2014
DOI: 10.1038/ncomms6657
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Disorder-induced topological change of the superconducting gap structure in iron pnictides

Abstract: In superconductors with unconventional pairing mechanisms, the energy gap in the excitation spectrum often has nodes, which allow quasiparticle excitations at low energies. In many cases, such as in d-wave cuprate superconductors, the position and topology of nodes are imposed by the symmetry, and thus the presence of gapless excitations is protected against disorder. Here we report on the observation of distinct changes in the gap structure of ironpnictide superconductors with increasing impurity scattering. … Show more

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Cited by 107 publications
(157 citation statements)
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“…Such T -dependent impurity scattering was also observed with increasing irradiation in the previous α-particle irradiation experiment on iron-based superconductor NdFeAs(O,F), 21) and can be understood with the assumption that the magnetic moments of the defects induce Kondolike scattering, similar to the case of heavy-fermion materials. Although no discernible magnetic moment was observed after irradiation in the paramagnetic state down to 0.1 K in our system, 16) this observation indicates that non-magnetic holes created in the AFM networks induce a T -dependent scattering process that deserves further investigation to elucidate its origin. For x = 0.16( Figure 1(c)), and 0.24( Figure 1(d)), ρ(T ) exhibits a reduction at low temperatures due to the onset of superconductivity.…”
mentioning
confidence: 83%
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“…Such T -dependent impurity scattering was also observed with increasing irradiation in the previous α-particle irradiation experiment on iron-based superconductor NdFeAs(O,F), 21) and can be understood with the assumption that the magnetic moments of the defects induce Kondolike scattering, similar to the case of heavy-fermion materials. Although no discernible magnetic moment was observed after irradiation in the paramagnetic state down to 0.1 K in our system, 16) this observation indicates that non-magnetic holes created in the AFM networks induce a T -dependent scattering process that deserves further investigation to elucidate its origin. For x = 0.16( Figure 1(c)), and 0.24( Figure 1(d)), ρ(T ) exhibits a reduction at low temperatures due to the onset of superconductivity.…”
mentioning
confidence: 83%
“…Through the use of successive electron irradiation, we can perform systematic measurements on a given sample with a gradual introduction of impurity scattering induced by point defects, and without changing the carrier concentration or band width. 15,16) In general, impurity scattering reduces the T c in unconventional superconductors, where the suppression rate depends on the gap structures. 17) Indeed, the superconducting dome shrinks with the introduction of scattering via chemical substitution in cuprates and heavy-fermion superconductors.…”
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confidence: 99%
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“…The additional complexity of competing orders such superconductivity with charge density wave (CDW) or magnetism makes this problem one of the most challenging frontiers in physics. [2][3][4][5] A large body of literature is devoted to this interplay in nearly magnetic materials. 6 The interplay of disorder and superconductivity in CDW materials have been less explored than its magnetic analog.…”
Section: Introductionmentioning
confidence: 99%
“…Studying the effects of a controlled point -like disorder on superconducting properties is a powerful tool to understand the mechanisms of superconductivity [1][2][3][4][5][6][7][8]. According to the Anderson's theorem, conventional isotropic s−wave superconductors are not affected by the potential (non-magnetic) scattering, but are sensitive to a spin -flip scattering on magnetic impurities [1].…”
Section: Introductionmentioning
confidence: 99%