38 research outputs found
Type-I superconductivity in AlRe
While the pure elements tend to exhibit Type-I rather than Type-II
superconductivity, nearly all compound superconductors are Type-II, with only a
few known exceptions. We report single crystal growth and physical
characterization of the rhenium aluminide AlRe, which we conclude is a
Type-I superconductor based on magnetization, ac-susceptibility, and
specific-heat measurements. This detection of superconductivity, despite the
strong similarity of AlRe to a family of W and Mo aluminides that do not
superconduct, suggests that these aluminides are an ideal testbed for
identifying the relative importance of valence electron count and inversion
symmetry in determining whether a material will superconduct.Comment: 9 pages, 7 figures, CIF file as ancillar
Dirac Surface States and Nature of Superconductivity in Noncentrosymmetric BiPd
In non-magnetic bulk materials, inversion symmetry protects the spin
degeneracy. If the bulk crystal structure lacks a centre of inversion, however,
spin-orbit interactions lift the spin degeneracy, leading to a Rashba metal
whose Fermi surfaces exhibit an intricate spin texture. In superconducting
Rashba metals a pairing wavefunction constructed from these complex spin
structures will generally contain both singlet and triplet character. Here we
examine the possible triplet components of the order parameter in
noncentrosymmetric BiPd, combining for the first time in a noncentrosymmetric
superconductor macroscopic characterization, atomic-scale ultra-low-temperature
scanning tunnelling spectroscopy, and relativistic first-principles
calculations. While the superconducting state of BiPd appears topologically
trivial, consistent with Bardeen-Cooper-Schrieffer theory with an order
parameter governed by a single isotropic s-wave gap, we show that the material
exhibits Dirac-cone surface states with a helical spin polarization.Comment: replaced by published versio
Electronic structure of Li2 RuO3 studied by LDA and LDA+DMFT calculations and soft x-ray spectroscopy
The electronic structure of Li2RuO3 was investigated using x-ray emission and absorption spectroscopy and by theoretical calculations employing two approaches: the local density approximation (LDA) and a combination of LDA with the cluster extension of dynamical mean-field theory (LDA+DMFT). The evolution of the spectral properties with the strength of electronic correlations is analyzed. We show that for moderate values of on-site Coulomb repulsion U and intra-atomic Hund's rule exchange JH,Li2RuO3 is in an orbital-selective strongly correlated state in the sense that a part of the t2g manifold (i.e., xz/yz) behaves as local atomic orbitals susceptible to Hubbard correlations, while the remaining (xy) orbitals must be described as bond-centered molecular orbitals. Both theoretical approaches succeed in explaining the x-ray data, and a comparison of the theoretical and experimental spectra provides a reasonable estimate of the possible correlation strength (U) and Hund's coupling (JH) in Li2RuO3. © 2015 American Physical Society1771sciescopu
Kinetic stabilization of 1D surface states near twin boundaries in noncentrosymmetric BiPd
CMY, CT and PW acknowledge funding from EPSRC through EP/I031014/1 and EP/L505079/1 and DCP acknowledges support from the National Natural Science Foundation of China (Project No. 11650110428).The search for one-dimensional (1D) topologically-protected electronic states has become an important research goal for condensed matter physics owing to their potential use in spintronic devices or as a building block for topologically non-trivial electronic states. Using low temperature scanning tunneling microscopy, we demonstrate the formation of 1D electronic states at twin boundaries at the surface of the noncentrosymmetric material BiPd. These twin boundaries are topological defects which separate regions with antiparallel orientations of the crystallographic {b} axis. We demonstrate that the formation of the 1D electronic states can be rationalized by a change in effective mass of two-dimensional surface states across the twin boundary. Our work therefore reveals a novel route towards designing 1D electronic states with strong spin-orbit coupling.PostprintPostprintPeer reviewe
Properties of spin 1/2 triangular lattice antiferromagnets: CuRE2Ge2O8 (RE=Y, La)
We found new two-dimensional (2D) quantum (S=1/2) antiferromagnetic systems:
CuRE2Ge2O8 (RE=Y and La). According to our analysis of high-resolution X-ray
and neutron diffraction experiments, the Cu-network of CuRE2Ge2O8 (RE=Y and La)
exhibits a 2D triangular lattice linked via weak bonds along the perpendicular
b-axis. Our bulk characterizations from 0.08 to 400 K show that they undergo a
long-range order at 0.51(1) and 1.09(4) K for the Y and La systems,
respectively. Interestingly, they also exhibit field induced phase transitions.
For theoretical understanding, we carried out the density functional theory
(DFT) band calculations to find that they are typical charge-transfer-type
insulators with a gap of Eg = 2 eV. Taken together, our observations make
CuRE2Ge2O8 (RE=Y and La) additional examples of low-dimensional quantum spin
triangular antiferromagnets with the low-temperature magnetic ordering.Comment: 15 pages, 6 figures, and 1 tabl
Hidden Charge Order in an Iron Oxide Square-Lattice Compound
Since the discovery of charge disproportionation in the FeO2 square-lattice compound Sr3Fe2O7 by Mössbauer spectroscopy more than fifty years ago, the spatial ordering pattern of the disproportionated charges has remained “hidden” to conventional diffraction probes, despite numerous x-ray and neutron scattering studies. We have used neutron Larmor diffraction and Fe K-edge resonant x-ray scattering to demonstrate checkerboard charge order in the FeO2 planes that vanishes at a sharp second-order phase transition upon heating above 332 K. Stacking disorder of the checkerboard pattern due to frustrated interlayer interactions broadens the corresponding superstructure reflections and greatly reduces their amplitude, thus explaining the difficulty of detecting them by conventional probes. We discuss the implications of these findings for research on “hidden order” in other materials
Correct Brillouin zone and electronic structure of BiPd
A promising route to the realization of Majorana fermions is in noncentrosymmetric superconductors, in which spin-orbit coupling lifts the spin degeneracy of both bulk and surface bands. A detailed assessment of the electronic structure is critical to evaluate their suitability for this through establishing the topological properties of the electronic structure. This requires correct identification of the time-reversal-invariant momenta. One such material is BiPd, a recently rediscovered noncentrosymmetric superconductor which can be grown in large, high-quality single crystals and has been studied by several groups using angular resolved photoemission to establish its surface electronic structure. Many of the published electronic structure studies on this material are based on a reciprocal unit cell which is not the actual Brillouin zone of the material. We show here the consequences of this for the electronic structures and show how the inferred topological nature of the material is affected.PostprintPeer reviewe