A method includes depositing a glass frit on sidewalls of a plurality of cavities of a shaped article formed from a glass material, a glass ceramic material, or a combination thereof. The glass frit is heated to a firing temperature above a glass transition temperature of the glass frit to sinter the glass frit into a glaze disposed on the sidewalls of the plurality of cavities.

Transparent conductive coatings are polished using particle slurries in combination with mechanical shearing force, such as a polishing pad. Substrates having transparent conductive coatings that are too rough and/or have too much haze, such that the substrate would not produce a suitable optical device, are polished using methods described herein. The substrate may be tempered prior to, or after, polishing. The polished substrates have low haze and sufficient smoothness to make high-quality optical devices.

A cover glass includes: a glass substrate having a convex and concave shape formed on at least one of surfaces thereof by an antiglare treatment; and an antireflection film disposed on the surface of the glass substrate, the surface having the convex and concave shape. In the cover glass, a difference Δa* in a* value between any two points within a surface of the cover glass on the side where the antireflection film is present and a difference Δb* in b*value between any two points within the surface of the cover glass on the side where the antireflection film is present satisfy the following expression: √{(Δa*).sup.2+(Δb*).sup.2}≤4.

A glass composite includes a first glass member and a second glass member. The first glass member and the second glass member are at least partially connected with each other at the surfaces. The glass composite has a light transmittance not lower than 95% of the light transmittance of the one, with the lower light transmittance, of the first glass member and the second glass member.

This disclosure discloses a camera hole cover plate, including: a cover plate body, where the cover plate body includes a transparent area for covering a display screen, and a cover plate edge, where the cover plate edge and the cover plate body are an integral structure, the cover plate edge is around the cover plate body, and the area of the cover plate edge located on the outside of the transparent area comprises a frosted area.

A glass composite includes a first glass member and a second glass member. The first glass member and the second glass member are at least partially connected with each other at the surfaces, and a contact interface is formed on the contacting position of the first glass member and the second glass member. The contact interface is visually observed to have no crevices; and when the glass composite is in contact with an acid solution, crevices are suitably formed in the glass composite at the contact interface.

A coated glass substrate is disclosed. The coated glass substrate includes a coating containing at least one metal oxide containing a zinc oxide. The zinc of the zinc oxide is present in an amount of from 5 wt. % to 50 wt. % as determined according to XPS. The coated glass substrate has area surface roughness Sa or Sq of from about 5 nm to about 1,500 nm as determined via atomic force microscopy.

A method for processing of glass containers includes: simultaneously subjecting the glass containers to a first processing step; and simultaneously subjecting the glass containers to a second processing step after the first processing step. At least one of before or during at least one of the first processing step or the second processing step an outer container surface of each glass container is contact-free or in contact with a material having a lower hardness than that of the glass container or only in contact with such materials.

In one example, a method to manufacture a magnetic sensor, comprises providing an electrolyte solution, submersing a substrate in the electrolyte solution, submersing a plurality of ingots in the electrolyte solution, wherein the ingots comprises a metal that is magnetic, and depositing the metal on the substrate by applying a voltage between the metal ingot and the substrate to result in magnetic alloy layer on the substrate. Other examples and related methods are also disclosed herein.

A vehicular frameless interior rearview mirror assembly includes a mirror head and a mounting portion. The mirror head includes a mirror reflective element and a mirror casing. The mirror reflective element includes a glass substrate having a planar front side and a planar rear side. No portion of the mirror casing overlaps the planar front side of the glass substrate of the mirror reflective element. A camera is disposed within the mirror casing. With the mounting portion of the mirror assembly mounted at an in-cabin side of a windshield of a vehicle, the camera views a driver of the vehicle, and when the mirror head is moved by the driver of the vehicle to adjust the rearward view provided by the mirror reflective element to the driver, the camera moves in tandem with movement of the mirror head. The camera is part of a driver monitoring system of the vehicle.