Theories of low-energy quasi-particle states in disordered d-wave superconductors

Altland, Alexander; Simons, Benjamin D.; Zirnbauer, Martin R.

doi:10.1016/s0370-1573(01)00065-5

Cited by 149 publications

(229 citation statements)

References 89 publications

(255 reference statements)

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“…We then consider the coupling between fermions and disorders, which can be generically described by [34][35][36][37][38][39] …”

Section: Effective Modelmentioning

confidence: 99%

“…On the other hand, disorder scattering could break Cooper pairs by shortening the lifetime of Dirac fermions, which would destruct superconductivity. Moreover, there are at least three types of disorder in Dirac semimetals [34][35][36], including random chemical potential, random mass, and random gauge potential. They have various physical origins, couple to Dirac fermions in different manners, and can result in distinct low-energy behaviors [34][35][36][37][38][39].…”

Section: Introductionmentioning

confidence: 99%

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Superconductivity in two-dimensional disordered Dirac semimetals

et al. 2017

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In two-dimensional Dirac semimetals, Cooper pairing instability occurs only when the attractive interaction strength |u| is larger than some critical value |uc| because the density of states vanishes at Dirac points. Disorders enhance the low-energy density of states but meanwhile shorten the lifetime of fermions, which tend to promote and suppress superconductivity, respectively. To determine which of the two competing effects wins, we study the interplay of Cooper pairing interaction and disorder scattering by means of renormalization group method. We consider three types of disorders, including random mass, random gauge potential, and random chemical potential, and show that the first two suppress superconductivity. In particular, the critical BCS coupling |uc| is increased to certain larger value if the system contains only random mass or random gauge potential, which makes the onset of superconductivity more difficult. In the case of random chemical potential, the effective disorder parameter flows to the strong coupling regime, where the perturbation expansion breaks down and cannot provide a clear answer concerning the fate of superconductivity. When different types of disorder coexist in one system, their strength parameters all flow to strong couplings. In the strong coupling regime, the perturbative renormalization group method becomes invalid, and one needs to employ other methods to treat the disorder effects. We perform a simple gap equation analysis of the impact of random chemical potential on superconductivity by using the AbrikosovGorkov diagrammatic approach, and also briefly discuss the possible generalization of this approach.

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“…We then consider the coupling between fermions and disorders, which can be generically described by [34][35][36][37][38][39] …”

Section: Effective Modelmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Superconductivity in two-dimensional disordered Dirac semimetals

et al. 2017

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“…N of moduli fields. This allows us to use Random Matrix Theory (RMT) [18][19][20][21] Quantum tunneling to other sites is always present which allows the wavefunction to spread from site to site. Together with the stochastic distribution of sites this ensures the Anderson localization [22] of wavepackets around some vacuum site, at least for all the energy levels up to the disorder strength.…”

Section: A Model Of the Stringy Landscapementioning

confidence: 99%

Why the Universe started from a low entropy state

Holman

Mersini-Houghton

2006

Phys. Rev. D

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We show that the inclusion of backreaction of massive long wavelengths imposes dynamical constraints on the allowed phase space of initial conditions for inflation, which results in a superselection rule for the initial conditions. Only high energy inflation is stable against collapse due to the gravitational instability of massive perturbations. We present arguments to the effect that the initial conditions problem cannot be meaningfully addressed by thermostatistics as far as the gravitational degrees of freedom are concerned. Rather, the choice of the initial conditions for the universe in the phase space and the emergence of an arrow of time have to be treated as a dynamic selection.

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“…The latter theory has been studied a great deal. Of particular interest is the operator content, which is conveniently encoded in the generating function (6). Recall that the "ground state" (that is, fields of weight (0, 0)) is degenerate four times, while there are eight fields of weight (1, 0) (and eight fields of weight (0, 1)).…”

Section: Symplectic Fermions and Non Linearly Realized Symmetriesmentioning

confidence: 99%

Integrable quantum field theories with supergroup symmetries: the OSP(1/2) case

Saleur

Wehefritz-Kaufmann

2003

Nuclear Physics B

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As a step to understand general patterns of integrability in 1+1 quantum field theories with supergroup symmetry, we study in details the case of OSP (1/2). Our results include the solutions of natural generalizations of models with ordinary group symmetry: the U OSP (1/2) k WZW model with a current current perturbation, the U OSP (1/2) principal chiral model, and the U OSP (1/2) ⊗ U OSP (1/2)/U OSP (1/2) coset models perturbed by the adjoint. Graded parafermions are also discussed. A pattern peculiar to supergroups is the emergence of another class of models, whose simplest representative is the OSP (1/2)/OSP (0/2) sigma model, where the (non unitary) orthosymplectic symmetry is realized non linearly (and can be spontaneously broken). For most models, we provide an integrable lattice realization. We show in particular that integrable osp(1/2) spin chains with integer spin flow to U OSP (1/2) WZW models in the continuum limit, hence providing what is to our knowledge the first physical realization of a super WZW model.

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Theories of low-energy quasi-particle states in disordered d-wave superconductors

Cited by 149 publications

References 89 publications

Superconductivity in two-dimensional disordered Dirac semimetals

Superconductivity in two-dimensional disordered Dirac semimetals

Why the Universe started from a low entropy state

Integrable quantum field theories with supergroup symmetries: the OSP(1/2) case

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