M. Barbier, F. M. Peeters, P. Vasilopoulos, J. Milton Pereira Jr
Published 2011-01-20Version 1
We evaluate the dispersion relation for massless fermions, described by the Dirac equation, and for zero-spin bosons, described by the Klein-Gordon equation, moving in two dimensions and in the presence of a one-dimensional periodic potential. For massless fermions the dispersion relation shows a zero gap for carriers with zero momentum in the direction parallel to the barriers in agreement with the well-known "Klein paradox". Numerical results for the energy spectrum and the density of states are presented. Those for fermions are appropriate to graphene in which carriers behave relativistically with the "light speed" replaced by the Fermi velocity. In addition, we evaluate the transmission through a finite number of barriers for fermions and zero-spin bosons and relate it with that through a superlattice.
Comments: 9 pages, 12 figures
Journal: Phys. Rev. B 77, 115446 (2008)
Dirac electrons in a Kronig-Penney potential: dispersion relation and transmission periodic in the strength of the barriers
Bilayer graphene with single and multiple electrostatic barriers: band structure and transmission
Snell's Law for Spin Waves
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