Disclosed are a coating for glass molding, a preparation method and application thereof and a mold having the coating. The coating includes a nitride layer and nano precious metal particles which are dispersed in the nitride layer. A surface roughness of the coating is 2-12 nm. The preparation method of the coating includes: cleaning a substrate and targets under an inert gas; and under a mixed atmosphere of nitrogen and the inert gas, depositing, with a high-purity W target, a high-purity Cr target and a precious metal inserted Cr target, a Cr intermediate layer, a nitride layer and nano precious metal particles on a surface of the substrate. The coating has good oxidation resistance and excellent anti-adhesion property. Moreover, the coating effectively inhibits the adhesion between the glass body and the mold.

Disclosed are a coating for glass molding, a preparation method and application thereof and a mold having the coating. The coating includes a nitride layer and nano precious metal particles which are dispersed in the nitride layer. A surface roughness of the coating is 2-12 nm. The preparation method of the coating includes: cleaning a substrate and targets under an inert gas; and under a mixed atmosphere of nitrogen and the inert gas, depositing, with a high-purity W target, a high-purity Cr target and a precious metal inserted Cr target, a Cr intermediate layer, a nitride layer and nano precious metal particles on a surface of the substrate. The coating has good oxidation resistance and excellent anti-adhesion property. Moreover, the coating effectively inhibits the adhesion between the glass body and the mold.

Described are glass-forming molds made of a graphite mold body and a coating formed by atomic layer deposition, with the coating being made of alumina or a combination of alumina and yttria.

Disclosed is a mold for processing glass. The mold includes a concave mold having a cavity and a convex mold mating with the concave mold. When the molds are clamped, the convex mold protrudes into the cavity. The mold further includes a base, wherein the base is detachably fixed on a side of the convex mold distal from the cavity, and a material of the base is different from that of the concave or the convex mold fixed thereto. The mold according to the present disclosure may improve manufacture efficiency of three-dimensional glass substrates and has a prolonged life time.

Precision glass molds are described, which are formed by coating a mold made from high purity, fme grain sized graphite, with a coating including titanium. In various implementations, the titanium coating is overcoated with yttria (Y.sub.2O.sub.3) to provide a high precision glass mold of superior performance character. The resultant glass molds can be used to form glass articles having a highly smooth finish, for high precision applications such as consumer electronic device applications, medical instruments, and optical devices. The use of high purity, fme grain size graphite allows molds to be machined at low cost, thereby eliminating the need to fabricate a metal mold that must be coated with multiple layers including metal diffusion barrier layers to meet operational requirements for such precision applications.

Described are glass-forming molds made of a graphite mold body and a coating formed by atomic layer deposition, with the coating being made of alumina or a combination of alumina and yttria.

Precision glass molds are described, which are formed by coating a mold made from high purity, fine grain sized graphite, with a coating including titanium. In various implementations, the titanium coating is overcoated with yttria (Y.sub.2O.sub.3) to provide a high precision glass mold of superior performance character. The resultant glass molds can be used to form glass articles having a highly smooth finish, for high precision applications such as consumer electronic device applications, medical instruments, and optical devices. The use of high purity, fine grain size graphite allows molds to be machined at low cost, thereby eliminating the need to fabricate a metal mold that must be coated with multiple layers including metal diffusion barrier layers to meet operational requirements for such precision applications.

The present invention relates to a silicon mold device for production of an optical element in a high temperature environment and a preparation method thereof. The silicon mold device utilized in this invention features a symmetrical structure, ensuring uniform deformation during heating to mitigate eccentricity issues. Additionally, a stepped silicon mold core is employed and secured by applying force through an electrode pressure plate, thereby enhancing overall parallelism. Support columns assist in the closure and alignment of the upper and lower molds. Each support column can be individually adjusted for parallelism, facilitating the enhancement of precision and reliability in the preparation of optical elements.

A mold has a molding surface for hot molding of a body to be molded. The mold includes a glass having a porosity of 0.01% or more and containing 95 mol % or more of SiO.sub.2. A molding apparatus includes the mold. A method for producing a bent glass includes a placing step and a molding step. In the placing step, a glass to be molded is placed on a mold including a glass having a porosity of 0.01% or more. In the molding step, the glass to be molded which has been placed on the mold is heated, and then, the glass is caused to be molded to follow a molding surface of the mold.

Disclosed is a method of preparing a solid electrolyte composition for a lithium secondary battery which includes: (a) mixing materials including Li.sub.2O, SiO.sub.2, TiO.sub.2, P.sub.2O.sub.5, BaO, Cs.sub.2O and V.sub.2O.sub.5; (b) melting the mixed materials; (c) rapidly cooling the molten materials at room temperature and compressing the molten materials using a preheated plate to form electrolyte glass having a predetermined thickness; (d) heating the electrolyte glass to eliminate stress at a predetermined temperature range; (e) heating the electrolyte glass to a higher temperature range higher than in the step of heating the electrolyte glass to eliminate stress to be crystallized; and (f) precisely adjusting a thickness of the electrolyte glass by lapping the electrolyte glass.