A sensor for use in biosensing is disclosed. The sensor comprises a photonic crystal waveguide comprising a photonic crystal comprising holes in a layer of dielectric material and a waveguide in the photonic crystal. The sensor comprises at least one strip disposed on the photonic crystal waveguide, spaced apart along, and running across the photonic crystal waveguide so as to form respective strip cavities, each of the at least one strip including a respective layer of material for sensing presence of a respective analyte; and a slot running along the waveguide of the photonic crystal waveguide.

An optical device includes a first reflecting section, a second reflecting section, and a confining section. The first reflecting section is constituted of a thin-wire waveguide-type one-dimensional photonic crystal. The second reflecting section is constituted of a thin-wire waveguide-type one-dimensional photonic crystal of which a lattice constant differs from that of the first reflecting section. The confining section is sandwiched between the first reflecting section and the second reflecting section. A Fabry-Perot optical resonator is constituted by the first reflecting section, the confining section, and the second reflecting section.

A difference Δ1 between an equivalent refractive index of a first reflecting section and an equivalent refractive index of a core in a first region that corresponds to the first reflecting section and a difference between an equivalent refractive index of a second reflecting section and an equivalent refractive index of the core in a second region that corresponds to the second reflecting section is set so as to be greater than a difference between an equivalent refractive index of a confining section and an equivalent refractive index of the core in a third region that corresponds to the confining section.

A sensor device and a method of analyzing a component in a fluid are described. The sensor device comprises a planar substrate defining a substrate plane, an electromagnetic waveguide forming a waveguide resonator and extending in a length direction in a waveguide resonator plane parallel to the substrate plane, wherein the electromagnetic waveguide is supported on the substrate by a support structure, wherein the electromagnetic waveguide has a width in the waveguide resonator plane in a direction perpendicular to the length direction, and a height out of the waveguide plane in a direction perpendicular to the length direction.

A novel waveguide with excellent optical properties can be easily produced. The photonic nanowires based waveguide has a) a plurality of nanowires; each nanowire having a ridge shape; b) the nanowires are supported by a support substrate or partially or totally free standing; c) the support substrate further supports interfacing waveguides disposed on both sides of the plurality of nanowires. The special concept of present invention allows to align a number of ridge-shaped nanowire that enables to control the amount of light being outside the solid waveguide in the evanescence field. Further, the design is compatible with solid waveguides and offers the possibility to confine (guide the light) within a multiple waveguide arrangement.

Proposed is an optical component comprising: at least one first waveguide, the first waveguide comprising at least one partially reflective output end facet, wherein light passing the output end facet of the first waveguide propagates along a first propagation direction, and at least one second waveguide receiving the light passing the output end facet of the first waveguide at an input end facet of the second waveguide and guiding the light in a second propagation direction, wherein the output end facet and the input end facet are spaced from each other; and wherein the first waveguide and the second waveguide are arranged such that the first propagation direction and the second propagation direction are different. This proposal provides a concept, which is more efficient in view of coupling efficiency between the waveguides of the optical component.

Disclosed is a laser device. The laser device includes a substrate, a pump light source which is disposed on the substrate and provided with a light emitting layer configured to generate pump light, and an upper waveguide which is disposed above the pump light source in a first direction and provided with an upper resonator configured to allow laser light to be generated and resonate by using the pump light.

T-phase-shifted fiber Bragg gratings in optical waveguides, and methods of formation thereof. Sensing apparatus comprising such gratings using femtosecond pulse duration lasers and specialized transmission diffraction elements or phase masks.

Disclosed is a laser device. The laser device includes a substrate, a pump light source which is disposed on the substrate and provided with a light emitting layer configured to generate pump light, and an upper waveguide which is disposed above the pump light source in a first direction and provided with an upper resonator configured to allow laser light to be generated and resonate by using the pump light.

A method for non-intrusive pipeline testing involves constructing the pipeline at a construction location that is above ground, affixing an optical fiber along a surface of a length of the pipeline that is at the construction location, measuring dynamic strain experienced by the length of the pipeline by performing optical interferometry using the optical fiber, and moving the length of the pipeline from the construction location to a different installation location. The optical fiber includes at least one pair of fiber Bragg gratings (FBGs) tuned to reflect substantially identical wavelengths with a segment of the optical fiber extending between the FBGs.