An ultraviolet transmitting glass containing, in mole percentage based on oxides, 55 to 80% of SiO.sub.2, 12 to 27% of B.sub.2O.sub.3, 4 to 20% of R.sub.2O (where R represents an alkali metal selected from a group consisting of Li, Na, and K) in total, 0 to 3.5% of Al.sub.2O.sub.3, 0 to 5% of RO (where R represents an alkaline earth metal selected from a group consisting of Mg, Ca, Sr, and Ba) in total, 0 to 5% of ZnO, and 0 to 10% of ZrO.sub.2, wherein transmittance at a wavelength of 254 nm in terms of spectral transmittance at a plate thickness of 0.5 mm is 70% or more. The glass with high ultraviolet light transmittance, in particular, high deep ultraviolet light transmittance is provided.

A method for making a chalcogenide glass waveguide in a liquid crystal-based non-mechanical beam steering device that permits steering in the mid-wave infrared. The waveguide core, the subcladding, or both comprise a chalcogenide glass. A mask is used to produce a tapered subcladding. Also disclosed is the related non-mechanical beam steering device that includes a chalcogenide waveguide.

The present invention provides a photonic device such as a variable optical attenuator, in which two signal components, propagating in modes of two different polarization states, are converted to two different modes of the same polarization state prior to modulation. The modulation of both components is performed by a single device which applies the same modulation strength to both components. The two signal components can be converted back to propagate in the two different polarization states following modulation.

The invention relates generally to optically high transparency and adjustable haze, superomniphobic, rigid and flexible structures and, more particularly, to fused silica glass and flexible plastic, e.g., polymer, structures having a sub-wavelength texture formed on a surface thereof, which is effective to impart the optical properties of high transparency and adjustable haze to the structures. The texture is reentrant. Additionally, the optically high transparency and adjustable haze structures include a silicon dioxide coating applied to the texture and a treatment of a low surface energy material deposited on the silicon dioxide coating. The silicon dioxide coating renders the structures super hydrophilic, and the low surface energy material treatment renders the structures superomniphobic.

A package comprises a photonic integrated circuit (PIC) with a modulator having a first modulator input, and a PIC interconnect region within two millimeters or fifty microns from the modulator. Additionally, an electric integrated circuit (EIC) is included with a driver circuit and an EIC interconnect region within two millimeters or fifty microns from the driver circuit. The driver circuit is electrically connected to the first modulator input via the EIC interconnect region, a first metal interconnect, and the PIC interconnect region. The modulator receives a temperature-dependent bias voltage, where the temperature dependence of the bias voltage inversely matches the temperature dependence of the modulator across an extended temperature range.

An optical module of one embodiment includes a semiconductor modulator having a rectangular planar shape, an input lens system facing the input port, a first output lens system facing the first output port, a second output lens system facing the second output port, a first monitor element facing the first monitor port, a second monitor element facing the second monitor port, a first polarizer disposed between the first monitor port and the first monitor element, and a second polarizer disposed between the second monitor port and the second monitor element.

The present disclosure relates to humidity sensitive nano-photonics and a manufacturing method thereof, and more particularly to humidity sensitive nano-photonics including a metasurface and a method for manufacturing the same.

The humidity sensitive nano-photonics and the manufacturing method thereof according to an embodiment of the present disclosure include a metasurface that are capable of expanding and contracting depending on changes in the relative humidity of the surrounding environment, and have the advantage of being easily manufactured, mass-produced at low cost, capable of effectively adjusting the phase and intensity of light, and applicable to various materials and various shapes of surfaces as well.

A metasurface may include a substrate layer and a two-dimensional array of metallic optical pillars arranged in rows and columns. A tunable dielectric material with a tunable refractive index is positioned between row-adjacent optical resonators. A two-dimensional active-matrix driver includes integrated driver routing layer(s), capacitor layer(s), and/or transistor layer(s). The driver routing layers enable row and column addressing of the two-dimensional array of metallic pillars via a row conductor for each row of metallic pillars and a column conductor for each column of metallic pillars. A transistor layer includes transistor devices connected to and configured to be selectively driven by the row and column conductors. The capacitor layer includes a plurality of storage capacitors. Each metallic pillar is connected in parallel to one of the storage capacitors in the capacitor layer and one of the transistor devices in the transistor layer.

An optical system has a beam-steering device having a planar waveguide region between a tapered incoupler and a tapered outcoupler that respectively define opposing incoupler and outcoupler facets of the BS device. Each region has a substrate, a subcladding layer over the substrate, a core layer over the subcladding, and a top cladding layer over the core. Within the incoupler, at least one of the subcladding and the top cladding has a material having a refractive index that varies with an applied field (e.g., an electric field) applied at the incoupler. The optical system also has a field-applying device that applies the applied field at the incoupler, an output detector that generates a feedback signal based on detected outgoing light output from the outcoupler, and a controller that controls the field-applying device based on the feedback signal to alter the light output from the outcoupler.

A Photonic molecule may include a first ring resonator that is tunable by a first piezoelectric actuator. A Photonic molecule may include a second ring resonator that is tunable by a second piezoelectric actuator, wherein the second ring resonator optically coupled to the first ring resonator. A Photonic molecule may include a third ring resonator that is tunable by a third piezoelectric actuator, wherein the third ring resonator is optically coupled to the first ring resonator and the second ring resonator. A Photonic molecule may include a waveguide optically coupled to the first ring resonator.