Disclosed herein are laser scanning systems and methods of their use. In some embodiments, laser scanning systems can be used to ablatively or non-ablatively scan a surface of a material. Some embodiments include methods of scanning a multi-layer structure. Some embodiments include translating a focus-adjust optical system so as to vary laser beam diameter. Some embodiments make use of a 20-bit laser scanning system.

The present invention relates to an electrically conductive film characterized by being able to undergo elastic deformation, having little residual strain rate and exhibiting stress relaxation properties. More specifically, the present invention relates to an electrically conductive film wherein the stress relaxation rate (R) and the residual strain rate (alpha), as measured in a prescribed extension-restoration test, are as follows: 20%≦R≦95% and 0%≦α≦3%.

In a case of a multilayer wiring structure in which an insulating layer provided between wires is made of a material having high transmittance of light in a visible range containing ultraviolet rays, wires in the upper layer and those in a lower layer may be recognized together when defects of an upper layer are visually inspected. In this case, the lower layer may be noise for the inspection of the wires in the upper layer, lowering inspection accuracy. This lowered inspection accuracy has inhibited improvement in manufacturing yields and reliability. In order to solve this issue, a multilayer wiring substrate of the disclosure includes: a substrate; and a first wire and a second wire that are provided on the substrate with an insulating layer having a light transmitting property in between, and one or both of which are subjected to a surface treatment.

Provided is an optically transparent conductive material which is suitable as an optically transparent electrode for capacitive touchscreens, the optically transparent conductive material not causing moire even when placed over a liquid crystal display, having a favorably low pattern conspicuousness (non-conspicuousness), and having a high reliability. The optically transparent conductive material has, on an optically transparent support, an optically transparent conductive layer having optically transparent sensor parts electrically connected to terminal parts and optically transparent dummy parts not electrically connected to terminal parts, and in this optically transparent conductive material, the sensor parts and the dummy parts are formed of a metal thin line pattern having a mesh shape, and in the plane of the optically transparent conductive layer, the contour shape of each of the sensor parts extends in a first direction, the dummy parts are arranged alternately with the sensor parts in a second direction perpendicular to the first direction, the sensor parts are arranged at a cycle of L in the second direction, at least part of the metal thin line pattern in the sensor parts has a cycle of 2L/N in the second direction (wherein N is any natural number), and the metal thin line pattern in the dummy parts has a cycle longer than 2L/N or does not have a cycle in the second direction.

Provided are an optical sensor device using surface acoustic waves and an optical sensor device package. The optical sensor device includes: a substrate including a first light sensing area and a temperature sensing area and including a piezo electric material; a first input electrode and a first output electrode which are disposed in the first light sensing area and are apart from each other with a first delay gap therebetween; a first sensing film overlapping the first delay gap and configured to cover at least some portions of the first input electrode and the first output electrode; and a second input electrode and a second output electrode which are disposed in the temperature sensing area and are apart from each other with a second delay gap therebetween. The second delay gap is exposed to air.

An electronic device may have layers of glass for forming components such as a display. A display cover glass layer may overlap an array of pixels. A touch sensor may be formed under the display cover glass layer. Conductive structures such as transparent conductive electrodes or other conductive layers of material may be formed on the outer surface of the display cover glass layer. The electrodes on the outer surface of the display cover glass layer may be coupled to metal contacts and other circuitry on the inner surface of the display cover glass layer using conductive vias. Vias may be provided with barrier layers, opaque coatings, tapers, and other structures and may be formed using techniques that enhance compatibility with chemical strengthening processes.

A novel method for the manufacturing of fine line circuitry on a transparent substrates is provided, the method comprises the following steps in the given order providing a transparent substrate, depositing a pattern of light-shielding activation layer on at least a portion of the front side of said substrate, placing a photosensitive composition on the front side of the substrate and on the pattern of light-shielding activation layer, photo-curing the photosensitive composition from the back side of the substrate with a source of electromagnetic radiation, removing any uncured remnants of the photosensitive composition; and thereby exposing recessed structures and deposition of at least one metal into the thus formed recessed structures whereby a transparent substrate with fine line circuitry thereon is formed. The method allows for very uniform and fine line circuitry with a line and space dimension of 0.5 to 10 μm.

Provided are flexible electronics stacks and methods of use. An example flexible electronics stack includes a flexible polymeric substrate film and a rigid inorganic electronic component. The flexible polymeric substrate film includes a thermoset polymer prepared by curing a monomer solution; wherein the monomer solution comprises about 25 wt % to about 65 wt % of one or more thiol monomers and from about 25 wt % to about 65 wt % of one or more co-monomers.

Filament type light emitting devices are disclosed. One of the light emitting devices includes a non-conductive transparent substrate, one or more light emitting diode chips arrayed above the upper surface of the non-conductive transparent substrate and each including input and output ends extending toward the non-conductive transparent substrate, and conductive transparent connection portions formed on the upper surface of the non-conductive transparent substrate and electrically connected to the input and output ends. Light transmitting regions are provided without reflectors in the vicinity of the input and output ends between the non-conductive transparent substrate and the light emitting diode chips. Thus, light is emitted backward from the light emitting diode chips through the light transmitting regions and the non-conductive transparent substrate.

An electronic device including a substrate, a first metal pattern, a first insulating pattern, and a second metal pattern is provided. The first metal pattern is disposed on the substrate. The first insulating pattern is disposed on the first metal pattern. The second metal pattern is disposed on the first metal pattern and the first insulating pattern. The second metal pattern includes a first contact portion and a second contact portion. In a cross-sectional view, the first contact portion and the second contact portion are in contact with the first metal pattern, and the first insulating pattern is in contact with the first metal pattern and the second metal pattern between the first contact portion and the second contact portion.