1,341 research outputs found
Prediction of Debye-Scherrer diffraction patterns in arbitrarily strained samples
The prediction of Debye-Scherrer diffraction patterns from strained samples
is typically conducted in the small strain limit. Although valid for small
deviations from the hydrostat (such as the conditions of finite strength
typically observed in diamond anvil cells) this assertion is likely to fail for
the large strain anisotropies (often of order 10% in normal strain) such as
those found in uniaixally loaded dynamic compression experiments. In this paper
we derive a general form for the (\theta_B, \phi) dependence of the diffraction
for an arbitrarily deformed sample in arbitrary geometry. We show that this
formula is consistent with ray traced diffraction for highly strained
computationally generated polycrystals, and that the formula shows deviations
from the small strain solutions previously reported
Approaching a topological phase transition in Majorana nanowires
Recent experiments have produced mounting evidence of Majorana zero modes in
nanowire-superconductor hybrids. Signatures of an expected topological phase
transition accompanying the onset of these modes nevertheless remain elusive.
We investigate a fundamental question concerning this issue: Do well-formed
Majorana modes necessarily entail a sharp phase transition in these setups?
Assuming reasonable parameters, we argue that finite-size effects can
dramatically smooth this putative transition into a crossover, even in systems
large enough to support well-localized Majorana modes. We propose overcoming
such finite-size effects by examining the behavior of low-lying excited states
through tunneling spectroscopy. In particular, the excited-state energies
exhibit characteristic field and density dependence, and scaling with system
size, that expose an approaching topological phase transition. We suggest
several experiments for extracting the predicted behavior. As a useful
byproduct, the protocols also allow one to measure the wire's spin-orbit
coupling directly in its superconducting environment.Comment: 13 pages, 8 figure
Proximal phalanx shaft fracture with entrapment in the transverse retinacular ligament: a case report
We report the interesting case of a 33 years old male who underwent operative intervention for a left oblique proximal phalanx shaft fracture of the third finger which penetrated the transverse retinacular ligament (TRL). This patient required operative intervention due to entrapment of the bony fragment in the TRL which acted as a noose with traction on the fractured segment. The fracture was irreducible through a closed maneuver. The use of a dorsal approach allowed visualization of the fracture site and implementation of screws for fixation was deemed adequate secondary to the patient’s bone quality. He was placed in a volar splint at the conclusion of the case to allow for immobilization and protection of the repair. At follow-up, the patient’s radiographic images appeared appropriate and was progressing as expected. We report lessons learned from this case and describe a previously unreported fracture pattern and a possible method of reduction and fixation through a surgical approach in this report
Salter-Harris type II fracture of the middle phalanx with concomitant central slip injury in an 11 year old: a case report
An 11-year-old male sustained an irreducible, completely displaced epiphyseal fracture of the proximal interphalangeal joint (PIPJ) of the middle finger with an associated central slip injury. Central slip injuries occurring in conjunction with Salter-Harris type II middle phalanx fracture are rare entities, with no previously documented case. Our patient underwent open reduction, internal fixation through crossed-pins to achieve reduction and fixation. He was then splinted in extension for six weeks to allow healing of the central slip injury. At 1-year follow-up, the patient had full range-of-motion with no clinical indication of physeal disruption or growth arrest of the repaired digit. We demonstrate a case in which ephiphyseal fractures of the proximal interphalangeal joint with a concomitant central slip injury can safely be treated with open reduction internal fixation combined with a period of immobilization. We characterize a surgical method of reduction and fixation with splinted immobilization and describe lessons learned from this previously unreported case
Nonlocal conductance spectroscopy of Andreev bound states: Symmetry relations and BCS charges
Two-terminal conductance spectroscopy of superconducting devices is a common
tool for probing Andreev and Majorana bound states. Here, we study
theoretically a three-terminal setup, with two normal leads coupled to a
grounded superconducting terminal. Using a single-electron scattering matrix,
we derive the subgap conductance matrix for the normal leads and discuss its
symmetries. In particular, we show that the local and the nonlocal elements of
the conductance matrix have pairwise identical antisymmetric components.
Moreover, we find that the nonlocal elements are directly related to the local
BCS charges of the bound states close to the normal probes and we show how the
BCS charge of overlapping Majorana bound states can be extracted from
experiments.Comment: 7 page
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Quantum Dots for Conventional and Topological Qubits
This thesis presents a series of quantum dot studies, performed with an eye towards improved conventional and topological qubits. Chapters 1-3 focus on improved conventional (spin) qubits; Chapters 4-6 focus on the topological Majorana qubits.
Chapter 1 presents the first investigation of Coulomb peak height distributions in a spin-orbit coupled quantum dot, realized in a Ge/Si nanowire. Strong spin-orbit coupling in this hole-gas system leads to antilocalization of Coulomb blockade peaks, consistent with theory. In particular, the peak height distribution has its maximum away from zero at zero magnetic field, with an average that decreases with increasing field. Magnetoconductance in the open-wire regime places a bound on the spin-orbit length (lso < 20 nm), consistent with values extracted in the Coulomb blockade regime (lso < 25 nm).
Chapters 2 & 3 demonstrate operation of improved spin qubits. Chapter 2 continues the investigation of Ge/Si nanowires, demonstrating a qubit with tenfold-improved dephasing time compared to the standard GaAs case. e combination of long dephasing time and strong spin-orbit coupling suggests that Ge/Si nanowires are promising for a spin-orbit qubit. In Chap. 3, multi-electron spin qubits are operated in GaAs, and improved resilience to charge noise is found compared to the single-electron case.
Chapters 4 & 5, present a series of studies on composite superconductor/semiconductor Al/InAs quantum dots. Detailed study of transport cycles and Coulomb blockade peak spacings in zero magnetic field are presented in Chap. 4, and the parity lifetime of a bound state in the nanowire is inferred to exceed 10 milliseconds. Next, in Chap. 5, finite magnetic field behavior is investigated while varying quantum dot length. Coulomb peak spacings are consistent with the emergence of Majorana modes in the quantum dot. The robustness of Majorana modes to magnetic-field perturbations is measured, and is found to be exponential with increasing nanowire length. Coulomb peak heights are also investigated, and show signatures of electron teleportation by Majorana fermions.
Finally, Chap. 6 outlines some schemes to create topological Majorana qubits. Using experimental techniques similar to those in Chap.’s 2 & 3, it may be possible to demonstrate Majorana initialization, readout, and fusion rules.Physic
Evidence of the Harmonic Faraday Instability in Ultrasonic Atomization Experiments with a Deep, Inviscid Fluid
A popular method for generating micron-sized aerosols is to submerge ultrasonic (ω~MHz) piezoelectric oscillators in a water bath. The submerged oscillator atomizes the fluid, creating droplets with radii proportional to the wavelength of the standing wave at the fluid surface. Classical theory for the Faraday instability predicts a parametric instability driving a capillary wave at the subharmonic (ω/2) frequency. For many applications it is desirable to reduce the size of the droplets; however, using higher frequency oscillators becomes impractical beyond a few MHz. Observations are presented that demonstrate that smaller droplets may also be created by increasing the driving amplitude of the oscillator, and that this effect becomes more pronounced for large driving frequencies. It is shown that these observations are consistent with a transition from droplets associated with subharmonic (ω/2) capillary waves to harmonic (ω) capillary waves induced by larger driving frequencies and amplitudes, as predicted by a stability analysis of the capillary waves
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