From Kondo lattices to Kondo superlattices

Shimozawa, Masaaki; Goh, Swee K.; Shibauchi, T.; Matsuda, Yuji

doi:10.1088/0034-4885/79/7/074503

Cited by 54 publications

(59 citation statements)

References 155 publications

(302 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…For the sake of clarity of the main text, we include the expressions for the magnetic field H derived from the free energy density for reference here. From equations (2), (10), (11), and (12) we obtain the expression for the applied magnetic field as a function of the variational parameters f ∞ and ξ c at a given magnetic inductionB, which also allows us to obtain an expression for the lower critical field H c1 . The magnetic field reads:…”

Section: Appendix C: Expressions For the Magnetic Fieldmentioning

confidence: 99%

Orbitally limited pair-density-wave phase of multilayer superconductors

2018

View full text Add to dashboard Cite

We investigate the magnetic field dependence of an ideal superconducting vortex lattice in the parity-mixed pair-density wave phase of multilayer superconductors within a circular cell Ginzburg-Landau approach. In multilayer systems, due to local inversion symmetry breaking, a Rashba spinorbit coupling is induced at the outer layers. This combined with a perpendicular paramagnetic (Pauli) limiting magnetic field stabilizes a staggered layer dependent pair-density wave phase in the superconducting singlet channel. The high-field pair-density wave phase is separated from the low-field BCS phase by a first-order phase transition. The motivating guiding question in this paper is: what is the minimal necessary Maki parameter αM for the appearance of the pair-density wave phase of a superconducting trilayer system? To address this problem we generalize the circular cell method for the regular flux-line lattice of a type-II superconductor to include paramagnetic depairing effects. Then, we apply the model to the trilayer system, where each of the layers are characterized by Ginzburg-Landau parameter κ0, and a Maki parameter αM . We find that when the spin-orbit Rashba interaction compares to the superconducting condensation energy, the orbitally limited pair-density wave phase stabilizes for Maki parameters αM > 10.

show abstract

Section: Appendix C: Expressions For the Magnetic Fieldmentioning

confidence: 99%

Orbitally limited pair-density-wave phase of multilayer superconductors

2018

View full text Add to dashboard Cite

show abstract

“…[1][2][3][4][5][6] Thus, it has become feasible to change the electronic structure and tune the properties of f electron materials. This is particularly important when one thinks of the interesting phenomena which can be observed in these materials, such as magnetism, unconventional superconductivity and quantum criticality.…”

Section: Introductionmentioning

confidence: 99%

Magnetism in f -electron superlattices

2016

View full text Add to dashboard Cite

We analyze antiferromagnetism in f electron superlattices. We show that the competition between the Kondo effect and the RKKY interaction in f electron materials is modified by the superlattice structure. Thus, the quantum critical point which separates the magnetic phase and the Fermi liquid phase depends on the structure of the f electron superlattice. The competition between the Kondo effect and the RKKY interaction is also reflected in the magnetic interlayer coupling between different f electron layers. We demonstrate that in the case of weak Kondo effect the magnetic interlayer coupling behaves similar to other magnetic heterostructures without Kondo effect. However, close to the quantum phase transition, the dependence of the interlayer coupling on the distance between the f electron layers is modified by the Kondo effect. Another remarkable effect, which is characteristic for f electron superlattice, is that the magnetic interlayer coupling does vanish stepwise depending on the distance between different f electron layers. As a consequence, the quantum critical point depends also stepwise on this distance.

show abstract

“…The first term denotes the normal part of the Hamiltonian for each layer, while the second term denotes the hopping between the neighboring layers. The Hamiltonian locally breaks the reflection symmetry (i.e., the layer m is mapped to the layer 5 − m.), which leads to the spin-orbit interaction of Rashba type [38][39][40] . The last term represents the pairing potential of superconductors.…”

mentioning

confidence: 99%

Fate of Majorana Modes in CeCoIn5/YbCoIn5 Superlattices: A Test Bed for the Reduction of Topological Classification

et al. 2017

View full text Add to dashboard Cite

In this paper, we propose CeCoIn5/YbCoIn5 superlattice systems as a test bed for the reduction of topological classification in free fermions. We find that the system with quad-layer of CeCoIn5 shows a topological crystalline superconducting phase with the mirror Chern number eight at the non-interacting level. Furthermore, we demonstrate that in the presence of two-body interactions, gapless edge modes are no longer protected by the symmetry in the system with quad-layer, but are protected in the systems with bi-or tri-layer. This clearly exemplifies the reduction of topological classification from Z ⊕ Z to Z ⊕ Z8.-Introduction-After the discovery of the topological insulators (TIs) and topological superconductors (TSCs), topological properties of quantum phases have been extensively studied 1,2 . In TIs/TSCs, nontrivial topology of the wave function in the bulk predicts gapless excitations at boundary/surface of the systems, which are sources of novel transport properties. These systems are free fermion systems (i.e., they are described by a quadratic Hamiltonian), and the topology of TIs/TSCs is protected by symmetries. Examining how many topological phases exist under a given local symmetry (i.e., classification of TIs and TSCs) is an important issue and gives useful information 3-5 . On the experimental side, realization of TIs/TSCs has been a significant issue, and various numbers of TIs/TSCs have been indeed realized; a two-dimensional TI was first confirmed for a quantum well of HgTe/CdTe 6,7 , and three-dimensional TIs were reported for Bi 2 Se 3 etc. [8][9][10] . Also, a TSC was proposed for Cu x Bi 2 Se 3 11 .Understanding the effects of electron correlations, which are generally neglected in the treatment of TIs/TSCs, is one of the current important issues in this field. Theoretical proposals of TIs in strongly correlated compounds have further stimulated this issue 12-20 . Recent extensive studies have discovered the reduction of topological classification for free fermion systems. In particular, Fidkowski and Kitaev have found that for a one-dimensional TSC of class BDI, the topological classification for free fermions, Z, collapses into Z 8 in the presence of electron correlations [21][22][23] . This means that gapless edge modes can be unstable against electron interactions. The reduction of topological classification has further been extended to two-and three-dimensional systems by examining stability/instability of gapless edge modes [24][25][26][27][28][29][30][31][32][33][34][35][36] . In spite of such significant progress on the theoretical side, the reduction of topological classification has not been experimentally reported yet. Therefore, an experimental platform is indispensable for progress in this direction.In this paper, we address the following question. How can we realize an experimentally accessible test bed to observe the reduction of the classification? In order to answer this question, we analyze topological properties of superconducting phases in a superlattice system composed ...

show abstract

From Kondo lattices to Kondo superlattices

Cited by 54 publications

References 155 publications

Orbitally limited pair-density-wave phase of multilayer superconductors

Orbitally limited pair-density-wave phase of multilayer superconductors

Magnetism in f -electron superlattices

Fate of Majorana Modes in CeCoIn5/YbCoIn5 Superlattices: A Test Bed for the Reduction of Topological Classification

Contact Info

Product

Resources

About