72 research outputs found
Inverse Cotton-Mouton effect of the Vacuum and of atomic systems
In this letter we calculate the Inverse Cotton-Mouton Effect (ICME) for the
vacuum following the predictions of Quantum ElectroDynamics. We compare the
value of this effect for the vacuum with the one expected for atomic systems.
We finally show that ICME could be measured for the first time for noble gases
using state-of-the-art laser systems and for the quantum vacuum with
near-future laser facilities like ELI and HiPER, providing in particular a test
of the nonlinear behaviour of quantum vacuum at intensities below the Schwinger
limit of 4.5x10^33 W/m^2.Comment: Submitted to EP
Superadiabatic thermalization of a quantum oscillator by engineered dephasing
Fast nonadiabatic control protocols known as shortcuts to adiabaticity have
found a plethora of applications, but their use has been severely limited to
speeding up the dynamics of isolated quantum systems. We introduce shortcuts
for open quantum processes that make possible the fast control of Gaussian
states in non-unitary processes. Specifically, we provide the time modulation
of the trap frequency and dephasing strength that allow preparing an arbitrary
thermal state in a finite time. Experimental implementation can be done via
stochastic parametric driving or continuous measurements, readily accessible in
a variety of platforms.Comment: 5+4 pp, 3 figure
New bounds on millicharged particles from cosmology
Particles with millicharge q and sub-eV mass can be produced in photon-photon
collisions, distorting the energy spectrum of the Cosmic Microwave Background.
We derive the conservative bound q < 10^-7 e (as well as model-dependent bounds
two orders of magnitude stronger), incompatible with proposed interpretations
of the PVLAS anomaly based on millicharged production or on
millicharged-mediated axion-like couplings.Comment: 7 pages, 2 figures. Final versio
Furin, a transcriptional target of NKX2-5, has an essential role in heart development and function
The homeodomain transcription factor NKX2-5 is known to be essential for both normal heart development and for heart function. But little is yet known about the identities of its downstream effectors or their function during differentiation of cardiac progenitor cells (CPCs). We have used transgenic analysis and CRISPR-mediated ablation to identify a cardiac enhancer of the Furin gene. The Furin gene, encoding a proprotein convertase, is directly repressed by NKX2-5. Deletion of Furin in CPCs is embryonic lethal, with mutant hearts showing a range of abnormalities in the outflow tract. Those defects are associated with a reduction in proliferation and premature differentiation of the CPCs. Deletion of Furin in differentiated cardiomyocytes results in viable adult mutant mice showing an elongation of the PR interval, a phenotype that is consistent with the phenotype of mice and human mutant for Nkx2-5. Our results show that Furin mediate some aspects of Nkx2-5 function in the heart
Zemach and magnetic radius of the proton from the hyperfine splitting in hydrogen
The current status of the determination of corrections to the hyperfine
splitting of the ground state in hydrogen is considered. Improved calculations
are provided taking into account the most recent value for the proton charge
radius. Comparing experimental data with predictions for the hyperfine
splitting, the Zemach radius of the proton is deduced to be fm.
Employing exponential parametrizations for the electromagnetic form factors we
determine the magnetic radius of the proton to be fm. Both values
are compared with the corresponding ones derived from the data obtained in
electron-proton scattering experiments and the data extracted from a rescaled
difference between the hyperfine splittings in hydrogen and muonium
Birefringence of interferential mirrors at normal incidence Experimental and computational study
In this paper we present a review of the existing data on interferential
mirror birefringence. We also report new measurements of two sets of mirrors
that confirm that mirror phase retardation per reflection decreases when mirror
reflectivity increases. We finally developed a computational code to calculate
the expected phase retardation per reflection as a function of the total number
of layers constituting the mirror. Different cases have been studied and we
have compared computational results with the trend of the experimental data.
Our study indicates that the origin of the mirror intrinsic birefringence can
be ascribed to the reflecting layers close to the substrate.Comment: To be published in Applied Physics
Searching for energetic cosmic axions in a laboratory experiment: testing the PVLAS anomaly
Astrophysical sources of energetic gamma rays provide the right conditions
for maximal mixing between (pseudo)scalar (axion-like) particles and photons if
their coupling is as strong as suggested by the PVLAS claim. This is
independent of whether or not the axion interaction is standard at all energies
or becomes supressed in the extreme conditions of the stellar interior. The
flux of such particles through the Earth could be observed using a metre long,
Tesla strength superconducting solenoid thus testing the axion interpretation
of the PVLAS anomaly. The rate of events in CAST caused by axions from the Crab
pulsar is also estimated for the PVLAS-favoured parameters.Comment: 5 pages, 3 figur
Proton Zemach radius from measurements of the hyperfine splitting of hydrogen and muonic hydrogen
While measurements of the hyperfine structure of hydrogen-like atoms are
traditionally regarded as test of bound-state QED, we assume that theoretical
QED predictions are accurate and discuss the information about the
electromagnetic structure of protons that could be extracted from the
experimental values of the ground state hyperfine splitting in hydrogen and
muonic hydrogen. Using recent theoretical results on the proton polarizability
effects and the experimental hydrogen hyperfine splitting we obtain for the
Zemach radius of the proton the value 1.040(16) fm. We compare it to the
various theoretical estimates the uncertainty of which is shown to be larger
that 0.016 fm. This point of view gives quite convincing arguments in support
of projects to measure the hyperfine splitting of muonic hydrogen.Comment: Submitted to Phys. Rev.
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