, Yaron Oz
Institutions:: Stony Brook University, Tel Aviv University
Publication date:: 2026-04-22
DOI:: 10.1007/jhep04(2026)177
OpenAlex record:: View

AI provenance: AI provenance information is not available for this post.