147 research outputs found
Intrinsic Josephson junctions in the iron-based multi-band superconductor (V2Sr4O6)Fe2As2
In layered superconductors, Josephson junctions may be formed within the unit
cell due to sufficiently low interlayer coupling. These intrinsic Josephson
junction (iJJ) systems have attracted considerable interest for their
application potential in quantum computing as well as efficient sources of THz
radiation, closing the famous "THz gap". So far, iJJ have been demonstrated in
single-band, copper-based high-Tc superconductors, mainly in Ba-Sr-Ca-Cu-O.
Here we report clear experimental evidence for iJJ behavior in the iron-based
superconductor (V2Sr4O6)Fe2As2. The intrinsic junctions are identified by
periodic oscillations of the flux flow voltage upon increasing a well aligned
in-plane magnetic field. The periodicity is well explained by commensurability
effects between the Josephson vortex lattice and the crystal structure, which
is a hallmark signature of Josephson vortices confined into iJJ stacks. This
finding adds (V2Sr4O6)Fe2As2 as the first iron-based, multi-band superconductor
to the copper-based iJJ materials of interest for Josephson junction
applications, and in particular novel devices based on multi-band Josephson
coupling may be realized.Comment: Accepted in Nature Physic
Field induced density wave in the heavy fermion compound CeRhIn5
Metals containing Ce often show strong electron correlations due to the
proximity of the 4f state to the Fermi energy, leading to strong coupling with
the conduction electrons. This coupling typically induces a variety of
competing ground states, including heavy-fermion metals, magnetism and
unconventional superconductivity. The d-wave superconductivity in CeTMIn5
(TM=Co, Rh, Ir) has attracted significant interest due to its qualitative
similarity to the cuprate high-Tc superconductors. Here, we show evidence for a
field induced phase-transition to a state akin to a density-wave (DW) in the
heavy fermion CeRhIn5, existing in proximity to its unconventional
superconductivity. The DW state is signaled by a hysteretic anomaly in the
in-plane resistivity accompanied by the appearance of non-linear electrical
transport at high magnetic fields (>27T), which are the distinctive
characteristics of density-wave states. The unusually large hysteresis enables
us to directly investigate the Fermi surface of a supercooled electronic system
and to clearly associate a Fermi surface reconstruction with the transition.
Key to our observation is the fabrication of single crystal microstructures,
which are found to be highly sensitive to "subtle" phase transitions involving
only small portions of the Fermi surface. Such subtle order might be a common
feature among correlated electron systems, and its clear observation adds a new
perspective on the similarly subtle CDW state in the cuprates.Comment: Accepted in Nature Communication
Ionic liquid gating of SrTiO lamellas fabricated with a focused ion beam
In this work, we combine two previously-incompatible techniques for defining
electronic devices: shaping three-dimensional crystals by focused ion beam
(FIB), and two-dimensional electrostatic accumulation of charge carriers. The
principal challenge for this integration is nanometer-scale surface damage
inherent to any FIB-based fabrication. We address this by using a sacrificial
protective layer to preserve a selected pristine surface. The test case
presented here is accumulation of 2D carriers by ionic liquid gating at the
surface of a micron-scale SrTiO lamella. Preservation of surface quality is
reflected in superconductivity of the accumulated carriers. This technique
opens new avenues for realizing electrostatic charge tuning in materials that
are not available as large or exfoliatable single crystals, and for patterning
the geometry of the accumulated carriers
Observation of two-dimensional Fermi surface and Dirac dispersion in YbMnSb
We present the crystal structure, electronic structure, and transport
properties of the material YbMnSb, a candidate system for the investigation
of Dirac physics in the presence of magnetic order. Our measurements reveal
that this system is a low-carrier-density semimetal with a 2D Fermi surface
arising from a Dirac dispersion, consistent with the predictions of density
functional theory calculations of the antiferromagnetic system. The low
temperature resistivity is very large, suggesting scattering in this system is
highly efficient at dissipating momentum despite its Dirac-like nature.Comment: 8 pages, 6 figure
Quantum limit transport and destruction of the Weyl nodes in TaAs
Weyl fermions are a new ingredient for correlated states of electronic
matter. A key difficulty has been that real materials also contain non-Weyl
quasiparticles, and disentangling the experimental signatures has proven
challenging. We use magnetic fields up to 95 tesla to drive the Weyl semimetal
TaAs far into its quantum limit (QL), where only the purely chiral 0th Landau
levels (LLs) of the Weyl fermions are occupied. We find the electrical
resistivity to be nearly independent of magnetic field up to 50 tesla: unusual
for conventional metals but consistent with the chiral anomaly for Weyl
fermions. Above 50 tesla we observe a two-order-of-magnitude increase in
resistivity, indicating that a gap opens in the chiral LLs. Above 80 tesla we
observe strong ultrasonic attenuation below 2 kelvin, suggesting a
mesoscopically-textured state of matter. These results point the way to
inducing new correlated states of matter in the QL of Weyl semimetals
Transport evidence for Fermi-arc mediated chirality transfer in the Dirac semimetal CdAs
Dirac semi-metals show a linear electronic dispersion in three dimension
described by two copies of the Weyl equation, a theoretical description of
massless relativistic fermions. At the surface of a crystal, the breakdown of
fermion chirality is expected to produce topological surface states without any
counterparts in high-energy physics nor conventional condensed matter systems,
the so-called "Fermi Arcs". Here we present Shubnikov-de Haas oscillations
involving the Fermi Arc states in Focused Ion Beam prepared microstructures of
CdAs. Their unusual magnetic field periodicity and dependence on sample
thickness can be well explained by recent theoretical work predicting novel
quantum paths weaving the Fermi Arcs together with chiral bulk states, forming
"Weyl orbits". In contrast to conventional cyclotron orbits, these are governed
by the chiral bulk dynamics rather than the common momentum transfer due to the
Lorentz force. Our observations provide evidence for direct access to the
topological properties of charge in a transport experiment, a first step
towards their potential application.Comment: 25 pages, 11 figures, final published versio
Phonon collapse and anharmonic melting of the 3D charge-density wave in kagome metals
The charge-density wave (CDW) mechanism and resulting structure of the AV3Sb5 family of kagome metals has posed a puzzling challenge since their discovery four years ago. In fact, the lack of consensus on the origin and structure of the CDW hinders the understanding of the emerging phenomena. Here, by employing a non-perturbative treatment of anharmonicity from first-principles calculations, we reveal that the charge-density transition in CsV3Sb5 is driven by the large electron-phonon coupling of the material and that the melting of the CDW state is attributed to ionic entropy and lattice anharmonicity. The calculated transition temperature is in very good agreement with experiments, implying that soft mode physics are at the core of the charge-density wave transition. Contrary to the standard assumption associated with a pure kagome lattice, the CDW is essentially three-dimensional as it is triggered by an unstable phonon at the L point. The absence of involvement of phonons at the M point enables us to constrain the resulting symmetries to six possible space groups. The unusually large electron-phonon linewidth of the soft mode explains why inelastic scattering experiments did not observe any softened phonon. We foresee that large anharmonic effects are ubiquitous and could be fundamental to understand the observed phenomena also in other kagome families
Scale-invariant magnetic anisotropy in RuCl at high magnetic fields
In RuCl, inelastic neutron scattering and Raman spectroscopy reveal a
continuum of non-spin-wave excitations that persists to high temperature,
suggesting the presence of a spin liquid state on a honeycomb lattice. In the
context of the Kitaev model, magnetic fields introduce finite interactions
between the elementary excitations, and thus the effects of high magnetic
fields - comparable to the spin exchange energy scale - must be explored. Here
we report measurements of the magnetotropic coefficient - the second derivative
of the free energy with respect to magnetic field orientation - over a wide
range of magnetic fields and temperatures. We find that magnetic field and
temperature compete to determine the magnetic response in a way that is
independent of the large intrinsic exchange interaction energy. This emergent
scale-invariant magnetic anisotropy provides evidence for a high degree of
exchange frustration that favors the formation of a spin liquid state in
RuCl.Comment: arXiv admin note: substantial text overlap with arXiv:1901.09245.
Nature Physic
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