The Microscopic Approach in the Theory of Superconductors With a Many-Component Order Parameter

Izyumov, Yu. A.; Laptev, V. M.; Syromyatnikov, V. N.

doi:10.1142/s0217979289000890

Cited by 15 publications

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“…Finally, we reduce P k into irreducible representations (IRs) of the original crystal point group. The gap functions should be zero, and thus, the gap nodes appear, if the corresponding IRs do not exist in the results of reductions [7,9,35]. Otherwise, the superconducting gap will open in general.…”

Section: Classification Theory Of Superconducting Gapmentioning

confidence: 99%

Unconventional superconducting gap structure protected by space group symmetry

Sumita

Yanase

2018

Phys. Rev. B

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Recent superconducting gap classifications based on space group symmetry have revealed nontrivial gap structures that were not shown by point group symmetry. First, we review a comprehensive classification of symmetry-protected line nodes within the range of centrosymmetric space groups. Next, we show an additional constraint; line nodes peculiar to nonsymmorphic systems appear only for primitive or orthorhombic base-centered Bravais lattice. Then, we list useful classification tables of 59 primitive or orthorhombic base-centered space groups for the superconducting gap structures. Furthermore, our gap classification reveals the jz-dependent point nodes (gap opening) appearing on a 3-or 6-fold axis, which means that the presence (absence) of point nodes depends on the Bloch-state angular momentum jz. We suggest that this unusual gap structure is realized in a heavy-fermion superconductor UPt3, using a group-theoretical analysis and a numerical calculation. The calculation demonstrates that a Bloch phase contributes to jz as effective orbital angular momentum by site permutation. We also discuss superconducting gap structures in MoS2, SrPtAs, UBe13, and PrOs4Sb12. arXiv:1801.03293v3 [cond-mat.supr-con]

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Section: Classification Theory Of Superconducting Gapmentioning

confidence: 99%

Unconventional superconducting gap structure protected by space group symmetry

Sumita

Yanase

2018

Phys. Rev. B

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“…Izyumov et al [13] proposed to use IRs of space groups for the description of oneelectron states coupled in a Cooper pair and showed that the above-mentioned direct connection between multiplicity and parity of a Copper pair may be violated if oneelectron states are characterize by the wave vector in symmetrical directions in a Brillouin zone. The space-group approach to the wavefunction of a Copper pair was further developed [14 to 16] by making use of the Pauli exclusion principle and of the Mackey theorem [17,18].…”

Section: Introductionmentioning

confidence: 99%

Space-Group Approach to the Nodal Structure of the Superconducting Order Parameter in UPt3

Yarzhemsky

1998

phys. stat. sol. (b)

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The nodal structure of the superconducting order parameter (SOP) in D 4 6h symmetry (crystal symmetry of UPt 3 ) is investigated making use of the space-group approach to the wave function of a Copper pair. It is shown that the lines of nodes of odd SOP appear in strong spin±orbit coupling case if the time-reversal symmetry is violated. The nodal structure of the SOP is defined by the space±time symmetry of the crystal and does not depend on any choice of basis functions. The theoretical nodal structure of the E 1u in D 4 6h symmetry agrees with the experimental data on UPt 3 .

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“…In both planes, there are four IRs, A g , B g , A u , and B u since the coset group M k /T is isomorphic to the point group C 2h [33]. The results are summarized in Table III. Note that the gap functions should be zero, which means the appearance of gap nodes, if the corresponding IRs do not exist in the reduction ofP k [21][22][23]. The absence of A u in PP corresponds to the emergent horizontal line node of the recently proposed E 2u state in UPt 3 superconductors [24,[34][35][36].…”

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confidence: 99%

“…Such classification provides useful information in analyzing the nodal structure of various unconventional superconductors [20]. Also, another development of gap classification based on the space group symmetry [21][22][23][24] gives us the correct way to take into account small representations at Brillouin zone (BZ) boundary in non-symmorphic space groups [25,26]. T. Micklitz and M. R. Norman [24] demonstrated in the pioneering work that new types of * nomoto.takuya@scphys.kyoto-u.ac.jp symmetry-protected nodes can appear at the BZ boundary.…”

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confidence: 99%

Symmetry-Protected Line Nodes in Non-symmorphic Magnetic Space Groups: Applications to UCoGe and UPd₂Al₃

Nomoto

Ikeda

2017

J. Phys. Soc. Jpn.

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We present the group-thoretical classification of gap functions in superconductors coexisting with some magnetic order in non-symmorphic magnetic space groups. Based on the weak-coupling BCS theory, we show that UCoGe-type ferromagnetic superconductors must have horizontal line nodes on either kz = 0 or ±π/c plane. Moreover, it is likely that additional Weyl point nodes exist at the axial point. On the other hand, in UPd2Al3-type antiferromagnetic superconductors, gap functions with Ag symmetry possess horizontal line nodes in antiferromagnetic Brillouin zone boundary perpendicular to c-axis. In other words, the conventional fully-gapped s-wave superconductivity is forbidden in this type of antiferromagnetic superconductors, irrelevant to the pairing mechanism, as long as the Fermi surface crosses a zone boundary. UCoGe and UPd2Al3 are candidates for unconventional superconductors possessing hidden symmetry-protected line nodes, peculiar to non-symmorphic magnetic space groups.In the research field of superconductivity, its coexistence of magnetism is a very interesting topic. Such coexistence between superconductivity and magnetism is often discovered in the U-based heavy-fermion superconductors. For example, UPd 2 Al 3 shows an antiferromagnetic transition at T N = 14K, and then coexists with unconventional superconductivity below T c = 2K [1,2]. UGe 2 [3], URhGe [4], and UCoGe [5] encounter a superconducting transition in the ferromagnetic phase. A rare reentrant superconductivity has been discovered under the magnetic field [6]. Theoretically, in UPd 2 Al 3 , it was discussed that a spin-singlet superconductivity with horizontal line nodes occurs via the virtual exchange of magnetic excitons [7,8]. In the ferromagnetic superconductors, it has been considered that the Ising-like ferromagnetic fluctuation can lead to a spin-triplet pairing state [9,10], and many fascinating phenomena including the odd H − T phase diagram have been studied [11][12][13][14][15][16]. However, in spite of the growing interest, the properties characteristic of the coexisting phase is less well understood systematically. In this situation, the group-theoreical classification, which provides definite statements independent of the details of materials, plays an important role.It is well-known that the superconducting states are classified into the irreducible representations (IRs) under a given point group symmetry [17][18][19]. Such classification provides useful information in analyzing the nodal structure of various unconventional superconductors [20]. Also, another development of gap classification based on the space group symmetry [21][22][23][24] gives us the correct way to take into account small representations at Brillouin zone (BZ) boundary in non-symmorphic space groups [25,26]. T. Micklitz and M. R. Norman [24] demonstrated in the pioneering work that new types of * nomoto.takuya@scphys.kyoto-u.ac.jp symmetry-protected nodes can appear at the BZ boundary. As for the coexisting phase, there is little progress of gap class...

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The Microscopic Approach in the Theory of Superconductors With a Many-Component Order Parameter

Cited by 15 publications

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Unconventional superconducting gap structure protected by space group symmetry

Unconventional superconducting gap structure protected by space group symmetry

Space-Group Approach to the Nodal Structure of the Superconducting Order Parameter in UPt3

Symmetry-Protected Line Nodes in Non-symmorphic Magnetic Space Groups: Applications to UCoGe and UPd₂Al₃

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The Microscopic Approach in the Theory of Superconductors With a Many-Component Order Parameter

Cited by 15 publications

References 0 publications

Unconventional superconducting gap structure protected by space group symmetry

Unconventional superconducting gap structure protected by space group symmetry

Space-Group Approach to the Nodal Structure of the Superconducting Order Parameter in UPt3

Symmetry-Protected Line Nodes in Non-symmorphic Magnetic Space Groups: Applications to UCoGe and UPd2Al3

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Symmetry-Protected Line Nodes in Non-symmorphic Magnetic Space Groups: Applications to UCoGe and UPd₂Al₃