13 research outputs found
Terahertz-Mediated Microwave-to-Optical Transduction
Transduction of quantum signals between the microwave and the optical ranges
will unlock powerful hybrid quantum systems enabling information processing
with superconducting qubits and low-noise quantum networking through optical
photons. Most microwave-to-optical quantum transducers suffer from thermal
noise due to pump absorption. We analyze the coupled thermal and wave dynamics
in electro-optic transducers that use a two-step scheme based on an
intermediate frequency state in the THz range. Our analysis, supported by
numerical simulations, shows that the two-step scheme operating with a
continuous pump offers near-unity external efficiency with a multi-order noise
suppression compared to direct transduction. As a result, two-step
electro-optic transducers may enable quantum noise-limited interfacing of
superconducting quantum processors with optical channels at MHz-scale bitrates
Anomalous polarization-dependent transport in nanoscale double-barrier superconductor/ferromagnet/superconductor junctions
We study the transport properties of nanoscale superconducting (S) devices in
which two superconducting electrodes are bridged by two parallel ferromagnetic
(F) wires, forming an SFFS junction with a separation between the two wires
less than the superconducting coherence length. This allows crossed Andreev
reflection to take place. We find that the resistance as a function of
temperature exhibits behavior reminiscent of the re-entrant effect and, at low
temperatures and excitation energies below the superconducting gap, the
resistance corresponding to antiparallel alignment of the magnetization of the
ferromagnetic wires is higher than that of parallel alignment, in contrast to
the behavior expected from crossed Andreev reflection. We present a model based
on spin-dependent interface scattering that explains this surprising result and
demonstrates the sensitivity of the junction transport properties to
interfacial parameters.Comment: 5 pages, 3 figure
Evidence for a robust sign-changing s-wave order parameter in monolayer films of superconducting Fe (Se,Te)/Bi2Te3
The Fe-based superconductor Fe (Se,Te) combines non-trivial topology with
unconventional superconductivity and may be an ideal platform to realize exotic
states such as high-order topological corner modes and Majorana modes. Thin
films of Fe (Se,Te) are important for device fabrication, phase sensitive
transport measurements and for realizing proposals to engineer higher-order
modes. However, while bulk Fe (Se,Te) has been extensively studied with a
variety of techniques, the nature of the superconducting order parameter in the
monolayer limit has not yet been explored. In this work, we study monolayer
films of Fe (Se,Te) on Bi2Te3 with scanning tunneling spectroscopy and
Bogoliubov quasiparticle interference (BQPI). We discover that the monolayer Fe
(Se,Te)/Bi2Te3 heterostructures host a robust, multigap superconducting state
that strongly resembles the bulk. BQPI maps at the gap energies show a strong
spatial modulation, oriented 45 degrees to the Fe-Se bond direction. Analysis
of the phase-referenced quasiparticle interference signal reveals a
sign-changing s-wave order parameter similar to the bulk. Moreover, we observe
a unique pattern of sign changes in the BQPI signal which have not been
observed in the bulk. Our work establishes monolayer Fe (Se,Te)/Bi2Te3 as a
robust multi-band unconventional superconductor and sets the stage for
explorations of non-trivial topology in this highly-tunable system.Comment: 23 pages, 4 figure
Imaging spontaneous currents in superconducting arrays of pi-junctions
Superconductors separated by a thin tunneling barrier exhibit the Josephson
effect that allows charge transport at zero voltage, typically with no phase
shift between the superconductors in the lowest energy state. Recently,
Josephson junctions with ground state phase shifts of pi proposed by theory
three decades ago have been demonstrated. In superconducting loops,
pi-junctions cause spontaneous circulation of persistent currents in zero
magnetic field, analogous to spin-1/2 systems. Here we image the spontaneous
zero-field currents in superconducting networks of temperature-controlled
pi-junctions with weakly ferromagnetic barriers using a scanning SQUID
microscope. We find an onset of spontaneous supercurrents at the 0-pi
transition temperature of the junctions Tpi = 3 K. We image the currents in
non-uniformly frustrated arrays consisting of cells with even and odd numbers
of pi-junctions. Such arrays are attractive model systems for studying the
exotic phases of the 2D XY-model and achieving scalable adiabatic quantum
computers.Comment: Pre-referee version. Accepted to Nature Physic
Quasi-particle Lifetimes in a d_{x^2-y^2} Superconductor
We consider the lifetime of quasi-particles in a d-wave superconductor due to
scattering from antiferromagnetic spin-fluctuations, and explicitly separate
the contribution from Umklapp processes which determines the electrical
conductivity. Results for the temperature dependence of the total scattering
rate and the Umklapp scattering rate are compared with relaxation rates
obtained from thermal and microwave conductivity measurements, respectively.Comment: 14 pages, 4 figure
Phase Coherence and Andreev Reflection in Topological Insulator Devices
Topological insulators (TIs) have attracted immense interest because they host helical surface states. Protected by time-reversal symmetry, they are robust to nonmagnetic disorder. When superconductivity is induced in these helical states, they are predicted to emulate p-wave pairing symmetry, with Majorana states bound to vortices. Majorana bound states possess non-Abelian exchange statistics that can be probed through interferometry. Here, we take a significant step towards Majorana interferometry by observing pronounced Fabry-PĂ©rot oscillations in a TI sandwiched between a superconducting and a normal lead. For energies below the superconducting gap, we observe a doubling in the frequency of the oscillations, arising from an additional phase from Andreev reflection. When a magnetic field is applied perpendicular to the TI surface, a number of very sharp and gate-tunable conductance peaks appear at or near zero energy, which has consequences for interpreting spectroscopic probes of Majorana fermions. Our results demonstrate that TIs are a promising platform for exploring phase-coherent transport in a solid-state system