Dispersion of ordered stripe phases in the cuprates

Abstract: A phase separation model is presented for the stripe phase of the cuprates, which allows the doping dependence of the photoemission spectra to be calculated. The idealized limit of a well-ordered array of magnetic and charged stripes is analyzed, including effects of long-range Coulomb repulsion. Remarkably, down to the limit of two-cell wide stripes, the dispersion can be interpreted as essentially a superposition of the two end-phase dispersions, with superposed minigaps associated with the lattice periodici… Show more

“…Therefore, the fact that the pseudogap closes in the overdoped regime in the cuprates strongly suggests that the stripe phase terminates at the same doping. Direct evidence for this has recently appeared 9,6,80,3 . Figure 14a compares the intensity I of the inelastic neutron peaks near (π, π) as a function of doping in YBCO 81 and LSCO 2,1 .…”

“…Thus, Uchida, et al 24 , studying the Hall coefficient R H , find a crossover from one-dimensional behavior (R H → 0 as T → 0) for x < x cr = 1/8 to two dimensional behavior (coupled charged stripes) for x > x cr . In YBCO, the spin gap grows slowly with doping for x < x cr , then more rapidly for x > x cr ; this behavior can be understood in terms of coupled spin ladders, as the coupling changes with the width of the charged stripes 9 . In Eu substituted LSCO 25 , the Meissner fraction is negligibly small for x < x cr , then grows roughly linearly with doping until x ≃ 0.18, staying large up to at least x = 0.22.…”

“…The dot-dashed curve shows that in the phase separation regime, the low energy physics can be approximated by the form of free energy assumed in Ref. 9,…”

“…For this purpose we replot the data as integrated spectral weight over a finite energy cut within energy ∆E of the Fermi surface. Figure 11a shows a cut with ∆E = 200meV, for the model of a 1/8 doped stripe array (i.e., x = 0.125) 9 . The pattern is readily understood: the stripe superlattice leads to a number of quasi-one-dimensional bands; however, due to structure factor effects they have significant intensity only near the original Fermi surface, solid line in Fig.…”

“…[7][8][9][10][11] While fluctuations 7,8 play an important role in the real cuprates, we have constructed ordered stripe arrays, for which detailed tight-binding calculations are possible 9 . Such calculations can aid in elucidating the structure of the charged stripes, both for wide stripes -what stabilizes the preferred hole density -and for narrow stripes -how do quantum size effects (QSE) modify properties of the stripes.…”

Phase separation models for cuprate stripe arrays

“…Therefore, the fact that the pseudogap closes in the overdoped regime in the cuprates strongly suggests that the stripe phase terminates at the same doping. Direct evidence for this has recently appeared 9,6,80,3 . Figure 14a compares the intensity I of the inelastic neutron peaks near (π, π) as a function of doping in YBCO 81 and LSCO 2,1 .…”

“…Thus, Uchida, et al 24 , studying the Hall coefficient R H , find a crossover from one-dimensional behavior (R H → 0 as T → 0) for x < x cr = 1/8 to two dimensional behavior (coupled charged stripes) for x > x cr . In YBCO, the spin gap grows slowly with doping for x < x cr , then more rapidly for x > x cr ; this behavior can be understood in terms of coupled spin ladders, as the coupling changes with the width of the charged stripes 9 . In Eu substituted LSCO 25 , the Meissner fraction is negligibly small for x < x cr , then grows roughly linearly with doping until x ≃ 0.18, staying large up to at least x = 0.22.…”

“…The dot-dashed curve shows that in the phase separation regime, the low energy physics can be approximated by the form of free energy assumed in Ref. 9,…”

“…For this purpose we replot the data as integrated spectral weight over a finite energy cut within energy ∆E of the Fermi surface. Figure 11a shows a cut with ∆E = 200meV, for the model of a 1/8 doped stripe array (i.e., x = 0.125) 9 . The pattern is readily understood: the stripe superlattice leads to a number of quasi-one-dimensional bands; however, due to structure factor effects they have significant intensity only near the original Fermi surface, solid line in Fig.…”

“…[7][8][9][10][11] While fluctuations 7,8 play an important role in the real cuprates, we have constructed ordered stripe arrays, for which detailed tight-binding calculations are possible 9 . Such calculations can aid in elucidating the structure of the charged stripes, both for wide stripes -what stabilizes the preferred hole density -and for narrow stripes -how do quantum size effects (QSE) modify properties of the stripes.…”

Phase separation models for cuprate stripe arrays

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