1,751 research outputs found
State estimation: direct state measurement vs. tomography
We compare direct state measurement (DST or weak state tomography) to
conventional state reconstruction (tomography) through accurate Monte-Carlo
simulations. We show that DST is surprisingly robust to its inherent bias. We
propose a method to estimate such bias (which introduces an unavoidable error
in the reconstruction) from the experimental data. As expected we find that DST
is much less precise than tomography. We consider both finite and
infinite-dimensional states of the DST pointer, showing that they provide
comparable reconstructions.Comment: 4 pages, 4 figure
Linear Stability Analysis of a Levitated Nanomagnet in a Static Magnetic Field: Quantum Spin Stabilized Magnetic Levitation
We theoretically study the levitation of a single magnetic domain nanosphere
in an external static magnetic field. We show that apart from the stability
provided by the mechanical rotation of the nanomagnet (as in the classical
Levitron), the quantum spin origin of its magnetization provides two additional
mechanisms to stably levitate the system. Despite of the Earnshaw theorem, such
stable phases are present even in the absence of mechanical rotation. For large
magnetic fields, the Larmor precession of the quantum magnetic moment
stabilizes the system in full analogy with magnetic trapping of a neutral atom.
For low magnetic fields, the magnetic anisotropy stabilizes the system via the
Einstein-de Haas effect. These results are obtained with a linear stability
analysis of a single magnetic domain rigid nanosphere with uniaxial anisotropy
in a Ioffe-Pritchard magnetic field.Comment: Published version. 10 pages, 4 figures, 3 table
Hybrid Architecture for Engineering Magnonic Quantum Networks
We show theoretically that a network of superconducting loops and magnetic
particles can be used to implement magnonic crystals with tunable magnonic band
structures. In our approach, the loops mediate interactions between the
particles and allow magnetic excitations to tunnel over long distances. As a
result, different arrangements of loops and particles allow one to engineer the
band structure for the magnonic excitations. Furthermore, we show how magnons
in such crystals can serve as a quantum bus for long-distance magnetic coupling
of spin qubits. The qubits are coupled to the magnets in the network by their
local magnetic-dipole interaction and provide an integrated way to measure the
state of the magnonic quantum network.Comment: Manuscript: 4 pages, 3 figures. Supplemental Material: 9 pages, 4
figures. V2: Published version in PRA: 14 pages + 8 figures. Substantial
rearrangement of the content of the previous versio
Quantum Spin Stabilized Magnetic Levitation
We theoretically show that, despite Earnshaw's theorem, a non-rotating single
magnetic domain nanoparticle can be stably levitated in an external static
magnetic field. The stabilization relies on the quantum spin origin of
magnetization, namely the gyromagnetic effect. We predict the existence of two
stable phases related to the Einstein--de Haas effect and the Larmor
precession. At a stable point, we derive a quadratic Hamiltonian that describes
the quantum fluctuations of the degrees of freedom of the system. We show that
in the absence of thermal fluctuations, the quantum state of the nanomagnet at
the equilibrium point contains entanglement and squeezing.Comment: Published version. 5 pages, 2 figure
Exploiting the photonic nonlinearity of free-space subwavelength arrays of atoms
Ordered ensembles of atoms, such as atomic arrays, exhibit distinctive
features from their disordered counterpart. In particular, while collective
modes in disordered ensembles show a linear optical response, collective
subradiant excitations of subwavelength arrays are endowed with an intrinsic
non-linearity. Such non-linearity has both a coherent and a dissipative
component: two excitations propagating in the array scatter off each other
leading to formation of correlations and to emission into free space modes. We
show how to take advantage of such non-linearity to coherently prepare a single
excitation in a subradiant (dark) collective state of a one dimensional array
as well as to perform an entangling operation on dark states of parallel
arrays. We discuss the main source of errors represented by disorder introduced
by atomic center-of-mass fluctuations, and we propose a practical way to
mitigate its effects.Comment: Published version. Minor typos corrected. 12+13 pages, 7+6 figure
Trafficking of Estrella lausannensis in human macrophages.
Estrella lausannensis is a new member of the Chlamydiales order. Like other Chlamydia-related bacteria, it is able to replicate in amoebae and in fish cell lines. A preliminary study investigating the pathogenic potential of Chlamydia-related bacteria found a correlation between antibody response to E. lausannensis and pneumonia in children. To further investigate the pathogenic potential of E. lausannensis, we determined its ability to grow in human macrophages and its intracellular trafficking. The replication in macrophages resulted in viable E. lausannensis; however, it caused a significant cytopathic effect. The intracellular trafficking of E. lausannensis was analyzed by determining the interaction of the Estrella-containing inclusions with various endocytic markers as well as host organelles. The E. lausannensis inclusion escaped the endocytic pathway rapidly avoiding maturation into phagolysosomes by preventing both EEA-1 and LAMP-1 accumulation. Compared to Waddlia chondrophila, another Chlamydia-related bacteria, the recruitment of mitochondria and endoplasmic reticulum was minimal for E. lausannensis inclusions. Estrella lausannensis appears to use a distinct source of nutrients and energy compared to other members of the Chlamydiales order. In conclusion, we hypothesize that E. lausannensis has a restricted growth in human macrophages, due to its reduced capacity to control programmed cell death
An innovative technique for the investigation of the 4-fold forbidden beta-decay of V
For the first time a Vanadium-based crystal was operated as cryogenic
particle detector. The scintillating low temperature calorimetric technique was
used for the characterization of a 22 g YVO crystal aiming at the
investigation of the 4-fold forbidden non-unique decay of V.
The excellent bolometric performance of the compound together with high light
output of the crystal makes it an outstanding technique for the study of such
elusive rate process. The internal radioactive contaminations of the crystal
are also investigated showing that an improvement on the current status of
material selection and purification are needed, U and Th
are measured at the level of 28 mBq/kg, 1.3 Bq/kg and 28 mBq/kg, respectively.
In this work, we also discuss a future upgrade of the experimental set-up which
may pave the road for the detection of the rare V decay
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