Abstract: Disclosed are a metal mesh touch screen and a method for manufacturing a metal mesh touch screen. The metal mesh touch screen includes the first functional electrode layer, a first adhesive layer, a second functional electrode layer and a second adhesive layer placed sequentially. The first functional electrode layer includes the first metal mesh wiring extending in a first direction and a metal material for preparing the first metal mesh wiring is a metal foil with a first rough surface and a second rough surface. The second functional electrode layer includes a second metal mesh wiring extending in a second direction and a metal material for preparing the second metal mesh wiring is the metal foil with the first rough surface and the second rough surface.

Abstract: Disclosed are a metal mesh structure for a capacitive touch screen, a touch display device and a mobile terminal. The metal mesh structure includes: a first metal mesh layer, a first coating layer, a first optical adhesive layer, a second metal mesh layer and a second coating layer which are arranged in sequence. The first coating layer is coated on the first metal mesh layer, a thickness of the first coating layer is smaller than that of the first metal mesh layer, the second coating layer is coated on the second metal mesh layer, and a thickness of the second coating layer is smaller than that of the second metal mesh layer.

Abstract: Disclosed is a foldable touch screen electrode structure, including: a glass substrate including a first sidewall and a second sidewall opposite to each other in a thickness direction of the glass substrate, each of the first sidewall and the second sidewall being provided with an oxide layer; at least two upper adhesive layers and at least two lower adhesive layers; an upper metal grid layer adhered to the first sidewall through the at least two upper adhesive layers; a lower metal grid layer adhered to the second sidewall through the at least two lower adhesive layers; and an upper surface layer connected to an upper metal grid layer, and a lower surface layer connected to a lower metal grid layer; each of the upper surface layer and the lower surface layer includes a rough layer and a low reflection layer which are sequentially stacked.

Abstract: Disclosed are a metal mesh touch screen and a method for manufacturing a metal mesh touch screen. The metal mesh touch screen includes the first functional electrode layer, a first adhesive layer, a second functional electrode layer and a second adhesive layer placed sequentially. The first functional electrode layer includes the first metal mesh wiring extending in a first direction and a metal material for preparing the first metal mesh wiring is a metal foil with a first rough surface and a second rough surface. The second functional electrode layer includes a second metal mesh wiring extending in a second direction and a metal material for preparing the second metal mesh wiring is the metal foil with the first rough surface and the second rough surface.

Abstract: Disclosed are an electrothermal film structure, an electrothermal film heating device and a method for manufacturing an electrothermal film. The electrothermal film structure includes a supporting layer, a meshed conductive circuit layer and a transparent optical layer. The meshed conductive circuit layer provided on the supporting layer includes several micron-level conductive circuits distributed in a mesh, and the transparent optical layer is provided on the meshed conductive circuit layer.

Abstract: Disclosed is an electrochromic material. The electrochromic material includes: a low eutectic solvent, and a color-changing material which includes a hydrogen bond donor material and a hydrogen bond acceptor material. The electrochromic material also includes an aerogel.

Abstract: Disclosed are a metal mesh structure for a capacitive touch screen, a touch display device and a mobile terminal. The metal mesh structure includes: a first metal mesh layer, a first coating layer, a first optical adhesive layer, a second metal mesh layer and a second coating layer which are arranged in sequence. The first coating layer is coated on the first metal mesh layer, a thickness of the first coating layer is smaller than that of the first metal mesh layer, the second coating layer is coated on the second metal mesh layer, and a thickness of the second coating layer is smaller than that of the second metal mesh layer.

Abstract: Disclosed are a method for manufacturing a metal sensing electrode structure, a touch display device and a mobile terminal. The method for manufacturing a metal sensing electrode structure for a capacitive touch screen includes: coating a protective material on a first surface of a first metal foil layer to obtain a first coating layer, wherein a thickness of the first metal foil layer is greater than that of the first coating layer; connecting a surface of the first coating layer opposite to the first metal foil layer with a first optical adhesive layer; and performing a photolithography process on a second surface of the first metal foil layer to obtain a first metal sensing electrode structure.

Abstract: Disclosed is a foldable touch screen electrode structure, including: a glass substrate including a first sidewall and a second sidewall opposite to each other in a thickness direction of the glass substrate, each of the first sidewall and the second sidewall being provided with an oxide layer; at least two upper adhesive layers and at least two lower adhesive layers; an upper metal grid layer adhered to the first sidewall through the at least two upper adhesive layers; a lower metal grid layer adhered to the second sidewall through the at least two lower adhesive layers; and an upper surface layer connected to an upper metal grid layer, and a lower surface layer connected to a lower metal grid layer; each of the upper surface layer and the lower surface layer includes a rough layer and a low reflection layer which are sequentially stacked.