Abstract: A cutting method of a multilayer structure containing a brittle layer is provided. The cutting method includes: cutting the multilayer structure to form a cut edge; removing a material of the multilayer structure other than the brittle layer along the cut edge, wherein the material of the multilayer structure other than the brittle layer has a width ranging from 1 micron to 2 millimeter; and modifying an edge of the brittle layer remaining after removing the material of the multilayer structure other than the brittle layer by a laser beam.

Abstract: A method for fabricating an organic electro-luminescence device, comprising: forming a first conductive layer comprising a first electrode and a contact pattern on a substrate; forming a first mask on the first conductive layer, the first mask comprising an opening for exposing a portion of the first electrode and a portion of the contact pattern; forming a patterned organic functional layer by shielding of a second mask, the patterned organic functional layer covering the first mask and the first electrode exposed by the first mask, and the second mask being disposed over the first mask to shield the portion of the contact pattern exposed by the opening; forming a second conductive layer and patterning the second conductive layer by removing the first mask and a portion of the second conductive layer on the first mask to form a second electrode electrically connected to the contact pattern.

Abstract: A method for fabricating an organic electro-luminescence device, including: on a substrate, forming a first conductive layer including a first electrode and a first contact pattern electrically insulated therefrom; on the first conductive layer, forming a first mask including a release film, a base film disposed between the release film and the first conductive layer and an opening for partially exposing the first electrode and the first contact pattern; by shielding of a second mask, forming a patterned organic functional layer partially covering the first mask and the first electrode exposed by the first mask; removing the second mask; forming a second conductive layer over the structure aforesaid; and patterning the second conductive layer by removing the release film and the second conductive layer formed thereon to form a second electrode electrically connected to the first contact pattern and a second contact pattern electrically connected to the first electrode.

Abstract: A method for fabricating an organic electro-luminescence device, comprising: forming a first conductive layer comprising a first electrode and a contact pattern on a substrate; foil ling a first mask on the first conductive layer, the first mask comprising an opening for exposing a portion of the first electrode and a portion of the contact pattern; forming a patterned organic functional layer by shielding of a second mask, the patterned organic functional layer covering the first mask and the first electrode exposed by the first mask, and the second mask being disposed over the first mask to shield the portion of the contact pattern exposed by the opening; forming a second conductive layer and patterning the second conductive layer by removing the first mask and a portion of the second conductive layer on the first mask to form a second electrode electrically connected to the contact pattern.

Abstract: A touch panel and a manufacturing method thereof and a touch display panel are provided. The touch panel includes a substrate, at least one first conductive line, an insulating layer, and at least one second conductive line. The substrate has a sensing region and a periphery region. The first conductive line is disposed on the periphery region. The insulating layer is disposed on the periphery region and covers the first conductive line. The second conductive line is disposed on the periphery region. The first conductive line and the second conductive line are electrically insulated to each other. A portion of at least one second conductive line is disposed on the insulating layer located above the first conductive line.

Abstract: A method for fabricating an organic electro-luminescence device, comprising: forming a first conductive layer comprising a first electrode and a contact pattern on a substrate; forming a first mask on the first conductive layer, the first mask comprising an opening for exposing a portion of the first electrode and a portion of the contact pattern; forming a patterned organic functional layer by shielding of a second mask, the patterned organic functional layer covering the first mask and the first electrode exposed by the first mask, and the second mask being disposed over the first mask to shield the portion of the contact pattern exposed by the opening; forming a second conductive layer and patterning the second conductive layer by removing the first mask and a portion of the second conductive layer on the first mask to form a second electrode electrically connected to the contact pattern.

Abstract: A method for fabricating an organic electro-luminescence device, comprising: forming a first conductive layer comprising a first electrode and a contact pattern on a substrate; foil ling a first mask on the first conductive layer, the first mask comprising an opening for exposing a portion of the first electrode and a portion of the contact pattern; forming a patterned organic functional layer by shielding of a second mask, the patterned organic functional layer covering the first mask and the first electrode exposed by the first mask, and the second mask being disposed over the first mask to shield the portion of the contact pattern exposed by the opening; forming a second conductive layer and patterning the second conductive layer by removing the first mask and a portion of the second conductive layer on the first mask to form a second electrode electrically connected to the contact pattern.

Abstract: A method for fabricating an organic electro-luminescence device, including: on a substrate, forming a first conductive layer including a first electrode and a first contact pattern electrically insulated therefrom; on the first conductive layer, forming a first mask including a release film, a base film disposed between the release film and the first conductive layer and an opening for partially exposing the first electrode and the first contact pattern; by shielding of a second mask, forming a patterned organic functional layer partially covering the first mask and the first electrode exposed by the first mask; removing the second mask; forming a second conductive layer over the structure aforesaid; and patterning the second conductive layer by removing the release film and the second conductive layer formed thereon to form a second electrode electrically connected to the first contact pattern and a second contact pattern electrically connected to the first electrode.

Abstract: A cutting method of a multilayer structure containing a brittle layer is provided. The cutting method includes: cutting the multilayer structure to form a cut edge; removing a material of the multilayer structure other than the brittle layer along the cut edge, wherein the material of the multilayer structure other than the brittle layer has a width ranging from 1 micron to 2 millimeter; and modifying an edge of the brittle layer remaining after removing the material of the multilayer structure other than the brittle layer by a laser beam.

Abstract: An interleaving element is adapted to interleave a roll of glass substrate. The glass substrate includes at least one active area, a plurality of spacing zones and two edge zones. The plurality of spacing zones and the edge zones define the active area. The interleaving element includes two elongated side elements and a plurality of bridging elements. The elongated side elements correspond to the two edge zones. Each of the plurality of bridging elements is connected with the elongated side elements. The plurality of bridging elements corresponds to the spacing zones.

Abstract: A laser patterning touch panel includes an active area, an inactive area, and a plurality of first coaxial patterns. The active area is disposed in a center area of the substrate. The inactive area does not overlap the active area and has a transparent conductive layer thereon. The plurality of first coaxial patterns are disposed on the transparent conductive layer and surround the active area. Each of the plurality of first coaxial patterns includes a continuous line segment with a width, and partially overlaps with a neighboring one of the first coaxial patterns.

Abstract: An interleaving element is adapted to interleave a roll of glass substrate. The glass substrate includes at least one active area, a plurality of spacing zones and two edge zones. The plurality of spacing zones and the edge zones define the active area. The interleaving element includes two elongated side elements and a plurality of bridging elements. The elongated side elements correspond to the two edge zones. Each of the plurality of bridging elements is connected with the elongated side elements. The plurality of bridging elements corresponds to the spacing zones.

Abstract: A laser patterning touch panel includes an active area, an inactive area, and a plurality of first coaxial patterns. The active area is disposed in a center area of the substrate. The inactive area does not overlap the active area and has a transparent conductive layer thereon. The plurality of first coaxial patterns are disposed on the transparent conductive layer and surround the active area. Each of the plurality of first coaxial patterns includes a continuous line segment with a width, and partially overlaps with a neighboring one of the first coaxial patterns.

Abstract: A touch panel and a manufacturing method thereof and a touch display panel are provided. The touch panel includes a substrate, at least one first conductive line, an insulating layer, and at least one second conductive line. The substrate has a sensing region and a periphery region. The first conductive line is disposed on the periphery region. The insulating layer is disposed on the periphery region and covers the first conductive line. The second conductive line is disposed on the periphery region. The first conductive line and the second conductive line are electrically insulated to each other. A portion of at least one second conductive line is disposed on the insulating layer located above the first conductive line.

Abstract: An electrical property measuring apparatus for pressure sensor includes a first plate, a second plate, an object to be measured, an electrical property measuring unit used for measuring the electrical properties of the object, and a fluid supplying system. The second plate is opened or closed relative to the first plate. The object is disposed between the first plate and the second plate. The fluid supplying system connects to a space formed by the first plate and a pressed surface or a space formed by the second plate and a pressed surface. The fluid supplying system provides a fluid to the space such that the fluid presses on the object and the electrical property measuring unit measures the electrical properties of the object. A method of measuring electrical property for pressure sensor is also provided.

Abstract: A pressure measurement structure includes a first substrate, a second substrate, a first electrode layer, a second electrode layer, at least a piezoresistive layer and a wiring layer. The second substrate faces towards the first substrate. The first electrode layer is disposed on the first substrate and faces towards the second substrate. The second electrode layer is disposed on the second substrate and faces towards the first electrode layer. At least a piezoresistive layer is located between the first electrode layer and the second electrode layer. A wiring layer is disposed on the second substrate and back to the first substrate. The wiring layer includes multiple wires. Part of the wires are electrically connected to the first electrode layer. The other part of the wires are electrically connected to the second electrode layer.

Abstract: An electrical property measuring apparatus for pressure sensor includes a first plate, a second plate, an object to be measured, an electrical property measuring unit used for measuring the electrical properties of the object, and a fluid supplying system. The second plate is opened or closed relative to the first plate. The object is disposed between the first plate and the second plate. The fluid supplying system connects to a space formed by the first plate and a pressed surface or a space formed by the second plate and a pressed surface. The fluid supplying system provides a fluid to the space such that the fluid presses on the object and the electrical property measuring unit measures the electrical properties of the object. A method of measuring electrical property for pressure sensor is also provided.

Abstract: An improved imprint device is disclosed. It comprises a drive component, an imprinting object, and at least one mold, stacked together within a chamber, a fluid supplier is used for providing the solvent fluid into the chamber through a pipe. The solvent fluid will permeate the imprinting object, and the imprinting object will be plasticized at the temperature lower than the glass transition temperature. The drive component is used for driving the mold to the plasticized imprinting object, so that the pattern on the mold will be imprinted on the imprinting object. It is the advantage of the present invention to reduce the process temperature, prevent the pattern distortion, and save the process time. Furthermore, by using the fluid and a barrier film as a pressing medium, the pressure can be applied to the object and the mold uniformly, such that a large area imprint can be achieved.

Abstract: An improved imprint device is disclosed. It comprises a drive component, an imprinting object, and at least one mold, stacked together within a chamber, a fluid supplier is used for providing the solvent fluid into the chamber through a pipe. The solvent fluid will permeate the imprinting object, and the imprinting object will be plasticized at the temperature lower than the glass transition temperature. The drive component is used for driving the mold to the plasticized imprinting object, so that the pattern on the mold will be imprinted on the imprinting object. It is the advantage of the present invention to reduce the process temperature, prevent the pattern distortion, and save the process time. Furthermore, by using the fluid and a barrier film as a pressing medium, the pressure can be applied to the object and the mold uniformly, such that a large area imprint can be achieved.