TY - JOUR
T1 - Dynamics of electric transport in interacting Weyl semimetals
AU - Rosenstein, B.
AU - Lewkowicz, M.
PY - 2013/7/3
Y1 - 2013/7/3
N2 - The response to an electric field (dc and ac) of electronic systems in which the Fermi "surface" consists of a number of three-dimensional (3D) Weyl points (such as some pyrochlore iridates) exhibits a peculiar combination of characteristics usually associated with insulating and conducting behavior. Generically a neutral plasma in clean materials can be described by a tight-binding model with a strong spin-orbit interaction. A system of that type has a vanishing dc conductivity; however the current response to the dc field is very slow: The current decays with time in a powerwise manner, different from an insulator. The ac conductivity, in addition to a finite real part σ′(Ω) which is linear in frequency, exhibits an imaginary part σ′′(Ω) that increases logarithmically as a function of the UV cutoff (atomic scale). This leads to a substantial dielectric response like a large dielectric constant at low frequencies. This is in contrast to a two-dimensional (2D) Weyl semimetal-like graphene at a neutrality point where the ac conductivity is purely pseudodissipative. The Coulomb interaction between electrons is long range and sufficiently strong to make a significant impact on transport. The interaction contribution to the ac conductivity is calculated within the tight-binding model. The result for the real part expressed via the renormalized (at frequency Ω̄) Fermi velocity v is Δσ ′(Ω)=e4Ω/(9π2âv)[2log(Ω/ Ω̄)-5].
AB - The response to an electric field (dc and ac) of electronic systems in which the Fermi "surface" consists of a number of three-dimensional (3D) Weyl points (such as some pyrochlore iridates) exhibits a peculiar combination of characteristics usually associated with insulating and conducting behavior. Generically a neutral plasma in clean materials can be described by a tight-binding model with a strong spin-orbit interaction. A system of that type has a vanishing dc conductivity; however the current response to the dc field is very slow: The current decays with time in a powerwise manner, different from an insulator. The ac conductivity, in addition to a finite real part σ′(Ω) which is linear in frequency, exhibits an imaginary part σ′′(Ω) that increases logarithmically as a function of the UV cutoff (atomic scale). This leads to a substantial dielectric response like a large dielectric constant at low frequencies. This is in contrast to a two-dimensional (2D) Weyl semimetal-like graphene at a neutrality point where the ac conductivity is purely pseudodissipative. The Coulomb interaction between electrons is long range and sufficiently strong to make a significant impact on transport. The interaction contribution to the ac conductivity is calculated within the tight-binding model. The result for the real part expressed via the renormalized (at frequency Ω̄) Fermi velocity v is Δσ ′(Ω)=e4Ω/(9π2âv)[2log(Ω/ Ω̄)-5].
UR - http://www.scopus.com/inward/record.url?scp=84881177182&partnerID=8YFLogxK
U2 - 10.1103/PhysRevB.88.045108
DO - 10.1103/PhysRevB.88.045108
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AN - SCOPUS:84881177182
SN - 1098-0121
VL - 88
JO - Physical Review B - Condensed Matter and Materials Physics
JF - Physical Review B - Condensed Matter and Materials Physics
IS - 4
M1 - 045108
ER -