Role of Umklapp Processes in Conductivity of Doped Two-Leg Ladders

A.A. Abrikosov; C.L. Kane; Catherine Kallin; E. Dagotto; E. Dagotto; E. Orignac; E.H. Kim; E.M. McCarron; Eugene H. Kim; H-H. Lin; H. Frahm; H.J. Schulz; H.J. Schulz; H.J. Schulz; J. Solyom; J. von Delft; Jihong Qin; K. Magishi; L.B. Ioffe; M. Gurvitch; Patrick Byrne; R. Shankar; R.M. Noack; T. Giamarchi; T. Giamarchi; T. Giamarchi; T. Osafune; W. Götze

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Role of Umklapp Processes in Conductivity of Doped Two-Leg Ladders

Authors: A.A. Abrikosov
C.L. Kane
Catherine Kallin
E. Dagotto
E. Dagotto
E. Orignac
E.H. Kim
E.M. McCarron
Eugene H. Kim
H-H. Lin
H. Frahm
H.J. Schulz
H.J. Schulz
H.J. Schulz
J. Solyom
J. von Delft
Jihong Qin
K. Magishi
L.B. Ioffe
M. Gurvitch
Patrick Byrne
R. Shankar
R.M. Noack
T. Giamarchi
T. Giamarchi
T. Giamarchi
T. Osafune
W. Götze
Publication date: 22 April 2002
Publisher: 'American Physical Society (APS)'
Doi

Abstract

Recent conductivity measurements performed on the hole-doped two-leg ladder material

\mathrm{Sr_{14-x}Ca_xCu_{24}O_{41}}

reveal an approximately linear power law regime in the c-axis DC resistivity as a function of temperature for

x=11

. In this work, we employ a bosonic model to argue that umklapp processes are responsible for this feature and for the high spectral weight in the optical conductivity which occurs beyond the finite frequency Drude-like peak. Including quenched disorder in our model allows us to reproduce experimental conductivity and resistivity curves over a wide range of energies. We also point out the differences between the effect of umklapp processes in a single chain and in the two-leg ladder.Comment: 10 pages, 2 figure

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