A device for detecting electromagnetic radiation, including a substrate; at least one thermal detector, placed on the substrate, including an absorbing membrane suspended above the substrate; and an encapsulating structure encapsulating the thermal detector, including an encapsulating layer extending around and above the thermal detector so as to define with the substrate a cavity in which the thermal detector is located; wherein the encapsulating layer includes at least one through-orifice that is what is referred to as an exhaust vent, each exhaust vent being placed so that at least one thermal detector has a single exhaust vent located facing the corresponding absorbing membrane, preferably plumb with the center of said absorbing membrane.

A device for detecting electromagnetic radiation, including a substrate; at least one thermal detector, placed on the substrate, including an absorbing membrane suspended above the substrate; and an encapsulating structure encapsulating the thermal detector, including an encapsulating layer extending around and above the thermal detector so as to define with the substrate a cavity in which the thermal detector is located; wherein the encapsulating layer includes at least one through-orifice that is what is referred to as an exhaust vent, each exhaust vent being placed so that at least one thermal detector has a single exhaust vent located facing the corresponding absorbing membrane, preferably plumb with the center of said absorbing membrane.

A windowless microbolometer for use in terrestrial applications and non-terrestrial applications is provided. The windowless microbolometer array may interact with a flow of gas such that a pixel-based image of the gas is generated when the flow of gas impinges upon the windowless microbolometer array. The windowless microbolometer array may also interact with a molecular beam to provide information related to density, shape, and propagation of the molecular beam.

A windowless microbolometer for use in terrestrial applications and non-terrestrial applications is provided. The windowless microbolometer array may interact with a flow of gas such that a pixel-based image of the gas is generated when the flow of gas impinges upon the windowless microbolometer array. The windowless microbolometer array may also interact with a molecular beam to provide information related to density, shape, and propagation of the molecular beam.

The present disclosure is a infrared sensor capable of being integrated into a IR focal plane array. It includes of a CMOS based readout circuit with preamplification, noise filtering, and row/column address control. Using either a microbolometer device structure with either a thermal sensing element of vanadium oxide or amorphous silicon, a nanocomposite is fabricated on top of either of these materials comprising aligned or unaligned carbon nanotube films with IR trans missive layer of silicon nitride followed by one to five monolayers of graphene. These layers are connected in series minimizing the noise sources and enhancing the NEDT of each film. The resulting IR sensor is capable of NEDT of less than 1 mK. The wavelength response is from 2 to 12 microns. The approach is low cost using a process that takes advantage of the economies of scale of wafer level CMOS.

A method of manufacturing MEMS housings includes: providing glass spacers; providing a window plate; attaching the window plate to the glass spacers; aligning the glass spacers with a device glass plate having MEMS devices thereon; bonding the glass spacers to the device glass plate; and singulating the glass spacers, window plate, and device glass plate to produce the MEMS housings.

A MEMS device includes a bolometer attached to a silicon wafer by a base portion of at least one anchor structure. The base portion comprises a layer stack having a metal-insulator-metal (MIM) configuration such that the base portion acts as a resistive switch such that, when the first DC voltage is applied to the patterned conductive layer, the base portion transitions from a high resistive state to a low resistive state, and, when the second DC voltage is applied to the patterned conductive layer, the base portion transitions from a high resistive state to a low resistive state.

A MEMS device includes a bolometer attached to a silicon wafer by a base portion of at least one anchor structure. The base portion comprises a layer stack having a metal-insulator-metal (MIM) configuration such that the base portion acts as a resistive switch such that, when the first DC voltage is applied to the patterned conductive layer, the base portion transitions from a high resistive state to a low resistive state, and, when the second DC voltage is applied to the patterned conductive layer, the base portion transitions from a high resistive state to a low resistive state.

The subject matter of this specification can be embodied in, among other things, a photodetector that includes a semiconductor substrate, a semiconductor annulus on a planar face of the semiconductor substrate, and a metal layer on the semiconductor substrate, wherein the metal layer comprises a first region surrounding the semiconductor annulus and comprises a second region filling an interior region to the semiconductor annulus, and the metal layer in the first region forms a Schottky junction with the semiconductor ring.

A cigarette temperature detection device including multiple cylindrical convex lenses is provided, wherein each of the cylindrical convex lenses has a thicker central wall between two thinner end walls formed by rotating a parallel line at a predetermined distance around a long axis of an elliptical-like section resulting from cutting the circular convex lens by a plane perpendicular to a centerline. The disclosed cigarette temperature detection device allows accurate and reliable detection of a temperature of an entire circumferential surface of a cigarette on site.