Display device includes a display panel. The display panel includes a first substrate, a sealant, and, a second substrate fastended to the first substrate via the sealant. At least one of the first substrate and the second substrate is a non-planar substrate including at least two portions correspondingly extending in different planes.

Display device includes a display panel. The display panel includes a first substrate, a sealant, and, a second substrate fastended to the first substrate via the sealant. At least one of the first substrate and the second substrate is a non-planar substrate including at least two portions correspondingly extending in different planes.

The present disclosure provides a flexible backlight, a method for manufacturing the same, and a display device. The flexible backlight includes: a first flexible substrate and a second flexible substrate arranged opposite to each other; a plurality of spacers arranged between the first flexible substrate and the second flexible substrate, for supporting a spacing between the first flexible substrate and the second flexible substrate, and for forming an accommodating chamber between the first flexible substrate and the second flexible substrate; a first electrode and a second electrode for forming an electric field; a gas contained in the accommodating chamber, in which the gas is capable of emitting a non-visible light by the action of the electric field; and a photoexcitation layer arranged on the second flexible substrate, in which the photoexcitation layer can emit a visible light under illumination of the non-visible light and is in contact with the spacer.

The invention relates to a plasma screen that fits different shapes and measurements, which is foldable, pliable and impermeable, with self-adhesive material for placing on any surface. The device is small, slim, autonomous (does not need to be connected to electricity), pliable, foldable (can be folded), impermeable (resistant to water and inclement weather), easy to stick on any surface and very low cost. The device is interactive and comprises a user terminal (1) that brings together all the parts of the device, the terminal taking the form of different-shaped plastic stickers and containing a foldable plasma screen (2) that covers the circumference of same and transmits images and video. All the parts of the device are connected, by means of small cables (9), to an integrated microcomputer (3) with a processor that contains a computer program, a formula and algorithms that allow information processing and transmission and GPS location. The microcomputer is connected, by means of cables (9), to a wireless modem (4) that allows communication with other mobile devices, and is also connected, by means of cables (9), to a self-recharging battery (5) that powers the device. The microcomputer is connected, by means of cables (9), to solar cells (6) that power the battery (5), without the need for connecting to electricity, making the device autonomous. The front part of the sticker is covered by a transparent plastic fabric (7) that protects the device against rain, grease and other substances and is glued to the monitor (2) covering the circumference and shape of the sticker. The rear part of the sticker is covered by a plastic fabric (8) with self-adhesive material, which can be hung, glued or placed on different surfaces, the fabric being glued to the device.

The present disclosure provides a flexible backlight, a method for manufacturing the same, and a display device. The flexible backlight includes: a first flexible substrate and a second flexible substrate arranged opposite to each other; a plurality of spacers arranged between the first flexible substrate and the second flexible substrate, for supporting a spacing between the first flexible substrate and the second flexible substrate, and for forming an accommodating chamber between the first flexible substrate and the second flexible substrate; a first electrode and a second electrode for forming an electric field; a gas contained in the accommodating chamber, in which the gas is capable of emitting a non-visible light by the action of the electric field; and a photoexcitation layer arranged on the second flexible substrate, in which the photoexcitation layer can emit a visible light under illumination of the non-visible light and is in contact with the spacer.

A substrate processing apparatus includes a base member having an opening, a substrate holding member fixedly provided on the base member and configured to hold a plurality of substrates in multiple stages in a vertical direction, a plurality of shower plates provided to respectively face the substrates held by the substrate holding member and configured to supply a processing gas to the substrates existing thereunder in a shower shape, at least one gas introduction member configured to introduce the processing gas into the shower plates, a processing container provided to be able to make close contact with the base member and brought into close contact with the base member to define an arrangement space of the substrate holding member as a processing chamber, a heating device configured to heat the substrates in the processing chamber, and an exhaust mechanism configured to evacuate the processing chamber through the opening.

A substrate processing apparatus includes a base member having an opening, a substrate holding member fixedly provided on the base member and configured to hold a plurality of substrates in multiple stages in a vertical direction, a plurality of shower plates provided to respectively face the substrates held by the substrate holding member and configured to supply a processing gas to the substrates existing thereunder in a shower shape, at least one gas introduction member configured to introduce the processing gas into the shower plates, a processing container provided to be able to make close contact with the base member and brought into close contact with the base member to define an arrangement space of the substrate holding member as a processing chamber, a heating device configured to heat the substrates in the processing chamber, and an exhaust mechanism configured to evacuate the processing chamber through the opening.

A wafer placement table includes a ceramic substrate having a wafer placement surface on an upper surface thereof and containing an electrode therein; a conductive substrate disposed adjacent to a lower surface of the ceramic substrate, serving also as a plasma generating electrode, and having the same diameter as the ceramic substrate; a support substrate disposed adjacent to a lower surface of the conductive substrate, having a greater diameter than the conductive substrate, and electrically insulated from the conductive substrate; and a mounting flange constituting a part of the support substrate and radially extending out of the conductive substrate.

A gas reactor device includes a plurality of microcavities or microchannels defined at least partially within a thick metal oxide layer consisting essentially of defect free oxide. Electrodes are arranged with respect to the microcavities or microchannels to stimulate plasma generation therein upon application of suitable voltage. One or more or all of the electrodes are encapsulated within the thick metal oxide layer. A gas inlet is configured to receive feedstock gas into the plurality of microcavities or microchannels. An outlet is configured to outlet reactor product from the plurality of microcavities or microchannels. In an example preferred device, the feedstock gas is air or O.sub.2 and is converted by the plasma into ozone (O.sub.3). In another preferred device, the feedstock gas is an unwanted gas to be decomposed into a desired form. Gas reactor devices of the invention can, for example, decompose gases such as CO.sub.2, CH.sub.4, or NO.sub.x.

A gas reactor device includes a plurality of microcavities or microchannels defined at least partially within a thick metal oxide layer consisting essentially of defect free oxide. Electrodes are arranged with respect to the microcavities or microchannels to stimulate plasma generation therein upon application of suitable voltage. One or more or all of the electrodes are encapsulated within the thick metal oxide layer. A gas inlet is configured to receive feedstock gas into the plurality of microcavities or microchannels. An outlet is configured to outlet reactor product from the plurality of microcavities or microchannels. In an example preferred device, the feedstock gas is air or O.sub.2 and is converted by the plasma into ozone (O.sub.3). In another preferred device, the feedstock gas is an unwanted gas to be decomposed into a desired form. Gas reactor devices of the invention can, for example, decompose gases such as CO.sub.2, CH.sub.4, or NO.sub.x.