Conceitos essenciais
Dirac masses can be generated in photonic synthetic lattices through non-Hermitian perturbations induced by optical gain and loss, leading to novel quasiparticle phenomena like Klein tunneling and time-reflection effects.
Resumo
The content explores how Dirac masses, commonly associated with high-energy physics, can be generated in photonic synthetic lattices through non-Hermitian perturbations induced by optical gain and loss. This challenges the traditional view of mass as an intrinsic property of matter.
The key highlights are:
- In crystal lattices like graphene, relativistic Dirac particles can exist as low-energy quasiparticles, with their masses imparted by lattice symmetry-breaking perturbations.
- The authors demonstrate experimentally that Dirac masses can be generated by non-Hermitian perturbations based on optical gain and loss in a photonic synthetic lattice.
- The spacetime engineering of the gain and loss-induced Dirac mass affects the quasiparticle behavior, leading to phenomena like Klein tunneling at spatial boundaries.
- At temporal boundaries where the Dirac mass sign is flipped, the authors observe a variant of the time-reflection phenomenon, where the quasiparticle's velocity is reversed in the non-relativistic limit, but retained in the relativistic limit.
The content provides insights into the complex origins of particle masses and the ability to engineer Dirac masses using non-Hermitian photonic systems, opening up new possibilities for controlling the behavior of Dirac quasiparticles.
Estatísticas
Mass is commonly considered an intrinsic property of matter.
Relativistic Dirac particles can exist as low-energy quasiparticles in crystal lattices like graphene.
Dirac masses can be generated by non-Hermitian perturbations based on optical gain and loss in a photonic synthetic lattice.
Citações
"Mass is commonly considered an intrinsic property of matter, but modern physics reveals particle masses to have complex origins1, such as the Higgs mechanism in high-energy physics2,3."
"Using a photonic synthetic lattice, we show experimentally that Dirac masses can be generated by means of non-Hermitian perturbations based on optical gain and loss."