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Realizing the bosonic Klein paradox in a magnonic system

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 Added by Joren Harms
 Publication date 2021
  fields Physics
and research's language is English




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The Klein paradox refers to counterintuitive reflection or transmission of relativistic particles from a potential barrier, which is a natural consequence of relativistic quantum theory. The realization of this paradox using fundamental particles is nearly impossible because of the high energy barrier that needs to be overcome. Graphene, with emergent gapless fermion excitations, allows for the study of the fermionic Klein paradox. The test of this paradox for bosonic particles, however, remains a challenging problem. Here, we show that the bosonic Klein paradox can be tested in a driven-dissipative magnonic system. By carefully designing the strength of external drivings through spin-orbit torque and internal dissipation of the magnet, both positive-energy states (magnon) and negative energy states (antimagnon) can be dynamically stabilized. The reflection of incident magnons at a barrier can be amplified to be larger than one, accompanied by a backflow antimagnon current. Our findings may benefit the amplification of magnons in spintronic devices and further enable magnonic system as a platform to study relativistic physics.



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In 1928, P. Dirac proposed a new wave equation to describe relativistic electrons. Shortly afterwards, O. Klein solved a simple potential step problem for the Dirac equation and stumbled upon an apparent paradox - the potential becomes transparent when the height is larger than the electron energy. For massless particles, backscattering is completely forbidden in Klein tunneling, leading to perfect transmission through any potential barrier. Recent advent of condensed matter systems with Dirac-like excitations, such as graphene and topological insulators (TIs), has opened the possibility of observing the Klein tunneling experimentally. In the surface states of TIs, fermions are bound by spin-momentum locking, and are thus immune to backscattering due to time-reversal symmetry. Here we report the observation of perfect Andreev reflection in point contact spectroscopy - a clear signature of Klein tunneling and a manifestation of the underlying relativistic physics of a proximity-induced superconducting state in a topological Kondo insulator.
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