A method for bonding infrared transparent materials by placing a polymer comprising at least one chalcogenide element and crosslinking moieties between infrared-transparent optical elements and applying heat, pressure, or both. The crosslinking moieties may be organic, inorganic, or both. Also disclosed is the related bonded assembly comprising infrared transparent optical elements.

Methods of forming ceramic matrix composite structures include joining at least two lamina together to form a flexible ceramic matrix composite structure. Ceramic matrix composite structures include at least one region of reduced inter-laminar bonding at a selected location between lamina thereof. Thermal protection systems include at least one seal comprising a ceramic matrix composite material and have at least one region of reduced inter-laminar bonding at a selected location between lamina used to form the seal. Methods of forming thermal protection systems include providing one or more such seals between adjacent panels of a thermal protection system.

The present disclosure relates to a heating element comprising at least two parts which are composed of different molybdenum disilicide-based compositions, wherein at least one of the molybdenum disilicide-based parts is based on a chromium-alloyed based molybdenum disilicide composition ((Mo.sub.1-xCr.sub.x)Si.sub.2 where x is of from 0.05 to 0.25); and at least one part is based on a molybdenum disilicide-based composition comprising more than or equal to 90 weight % Mo(Si,AI).sub.2. The present disclosure also relates to the use of the heating element.

A bonding device includes an irradiator that irradiates a surface of a first component with ultraviolet rays, and a conveyor that conveys the first component, wherein the irradiator irradiates the first component held by the conveyor with the ultraviolet ray, and the conveyor conveys the first component irradiated with the ultraviolet rays to a surface of a second component, and brings the surface of the first component and the surface of the second component into contact with each other to bond the first component and the second component.

A high-temperature sensor, having at least one completely ceramic heater and at least one first sensor structure arranged on a first side of the completely ceramic heater, at least in areas. And a method for producing a sensor.

A substrate includes a polycrystalline ceramic core; a first adhesion layer encapsulating the polycrystalline ceramic core; a conductive layer encapsulating the first adhesion layer; a second adhesion layer encapsulating the conductive layer; a barrier layer encapsulating the second adhesion layer, and a bonding layer coupled to the barrier layer, and a substantially single crystalline silicon layer coupled to the bonding layer.

A ballistic protective composition having a sintered product of boron carbide and BAM where the sintered product includes up to about 80% BAM by weight based on the weight of the total BAM and boron carbide and wherein the sintered product is configured to prevent penetration of a ballistic threat through the sintered product. The ballistic protective composition may also be bonded to a ballistically protective fabric material to form a ballistic composite, which may be a wearable material, such as a body armor article.

A thermoelectric cloak including an inner region and an external medium. The inner region has a cloaking effect and is simultaneously invisible from both heat and electric charge fluxes; and heat, electric currents, and gradients in the external medium are unaltered by the cloaking effect of the inner region.

The present disclosure relates to a heating element comprising at least two parts which are composed of different molybdenum disilicide-based compositions, wherein at least one of the molybdenum disilicide-based parts is based on a chromium-alloyed based molybdenum disilicide composition ((Mo.sub.1-xCr.sub.x)Si.sub.2 where x is of from 0.05 to 0.25); and at least one part is based on a molybdenum disilicide-based composition comprising more than or equal to 90 weight % Mo(Si,Al).sub.2. The present disclosure also relates to the use of the heating element.

The present invention relates to a method of forming a 3D ceramic structure by adding a 3D structure with one or more layer(s) of ceramic mixture onto a ceramic substrate. The present invention also relates to a 3D ceramic structure as well as to a green 3D ceramic structure.