A stain disappearing laminate of the present invention comprises a sebum absorption and diffusion layer 3 and a sebum attachment inhibition layer 2 laminated on a base material in this order. The sebum attachment inhibition layer 2 repels sebum 5 and reduces attachment of the sebum, as well as allows attached sebum to pass through to the sebum attachment inhibition layer side, and the sebum absorption and diffusion layer 3 absorbs the sebum 5 passed through the sebum attachment inhibition layer 2 and diffuses the sebum within the sebum absorption and diffusion layer itself.

The present disclosure describes spill retention mechanisms for cooktops and other substrates. The spill retention mechanisms can hinder the movement of liquids primarily due to the physical attributes of the mechanisms, unlike hydrophobic mechanisms which hinder movement primarily due to the chemical attributes of the hydrophobic material.

The present invention relates to an article comprising a substrate at least partially coated with a composition comprising solid in the form of aggregate and (per) fluoropolyether polymer. The invented article shows excellent performance on amphiphobicity and transparency.

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.

Embodiments of a deadfront article are provided. The deadfront article includes a substrate having a first surface and a second surface. The deadfront article also includes a semi-transparent layer disposed onto the second surface of the substrate. The semi-transparent layer has a region of a solid color or of a design of two or more colors, and the semi-transparent layer has a first optical density. Further, the deadfront article includes a contrast layer disposed onto the region. The contrast layer is configured to enhance visibility of the color(s) of the semi-transparent layer.

A method includes depositing a surface modification layer on sidewalls of a plurality of cavities of a shaped article. The surface modification layer is formed from a glass material including a mobile component. The shaped article is formed from a glass material, a glass ceramic material, or a combination thereof. At least a portion of the mobile component is migrated from the surface modification layer into surface regions of the sidewalls of the shaped article, whereby subsequent to the migration, the surface regions have a reduced annealing point compared to a bulk of the shaped article. The surface modification layer and the surface regions of the sidewalls are reflowed. A surface roughness of the surface modification layer disposed on the sidewalls following the reflowing is less than a surface roughness of the sidewalls prior to the depositing.

A glass-ceramic plate for a cooking device includes a first main face to be in contact with liquids, a second main face and an edge, a liquid-retaining bead fastened to and in contact with the first main face, wherein the retaining bead surrounds a region of the first main face so as to form a liquid-retaining reservoir, and includes at least two hydrophobic sub-beads inscribed within one another and separated by hydrophilic zones, a width of the hydrophilic zone between two consecutive sub-beads is throughout at least greater than 500 m and less than a threshold value, the threshold value being defined so that, when a liquid is present in the hydrophilic zone, a variation in the retention time or volume of the liquid before overflowing, relative to a same liquid present in a hydrophilic zone, the width of which is greater than the value, is less than 5%.

Proposed are: a wavelength conversion member having an excellent aesthetic appearance when not irradiated with excitation light and having an excellent luminescence intensity; and a light emitting device using the wavelength conversion member. A wavelength conversion member 10 includes: a first wavelength conversion layer 1 containing a phosphor; and a second wavelength conversion layer 2 formed on a surface of the first wavelength conversion layer 1 and containing phosphor nanoparticles 2a.

The present invention relates to a process for producing a coated glass substrate, the process comprising providing a glass substrate having at least one surface, the surface having deposited thereon a layer of a transparent conductive material, providing a coating composition comprising a polysilazane, contacting the surface of the transparent conductive material with the coating composition and curing the coating composition to form a coating layer on the surface of the transparent conductive material the coating layer comprising silica, and to architectural and automotive glazing comprising coated glass substrates obtained using the process.

The present invention addresses the problem of providing a transparent product which has an anti-glare surface having a surface shape which makes it possible to lower the haze value thereof and to obtain an excellent glare-suppressing effect. The transparent product has a transparent substrate 11 equipped with an anti-glare surface. The surface shape of the anti-glare surface is shaped in a manner such that the ratio (r.sub.0/r.sub.0.2) of the autocorrelation length (r.sub.0), which is the minimum value of the distance r at which the autocorrelation function g(r) represented by formula (1) is 0, to the autocorrelation length (r.sub.0.2), which is the minimum value of the distance r at which the autocorrelation function g(r) is 0.2, is 2 or higher. The autocorrelation function g(r) is obtained by converting the autocorrelation function g(t.sub.x, t.sub.y) obtained by normalizing the surface shape z(x, y) of the antiglare surface to polar coordinates (t.sub.x=r cos , t.sub.y=r sin ), and averaging the angle direction.

[00001]$\begin{array}{cc}g\left(r\right)=\frac{1}{2.Math..Math.}.Math.{}_0^{2.Math..Math.}.Math.d.Math..Math..Math..Math.g\left(r.Math..Math.\cos .Math..Math.,r.Math..Math.\sin .Math..Math.\right)& \left(1\right)\end{array}$