An electrical conductor includes a substrate; and a first conductive layer disposed on the substrate and including a plurality of metal oxide nanosheets, wherein adjacent metal oxide nanosheets of the plurality of metal oxide nanosheets contact to provide an electrically conductive path between the contacting metal oxide nanosheets, wherein the plurality of metal oxide nanosheets include an oxide of Re, V, Os, Ru, Ta, Ir, Nb, W, Ga, Mo, In, Cr, Rh, Mn, Co, Fe, or a combination thereof, and wherein the metal oxide nanosheets of the plurality of metal oxide nanosheets have an average lateral dimension of greater than or equal to about 1.1 micrometers. Also an electronic device including the electrical conductor, and a method of preparing the electrical conductor.

Described are various configurations of high-speed via structures. Various embodiments can reduce or entirely eliminate insertion loss in high-speed signal processing environments by using impedance compensation structures that decrease a mismatch in components of a circuit. An impedance compensation structure can include a metallic structure placed near a via to lower an impedance difference between the via and a conductive pathway connected to the via.

A printed circuit board includes a spread weave of fibers having a first direction and a second direction with corresponding fibers spread more in the first direction than the second direction; and one or more pairs of traces on the spread weave of fibers, wherein the first direction has less differences in dielectric permittivity seen by each trace than the second direction, wherein the one or more pairs of traces are routed according to a routing design that includes one or more fixed regions on the spread weave of fibers, where routing of traces therein is restricted to linear, non-angled routed in the first direction.

Embodiments of a printed wiring board configured to inhibit increases in electrical resistance between a ground circuit and a reinforcement member are disclosed. The printed wiring board has a substrate film with a base film and a printed circuit, which printed circuit includes a ground circuit; an adhesive layer formed on the substrate film; and a conductive reinforcement member formed on the adhesive layer. The adhesive layer includes conductive particles. One or more layers of low-melting-point metal is or are provided between the adhesive layer and the substrate film; between the adhesive layer and the reinforcement member; and/or around the conductive particles.

An electronic circuit includes a first conductor configured horizontally on a first layer and a second conductor configured horizontally on a second layer. The second conductor is separated from the first conductor by a plurality of layers. A third conductor is configured between the first layer and the second layer. The third conductor electrically couples the first conductor and the second conductor. One or more intermediate conductors are electrically coupled to the third conductor, with the one or more intermediate conductors configured on one or more intermediate layers between the first layer and the second layer.

Provided is an electronic apparatus capable of improving time margin. The electronic apparatus includes: a base substrate including a substrate base including a plurality of layers and a plurality of wiring layers between the layers; a controller chip and at least one memory semiconductor chip mounted on the base substrate; a signal line disposed in one of the wiring layers and connecting the controller chip to the at least one memory semiconductor chip; and a pair of open stubs disposed in another wiring layer, connected to both ends of the signal line, and extending to face each other with a gap.

A substrate for a medical device, a portion of which is brought into contact with or inserted into a subject. The substrate includes a patient circuit conductively connected to the portion that is configured to be brought into contact with or inserted into the subject, and a ground-side circuit configured to perform at least one of transmission of a signal, reception of a signal, and supply of electric power on the patient circuit. The ground-side circuit is grounded by a protective ground to ensure safety of a manipulator of the medical device. The substrate also includes an insulating layer between the patient circuit and the ground-side circuit providing insulation between the patient circuit and the ground-side circuit, and an isolated circuit provided apart from the patient circuit and the ground-side circuit on the insulating layer and having a different reference potential from the patient circuit and the ground-side circuit.

A substrate for a medical device, a portion of which is brought into contact with or inserted into a subject. The substrate includes a patient circuit conductively connected to the portion that is configured to be brought into contact with or inserted into the subject, and a ground-side circuit configured to perform at least one of transmission of a signal, reception of a signal, and supply of electric power on the patient circuit. The ground-side circuit is grounded by a protective ground to ensure safety of a manipulator of the medical device. The substrate also includes an insulating layer between the patient circuit and the ground-side circuit providing insulation between the patient circuit and the ground-side circuit, and an isolated circuit provided apart from the patient circuit and the ground-side circuit on the insulating layer and having a different reference potential from the patient circuit and the ground-side circuit.

The conductive composition of the present embodiment contains metal nanoparticles having an average particle diameter of 30 nm to 600 nm, metal particles having an average particle diameter larger than that of the metal nanoparticles, a thermosetting resin having an oxirane ring in a molecule, a curing agent, and a cellulose resin. Then, the specific resistance of the conductor formed by applying and calcining the conductive composition on the substrate is preferably 5.010.sup.6 .Math.cm or less, and the conductor does not peel from the substrate when a tape having an adhesive force of 3.9 N/10 mm to 39 N/10 mm is pressed against the conductor and peeled off.

The present invention provides a photosensitive resin composition with which a dry resist film can be obtained, the dry resist film exhibiting excellent storage stability and migration resistance in thickness direction thereof. This photosensitive resin composition comprises: a photosensitive prepolymer having a carboxyl group and an ethylenically unsaturated group; a photopolymerization initiator; and a thermosetting agent. The thermosetting agent is a polycarbodiimide compound represented by formula (1), in which a carbodiimide group is protected by an amino group that dissociates at temperatures of 80 C. or greater. The polycarbodiimide compound has a weight average molecular weight of 300-3000, and a carbodiimide equivalent weight of 150-600. In formula (1), R.sup.1, R.sup.2, X.sup.1, X.sup.2, and n are as defined in the description.