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Condensed matter realization of fermion quasiparticles in Minkowski space

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 نشر من قبل Xiao Dong
 تاريخ النشر 2018
  مجال البحث فيزياء
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What is the difference between space and time? is an ancient question that remains a matter of intense debate. In Newtonian mechanics time is absolute, while in Einsteins theory of relativity time and space combine into Minkowski spacetime. Here, we firstly propose Minkowski fermions in 2+1 dimensional Minkowski spacetime which have two space-like and one time-like momentum axes. These quasiparticles can be further classified as Klein-Gordon fermions and Dirac-Minkowski fermions according to the linearly and quadratically dispersing excitations. Realization of Dirac-Minkowski quasiparticles requires systems with particular topological nodal-line band degeneracies, such as hyperbolic nodal lines or coplanar band crossings. With the help of first-principles calculations we find that novel massless Dirac-Minkowski fermions are realized in a metastable bulk boron allotrope, Pnnm-B16.



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