Beyond the standard model of Ginzburg-Landau theory: Multiband superconductors

Brendan J. Wilson; Mukunda P. Das

doi:10.1088/0953-8984/26/32/325701

Beyond the standard model of Ginzburg-Landau theory: Multiband superconductors

Brendan J. Wilson, Mukunda P. Das

Research output: Contribution to journal › Article › peer-review

2 Citations (Scopus)

Abstract

The recently discovered multiband superconductors have created a new class of novel superconductors. In these materials multiple superconducting gaps arise due to the formation of Cooper pairs on different sheets of the Fermi surfaces. An important feature of these superconductors is the interband couplings, which not only change the individual gap properties, but also create new collective modes. Here we investigate the effect of the interband couplings in the Ginzburg-Landau theory. We produce a general τ^(2n+1)/2 expansion (τ=1-T/T_c) and show that this expansion has unexpected behaviour for n2. This point emphasises the weaker validity of the GL theory for lower temperatures and gives credence to the existence of hidden criticality near the critical temperature of the uncoupled subdominant band. We apply this theory to a range of material parameters fitted to experimental measurements and find that for some cases the theory performs very well at all temperatures, but for other materials the range of applicability can be very limited.

Original language	English
Article number	325701
Journal	Journal of Physics Condensed Matter
Volume	26
Issue number	32
DOIs	https://doi.org/10.1088/0953-8984/26/32/325701
Publication status	Published - 13 Aug 2014

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title = "Beyond the standard model of Ginzburg-Landau theory: Multiband superconductors",

abstract = "The recently discovered multiband superconductors have created a new class of novel superconductors. In these materials multiple superconducting gaps arise due to the formation of Cooper pairs on different sheets of the Fermi surfaces. An important feature of these superconductors is the interband couplings, which not only change the individual gap properties, but also create new collective modes. Here we investigate the effect of the interband couplings in the Ginzburg-Landau theory. We produce a general τ(2n+1)/2 expansion (τ=1-T/Tc) and show that this expansion has unexpected behaviour for n2. This point emphasises the weaker validity of the GL theory for lower temperatures and gives credence to the existence of hidden criticality near the critical temperature of the uncoupled subdominant band. We apply this theory to a range of material parameters fitted to experimental measurements and find that for some cases the theory performs very well at all temperatures, but for other materials the range of applicability can be very limited.",

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N2 - The recently discovered multiband superconductors have created a new class of novel superconductors. In these materials multiple superconducting gaps arise due to the formation of Cooper pairs on different sheets of the Fermi surfaces. An important feature of these superconductors is the interband couplings, which not only change the individual gap properties, but also create new collective modes. Here we investigate the effect of the interband couplings in the Ginzburg-Landau theory. We produce a general τ(2n+1)/2 expansion (τ=1-T/Tc) and show that this expansion has unexpected behaviour for n2. This point emphasises the weaker validity of the GL theory for lower temperatures and gives credence to the existence of hidden criticality near the critical temperature of the uncoupled subdominant band. We apply this theory to a range of material parameters fitted to experimental measurements and find that for some cases the theory performs very well at all temperatures, but for other materials the range of applicability can be very limited.

AB - The recently discovered multiband superconductors have created a new class of novel superconductors. In these materials multiple superconducting gaps arise due to the formation of Cooper pairs on different sheets of the Fermi surfaces. An important feature of these superconductors is the interband couplings, which not only change the individual gap properties, but also create new collective modes. Here we investigate the effect of the interband couplings in the Ginzburg-Landau theory. We produce a general τ(2n+1)/2 expansion (τ=1-T/Tc) and show that this expansion has unexpected behaviour for n2. This point emphasises the weaker validity of the GL theory for lower temperatures and gives credence to the existence of hidden criticality near the critical temperature of the uncoupled subdominant band. We apply this theory to a range of material parameters fitted to experimental measurements and find that for some cases the theory performs very well at all temperatures, but for other materials the range of applicability can be very limited.

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Beyond the standard model of Ginzburg-Landau theory: Multiband superconductors

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