The standard model of particle physics currently provides our best description of fundamental particles and their interactions. The theory predicts that the different charged leptons, the electron, muon and tau, have identical electroweak interaction strengths. Previous measurements have shown that a wide range of particle decays are consistent with this principle of lepton universality. This article presents evidence for the breaking of lepton universality in beauty-quark decays, with a significance of 3.1 standard deviations, based on proton–proton collision data collected with the LHCb detector at CERN’s Large Hadron Collider. The measurements are of processes in which a beauty meson transforms into a strange meson with the emission of either an electron and a positron, or a muon and an antimuon. If confirmed by future measurements, this violation of lepton universality would imply physics beyond the standard model, such as a new fundamental interaction between quarks and leptons.
Electrochemical
CO2 reduction over Cu could provide
value-added multicarbon hydrocarbons and alcohols. Despite recent
breakthroughs, it remains a significant challenge to design a catalytic
system with high product selectivity. Here we demonstrate that a high
selectivity of ethylene (55%) and C2+ products (77%) could
be achieved by a highly modular tricomponent copolymer modified Cu
electrode, rivaling the best performance using other modified polycrystalline
Cu foil catalysts. Such a copolymer can be conveniently prepared by
a ring-opening metathesis polymerization, thereby offering a new degree
of freedom for tuning the selectivity. Control experiments indicate
all three components are essential for the selectivity enhancement.
A surface characterization showed that the incorporation of a phenylpyridinium
component increased the film robustness against delamination. It was
also shown that its superior performance is not due to a morphology
change of the Cu underneath. Molecular dynamics (MD) simulations indicate
that a combination of increased local CO2 concentration,
increased porosity for gas diffusion, and the local electric field
effect together contribute to the increased ethylene and C2+ product selectivity.
Kinetic energy transfer in compressible isotropic turbulence is studied using numerical simulations with solenoidal forcing at turbulent Mach numbers ranging from 0.4 to 1.0 and at a Taylor Reynolds number of approximately 250. The pressure dilatation plays an important role in the local conversion between kinetic energy and internal energy, but its net contribution to the average kinetic energy transfer is negligibly small, due to the cancellation between compression and expansion work. The right tail of probability density function (PDF) of the subgrid-scale (SGS) flux of kinetic energy is found to be longer at higher turbulent Mach numbers. With an increase of the turbulent Mach number, compression motions enhance the positive SGS flux, and expansion motions enhance the negative SGS flux. Average of SGS flux conditioned on the filtered velocity divergence is studied by numerical analysis and a heuristic model. The conditional average of SGS flux is shown to be proportional to the square of filtered velocity divergence in strong compression regions for turbulent Mach numbers from 0.6 to 1.0. Moreover, the antiparallel alignment between the large-scale strain and the SGS stress is observed in strong compression regions. The inter-scale transfer of solenoidal and compressible components of kinetic energy is investigated by Helmholtz decomposition. The SGS flux of solenoidal kinetic energy is insensitive to the change of turbulent Mach number, while the SGS flux of compressible kinetic energy increases drastically as the turbulent Mach number becomes larger. The compressible mode persistently absorbs energy from the solenoidal mode through nonlinear advection. The kinetic energy of the compressible mode is transferred from large scales to small scales through the compressible SGS flux, and is dissipated by viscosity at small scales.
In the original paper Phys. Rev. D 95, 052004 (2017), "Measurements of charm mixing and CP violation using D 0 → K AE π ∓ decays," the systematic uncertainties reported in Table II regarding the doubly tagged (DT) only result for ðx 0þ Þ 2 and y 0þ were swapped in both the "no direct CPV" and "all CPV allowed" fits. All other reported values are correct. The corrected table is shown below in Table II.
The conservative cascade of kinetic energy is established using both Fourier analysis and a new exact physical-space flux relation in a simulated compressible turbulence. The subgrid scale (SGS) kinetic energy flux of the compressive mode is found to be significantly larger than that of the solenoidal mode in the inertial range, which is the main physical origin for the occurrence of Kolmogorov's -5/3 scaling of the energy spectrum in compressible turbulence. The perfect antiparallel alignment between the large-scale strain and the SGS stress leads to highly efficient kinetic energy transfer in shock regions, which is a distinctive feature of shock structures in comparison with vortex structures. The rescaled probability distribution functions of SGS kinetic energy flux collapse in the inertial range, indicating a statistical self-similarity of kinetic energy cascades.
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