In a customizable circuit an interconnect matrix is provided that includes only two conductive layers, the matrix defining a first layer of L-shaped conductive lines and a second layer of substantially L-shaped conductive line segments that are connected to electrical components.

There are provided a manufacturing method for a substrate having a conductive pattern, a manufacturing method for an electronic device, and a substrate having a conductive pattern, which are excellent in the dimensional stability of the conductive pattern after applying an electric current, as well as a protective film for a metal nanobody.

Provided are the manufacturing method for a substrate having a conductive pattern, comprising a step 1a of forming a conductive layer a containing a metal nanobody and a resin 1 on a substrate; a step 1b of forming a resin layer b containing a resin 2 on the conductive layer a; a step 2a of forming a photosensitive resin layer c on the resin layer b; a step 3 of obtaining a resin pattern c′ of the photosensitive resin layer by exposure and development treatment on the photosensitive resin layer c; a step 4 of removing the metal nanobody in the conductive layer a by etching to form a conductive pattern d; and a step 5a of softening or swelling at least one of the resin 1 or the resin 2, the manufacturing method for an electronic device, the substrate having a conductive pattern, and the protective film for a metal nanobody.

A display device is provided. The display device includes an auxiliary substrate, a display substrate, and a circuit board. The auxiliary substrate includes an auxiliary circuit. The display substrate is disposed on the auxiliary substrate. The display substrate includes a circuit. The circuit board is electrically connected to the auxiliary substrate. The circuit of the display substrate is electrically connected to the auxiliary circuit through a first conductive via, and the circuit board provides a signal to the auxiliary circuit.

According to one embodiment, a flexible substrate includes a first protective member including a first surface, a line portion including a flexible insulating base located on the first surface and a wiring layer disposed on the insulating base and a second protective member covering the line portion, and the first protective member includes a valley portion and a peak portion in the first surface, and the line portion is formed in a wavy shape and located on the valley portion and the peak portion.

A transparent conductive film includes a transparent insulating substrate, a first electrode, and a second electrode, in which a first thin metal wire 38 of the first electrode has a first front surface 38A being directed to the viewing side and having a line width W1A, and a first back surface 38B being directed to the side opposite to the viewing side and having a line width W1B, a second thin metal wire 39 of the second electrode has a second front surface 39A being directed to the viewing side and having a line width W2A, and a second back surface 39B being directed to the side opposite to the viewing side and having a line width W2B, the W1A, W1B, W2A, and W2B are 0.5 to 10 μm, W1A is larger than W1B and W2A is larger than W2B.

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.

A chip part includes a substrate, a first electrode and a second electrode which are formed apart from each other on the substrate and a circuit network which is formed between the first electrode and the second electrode. The circuit network includes a first passive element including a first conductive member embedded in a first trench formed in the substrate and a second passive element including a second conductive member formed on the substrate outside the first trench.

According to one embodiment, a flexible substrate includes flexible insulating base material, conductive lines, a support body and a coating layer. The conductive lines are provided on the insulating base material. The support body supports the insulating base material. The coating layer covers the insulating base material and the support body. The conductive lines include scanning lines and signal lines. The scanning lines extend in a first direction and are arranged side by side in a second direction intersecting the first direction. The signal lines extend in the second direction and are arranged side by side in the first direction. The support body and the coating layer have a through hole in a region enclosed by two adjacent scanning lines and two adjacent signal lines.

The present invention aims to provide a substrate having an ITO with a low ITO pattern visibility, which substrate is formed by a method utilizing a simple technique such as coating, printing or the like, and which method is less burdensome from the viewpoints of cost and process; and to provide a touch panel member using the substrate. The present invention provides a substrate including a region where thin layers are laminated on a transparent ground substrate, which thin layers are, in the order mentioned from the upper surface of the substrate: an ITO (Indium Tin Oxide) thin layer (I); an organic thin layer (II) having a film thickness of from 0.01 to 0.4 μm and a refractive index of from 1.58 to 1.85; and a transparent adhesive thin layer (III) having a refractive index of from 1.46 to 1.52.

Provided herein is a method for manufacturing a conductive transparent substrate, the method including forming a plurality of main electrodes on the substrate such that the main electrodes are distanced from one another; and forming a connecting electrode that electrically connects two or more main electrodes such that the plurality of main electrodes are grouped into a plurality of group electrodes that are electrically disconnected from one another, thereby producing a conductive transparent substrate with excellent transmittance in a process of high yield.