A plate including functional material to be deposited onto a target surface using monochromatic radiation having a wavelength is described. The plate further includes a substrate with a first surface directed towards the target surface and with a second surface to receive the monochromatic radiation. The first surface is patterned with recessed areas that have a dielectric coating and that are filled with the functional material. The dielectric coating includes a sequence of dielectric coating layers alternating in refractive index. The dielectric coating therewith has a relatively high reflectivity for said monochromatic radiation incident perpendicular to the dielectric coating in comparison to a reflectivity for said monochromatic radiation incident at an angle of 45 degrees to the dielectric coating. As such shear forces are mitigated without requiring a high alignment accuracy. The present application further describes a deposition device including the plate and a method involving the plate.

A detection device includes (a) a LiDAR sensing device and (b) a housing enclosing the LiDAR sensing device, the housing including at least one cover lens. At least a portion of the cover lens is made of at least one glass sheet having an absorption coefficient lower than 5 m.sup.−1 in the wavelength range from 750 to 1650 nm. The cover lens helps to protect the LiDAR sensing device from external degradation.

Provided is laminated glass and a preparation method thereof, an electronic device housing, and an electronic device. The laminated glass comprises at least two glass members and at least one adhesive film disposed in a stacked manner, where the glass members and the adhesive film are alternately disposed, wherein decorative layers are provided on surfaces of at least two of the glass members facing toward the adhesive film, and at least two of the decorative layers independently comprise at least one of an etched texture, an optical coating layer, and a pattern layer.

An antifouling layer-attached glass substrate includes a glass substrate having a pair of main surfaces facing each other, and an antifouling layer formed on or above at least one main surface of the glass substrate. At the time of measuring an absorbance inside the antifouling layer-attached glass substrate by a Fourier transform infrared spectrophotometer according to ATR method (Attenuated Total Reflection) from a surface on a side where the antifouling layer is formed, in the case where an absorbance value at 3,955 cm.sup.−1 is set to 0.10, a value (H.sub.2O absorbance) obtained by subtracting, as a base, the absorbance value at 3,955 cm.sup.−1 from a peak value of an absorbance peak which appears around 3,400 cm.sup.−1 is 0.010 or more.

A method for forming a pressure sensor is provided wherein an optical fibre is provided, the optical fibre comprising a core, a cladding surrounding the core, and a birefringence structure for inducing birefringence in the core. The birefringence structure comprises first and second holes enclosed within the cladding and extending parallel to the core. A portion of the optical fibre comprising the core and the birefringence structure is encased within a chamber, wherein the chamber is defined by a housing comprising a pressure transfer element for equalising pressure between the inside and the outside of the housing. An optical sensor is provided along the core of the optical fibre. Providing the optical sensor comprises optically inducing stress in the core so that the optical sensor exhibits intrinsic birefringence. The chamber is filled with a substantially non-compressible fluid. Consequently, the birefringence structure is shaped so as to convert an external pressure provided by the non-compressible fluid within the chamber to an anisotropic stress in the optical sensor.

A surface-treating agent including a component (A) which is at least one fluoropolyether group-containing compound of formula (1A) or (2A) shown below; a component (B) which is at least one fluoropolyether group-containing compound of the following formula (1B) or (2B) shown below; and a component (C) which is one or more fluorine-containing oils:

Rf.sup.1A.sub.α1—X.sup.A—R.sup.A.sub.β1  (1A)

R.sup.A.sub.γ1—X.sup.A—Rf.sup.2A—X.sup.A—R.sup.A.sub.γ1  (2A)

Rf.sup.1B.sub.α2—X.sup.B—R.sup.B.sub.β2  (1B)

R.sup.B.sub.γ2—X.sup.B—Rf.sup.2B—X.sup.B—R.sup.B.sub.γ2  (2B)

wherein formulas (1A), (2A), (1B and (2B) are as defined herein.

Deadfront articles that include a tactile element formed on a first surface of a substrate and a visual element disposed on a second surface of the substrate opposite the first surface. The tactile element is positioned on the first surface of the substrate in a complimentary fashion to the visual element disposed on the second surface of the substrate. The tactile element may include a surface roughness portion having a surface roughness different than the surface roughness of an area bordering the surface roughness portion. The deadfront articles may be incorporated into an automobile interior to provide a visual and haptic display interface for a user.

This disclosure is directed to an improved process for making glass articles having optical coating and easy-to clean coating thereon, an apparatus for the process and a product made using the process. In particular, the disclosure is directed to a process in which the application of the optical coating and the easy-to-clean coating can be sequentially applied using a single apparatus. Using the combination of the coating apparatus and the substrate carrier described herein results in a glass article having both optical and easy-to-clean coating that have improved scratch resistance durability and optical performance, and in addition the resulting articles are “shadow free.”

The present invention relates to an optically functional absorbing solution composition, infrared absorbing-enhanced glass using same, and an infrared transmitting filter comprising same, the optically functional absorbing solution composition comprising: a resin having a siloxane group substituted at an acrylic group; an organic solvent; and a dye comprising heat resistant dyes and/or non-heat-resistant dyes.

A metal oxide film includes indium, M, (M is Al, Ga, Y, or Sn), and zinc and includes a region where a peak having a diffraction intensity derived from a crystal structure is observed by X-ray diffraction in the direction perpendicular to the film surface. Moreover, a plurality of crystal parts is observed in a transmission electron microscope image in the direction perpendicular to the film surface. The proportion of a region other than the crystal parts is higher than or equal to 20% and lower than or equal to 60%.