Photonic rotators integrated on a substrate are disclosed for manipulating light polarization.

A display device and a manufacturing method thereof are disclosed. The display device comprises an upper substrate (103), a lower substrate (104), a solvent (102), and ellipsoids (101), and the solvent (102) and the ellipsoids (101) are provided between the upper substrate (103) and the lower substrate (104). The ellipsoids are configured for forming photonic crystals and have electromagnetic characteristics. By means of photonic crystals formed by the ellipsoids having a shape of oval spheres with a size in order of nanometer or sub-micrometer, the display device can change wavelength of reflected light and present different colors, thus color images can be displayed.

A display device and a manufacturing method thereof are disclosed. The display device comprises an upper substrate (103), a lower substrate (104), a solvent (102), and ellipsoids (101), and the solvent (102) and the ellipsoids (101) are provided between the upper substrate (103) and the lower substrate (104). The ellipsoids are configured for forming photonic crystals and have electromagnetic characteristics. By means of photonic crystals formed by the ellipsoids having a shape of oval spheres with a size in order of nanometer or sub-micrometer, the display device can change wavelength of reflected light and present different colors, thus color images can be displayed.

An optical module includes: first and second optical elements; third and fourth optical elements; a first polarization control element and a first reflective light modulator that are sequentially arranged in one of a positive direction of a first vector and a negative direction of a second vector from the second optical element; a second polarization control element and a second reflective light modulator that are sequentially arranged in one of a negative direction of the first vector and a positive direction of the second vector from the third optical element; and a sliding mechanism that relatively moves the first and second optical elements and the third and fourth optical elements in the direction of the first vector relative.

An optical module includes: first and second optical elements; third and fourth optical elements; a first polarization control element and a first reflective light modulator that are sequentially arranged in one of a positive direction of a first vector and a negative direction of a second vector from the second optical element; a second polarization control element and a second reflective light modulator that are sequentially arranged in one of a negative direction of the first vector and a positive direction of the second vector from the third optical element; and a sliding mechanism that relatively moves the first and second optical elements and the third and fourth optical elements in the direction of the first vector relative.

Exemplary apparatus and method are provided. In particular, an electromagnetic radiation can be emitted with, e.g. a light source arrangement. For example, the light source arrangement can include a cavity and a filter, and a spectrum of the electromagnetic radiation can be controlled, e.g., with such cavity and filter, to have a mean frequency that changes (i) at an absolute rate that is greater than about 100 terahertz per millisecond, and (ii) over a range that is greater than about 10 terahertz. Additionally or alternatively, the light source arrangement can include a frequency shifting device which can shift the mean frequency of the electromagnetic radiation.

A structure includes a first material, the first material including an artificially structured array of elements, the first material further being arranged in a pattern to at least partially form a photonic band gap in a band gap frequency range. The first material has an effective permeability or an effective permittivity in the band gap frequency range that is determined at least partially by the elements in the array.

Magneto-optical modulator-based systems and devices for transferring quantum information are described. Such systems can be used for many applications, including as part of quantum computers. An example system includes a quantum information system configured to provide a signal corresponding to at least one qubit. The system further includes a magneto-optical driver configured to receive the signal corresponding to the at least one qubit and process the signal to generate a current based on the signal corresponding to the at least one qubit. The system further includes a magneto-optical modulator configured to receive the current from the magneto-optical driver and provide a modulated light output by modulating a received light input based on the current.

Improved multilayered magneto-optic-plasmonic (“MOP”) films that are used in connection with surface plasmon detection that have a first layer comprising titanium, a second layer selected from a group consisting of gold and silver, a third layer comprising cobalt, and a fourth layer comprising gold are disclosed. In an embodiment, the film has a first titanium layer with a thickness of approximately 2 nm, a second gold layer with a thickness of 35 nm, a layer of cobalt having a thickness of approximately 8 nm and a fourth gold base layer having a thickness of approximately 10 nm.

Improved multilayered magneto-optic-plasmonic (“MOP”) films that are used in connection with surface plasmon detection that have a first layer comprising titanium, a second layer selected from a group consisting of gold and silver, a third layer comprising cobalt, and a fourth layer comprising gold are disclosed. In an embodiment, the film has a first titanium layer with a thickness of approximately 2 nm, a second gold layer with a thickness of 35 nm, a layer of cobalt having a thickness of approximately 8 nm and a fourth gold base layer having a thickness of approximately 10 nm.