Entanglement and classical nonseparability convertible from orthogonal polarizations.

The nonclassicality of a macroscopic single-mode optical superposition state is potentially convertible into entanglement, when the state is mixed with the vacuum on a beam splitter. Considering light beams with polarization degree of freedom in Euclidean space as coherent product states in a bipartite Hilbert space, we propose a method to convert the two orthogonal polarizations into simultaneous entanglement and classical nonseparability through nonclassicality in the superpositions of coherent and displaced Fock states. Equivalent Bell state emerges from the resulted superpositions and the proportion of mixed entanglement and nonseparablity is determined by the displacement amplitudes along the polarization directions.

Computing Shor's algorithmic steps with interference patterns of classical light.

When considered as orthogonal bases in distinct vector spaces, the unit vectors of polarization directions and the Laguerre-Gaussian modes of polarization amplitude are inseparable, constituting a so-called classical entangled light beam. Equating this classical entanglement to quantum entanglement necessary for computing purpose, we show that the parallelism featured in Shor's factoring algorithm is equivalent to the concurrent light-path propagation of an entangled beam or pulse train. A gedanken experiment is proposed for executing the key algorithmic steps of modular exponentiation and Fourier transform on a target integer N using only classical manipulations on the amplitudes and polarization directions.

Wideband Microwave Photonic Circulator Using Two Asymmetric Partial-Height Triangle Ferrites.

Broadband 5G communication requires the operation of nonreciprocal devices in the Ku band. A wideband photonic crystal circulator is implemented by introducing two partial-height triangular Ni-Zn ferrites into the AlO ceramic rod-arrays. The asymmetric sizes of the two equilateral triangles paired with self-matching effectively extend the bandwidth of the circulator eight times over that of the symmetric scheme.

Advanced sensitivity amplification strategies for voltammetric immunosensors of tumor marker: State of the art.

Immunosensors are molecular recognition-based solid-state biosensing devices, in which the immunochemical reactions are coupled with transducers. As biologic or biochemical substances produced by tumor cells, tumor marker plays an important role in clinical diagnosis and treatment of cancer because its concentration is related to tumor size, clinical stage, and predicting prognosis. Voltammetric immunosensors based on the electrochemical analysis technique provide a sensitive electroanalytical approach for quantitatively detecting tumor markers by measuring the current as a function of the potential.

Synchronization of two cavity-coupled qubits measured by entanglement.

Some nonlinear radiations such as superfluorescence can be understood as cooperative effects between atoms. We regard cooperative radiations as a manifested effect secondary to the intrinsic synchronization among the two-level atoms and propose the entanglement measure, concurrence, as a time-resolved measure of synchronization. Modeled on two cavity-coupled qubits, the evolved concurrence monotonically increases to a saturated level.