A glass container has an outer glass surface with an inkjet printed image provided on the surface. A cold-end coating (CEC) with a thickness between 0 to 20 nm is present between the outer glass surface and the inkjet printed image. Such glass container is preferably a one-way beverage bottle. A method of inkjet printing an image on a glass container comprises the steps of (a) manufacturing a glass container having a CEC layer; (b) removing at least part of the CEC layer to a level wherein the remaining CEC layer has a thickness of 0 to 20 nm; and (c) inkjet printing an image on the glass container.

A glass container has an outer glass surface with an inkjet printed image provided on the surface. A cold-end coating (CEC) with a thickness between 0 to 20 nm is present between the outer glass surface and the inkjet printed image. Such glass container is preferably a one-way beverage bottle. A method of inkjet printing an image on a glass container comprises the steps of (a) manufacturing a glass container having a CEC layer; (b) removing at least part of the CEC layer to a level wherein the remaining CEC layer has a thickness of 0 to 20 nm; and (c) inkjet printing an image on the glass container.

The present disclosure relates to a mixture that includes a perovskite precursor, a solvent, and an additive that includes at least one of a first amine, a ketone, an aldehyde, a non-nucleophilic sterically hindered base, and/or a halogen-containing compound, where, upon removal of the solvent and the additive, the perovskite precursor is capable of being transformed into a perovskite.

Provided is a top plate for a cooking device capable of making the indication in a displaying region clearly visible during turn-on of a display and, during turn-off of the display, capable of making the boundary between the displaying region and a non-displaying region less visible while hiding the internal structure of the cooking device. A top plate 1 for a cooking device including a displaying region A capable of showing information given from a display 32 and a non-displaying region B blocking visible light includes: a glass substrate 2 having a cooking surface 2a on which a utensil is to be put and an underside surface 2b opposite to the cooking surface 2a; a dielectric multi-layer 3 provided on the underside surface 2b of the glass substrate 2; a light transmissive layer 6 provided on a portion of the dielectric multi-layer 3 overlapped with the displaying region A and containing a transparent material; and a light blocking layer 7 provided on a portion of the dielectric multi-layer 3 overlapped with the non-displaying region B, wherein the top plate 1 has a reflectance in a range of 20% to 80%, and an absolute value of a difference in refractive index between the light transmissive layer 6 and the light blocking layer 7 is 0.1 or less.

Provided is a top plate for a cooking device capable of making the indication in a displaying region clearly visible during turn-on of a display and, during turn-off of the display, capable of making the boundary between the displaying region and a non-displaying region less visible while hiding the internal structure of the cooking device. A top plate 1 for a cooking device including a displaying region A capable of showing information given from a display 32 and a non-displaying region B blocking visible light includes: a glass substrate 2 having a cooking surface 2a on which a utensil is to be put and an underside surface 2b opposite to the cooking surface 2a; a dielectric multi-layer 3 provided on the underside surface 2b of the glass substrate 2; a light transmissive layer 6 provided on a portion of the dielectric multi-layer 3 overlapped with the displaying region A and containing a transparent material; and a light blocking layer 7 provided on a portion of the dielectric multi-layer 3 overlapped with the non-displaying region B, wherein the top plate 1 has a reflectance in a range of 20% to 80%, and an absolute value of a difference in refractive index between the light transmissive layer 6 and the light blocking layer 7 is 0.1 or less.

Glass for a vehicle includes a glass plate; a test-region A demarcated in the glass plate, the test-region A being specified in JIS R3212; a shielding layer provided more outwardly than the test-region A in a plan view; an information transmission/reception region demarcated within an opening portion provided in the shielding layer, and through which a device mounted in the vehicle transmits/receives information; and an infrared reflective layer positioned peripheral to the information transmission/reception region in a plan view, the infrared reflective layer having a portion that overlaps with the shielding layer in a plan view, wherein a solar direct transmittance of the test-region A is 60% or less and a solar direct reflectance of a region in which the infrared reflective layer is provided peripheral to the information transmission/reception region is greater than a solar direct reflectance of the test-region A by at least 5%.

Glass for a vehicle includes a glass plate; a test-region A demarcated in the glass plate, the test-region A being specified in JIS R3212; a shielding layer provided more outwardly than the test-region A in a plan view; an information transmission/reception region demarcated within an opening portion provided in the shielding layer, and through which a device mounted in the vehicle transmits/receives information; and an infrared reflective layer positioned peripheral to the information transmission/reception region in a plan view, the infrared reflective layer having a portion that overlaps with the shielding layer in a plan view, wherein a solar direct transmittance of the test-region A is 60% or less and a solar direct reflectance of a region in which the infrared reflective layer is provided peripheral to the information transmission/reception region is greater than a solar direct reflectance of the test-region A by at least 5%.

A process for obtaining a material including a substrate coated on one of its sides with a coating including a functional layer, includes depositing the functional layer on the substrate, then depositing an absorbent layer on top of the functional layer, then performing a heat treatment by radiation, the radiation having at least one treatment wavelength between 200 and 2500 nm, the absorbent layer being in contact with air during the heat treatment, wherein the ab sorb ent layer ab sorbs at least 80% of the radiation used during the heat treatment and transmits less than 10% thereof.

A solar control film with improved moisture resistance function is provided. The solar control film includes a flexible substrate, at least one infrared-reflective composite layer and an outer dielectric layer. The infrared-reflective composite layer includes a dielectric sublayer and a metal sublayer. The dielectric sublayer is disposed on the flexible substrate, and the material of the dielectric sublayer includes TiO.sub.2. The metal sublayer is disposed on the dielectric sublayer, and includes 8.3-16.4 atomic % Ag, 0.5-1.0 atomic % Ti, 81.0-90.9 atomic % N, and 0.3-0.6 atomic % noble metal, and the noble metal is Au, Pd or any combinations thereof. The outer dielectric layer is disposed on the infrared-reflective composite layer, and the material of the outer dielectric layer includes TiO.sub.2. In this way, the provided solar control film can effectively suppress of forming white spots without significantly sacrificing its original function and characteristics.

A solar control film with improved moisture resistance function is provided. The solar control film includes a flexible substrate, at least one infrared-reflective composite layer and an outer dielectric layer. The infrared-reflective composite layer includes a dielectric sublayer and a metal sublayer. The dielectric sublayer is disposed on the flexible substrate, and the material of the dielectric sublayer includes TiO.sub.2. The metal sublayer is disposed on the dielectric sublayer, and includes 8.3-16.4 atomic % Ag, 0.5-1.0 atomic % Ti, 81.0-90.9 atomic % N, and 0.3-0.6 atomic % noble metal, and the noble metal is Au, Pd or any combinations thereof. The outer dielectric layer is disposed on the infrared-reflective composite layer, and the material of the outer dielectric layer includes TiO.sub.2. In this way, the provided solar control film can effectively suppress of forming white spots without significantly sacrificing its original function and characteristics.