Provided is a bidirectional neural interface having excellent elasticity and electrical conductivity improved by deformation, and further having self-healability and a method of manufacturing the same. The bidirectional neural interface includes a first elastic substrate, a neural electrode disposed on the first elastic substrate and including a conductive polymer composite, and a second elastic substrate disposed on the neural electrode, wherein the conductive polymer composite includes a matrix formed of a self-healing polymer material, and a plurality of electrical conductor clusters distributed in the matrix, wherein each of the electrical conductor clusters includes particles of a first electrical conductor, and a plurality of particles of a second electrical conductor formed of the same material as that of the first electrical conductor, distributed around each of the particles of the first electrical conductor and having smaller sizes than sizes of the particles of the first electrical conductor.

Various embodiments are directed to a method of forming an apparatus including placing a first electronic circuit in contact with a second electronic circuit, wherein each of the first and second electronic circuits have connector circuits configured and arranged to provide an electrical connection between the first and second electronic circuits and are formed with a polymer film that is configured to adhere, via self-healing, to another polymer film. The method further includes, in response to the contact, causing or facilitating the self-healing of the respective polymer films of the first and second electronic circuits, thereby creating the electrical connection therebetween.

Disclosed is an electronic device that includes a first cover, a second cover opposite the first cover, a side housing disposed between the first cover and the second cover and including a plate disposed between the first cover and the second cover and a frame surrounding the plate and connected with the first cover and the second cover, a display disposed between the plate and the first cover, and a printed circuit board disposed between the plate and the second cover and including a first surface facing the plate, a second surface facing the second cover, and side surfaces provided between the first surface and the second surface, at least some of the side surfaces including plated areas. The plate includes a connection structure to which the printed circuit board is electrically connected, the connection structure includes a recess, the recess including a first sidewall, a second sidewall facing the first sidewall, a first conductive structure comprising a conductive material disposed on the first sidewall, and a second conductive structure comprising a conductive material disposed on the second sidewall, and at least part of the printed circuit board is disposed in the recess such that the plated areas contact the first conductive structure and the second conductive structure.

The power on wafer assembly can include: a compliant connector, an integrated circuit, a printed circuit board (PCB), a power component, and a set of compliant connectors. The power on wafer assembly can optionally include: a compression element, a cooling system, a set of mechanical clamping components, and a power source. However, the power on wafer assembly can additionally or alternately include any other suitable components.

This invention is directed to substrates and articles utilizing these substrates that provide improved performance of printable electronics on polymer substrates. In particular, the improved substrates relate to polymer films and electrical conductors printed on them. Application of a thin polymeric coating to the polymer film provides the improved performance of the printed conductors.

Embodiments include an interconnectable circuit board array. The interconnectable circuit board array includes a plurality of interconnectable circuit boards coupled together with a plurality of board to board connectors. The board to board connectors include a first lateral side conductor and a second lateral side conductor to provide electrical communication between the connect circuit boards. The board to board connectors are configured such that when two adjacent circuit boards are bent in a lateral plane with respect to one another to form an angle, one of the lateral side conductors is contracted, one of the lateral side conductors is expanded, or one of the lateral side conductors is contracted and the other lateral side conductor is expanded. Other embodiments are also included herein.

Disclosed herein is a composite comprising an elastomer with an embedded network of liquid metal inclusions. The composite retains similar flexibility to that of an elastomer but exhibits electrical and thermal properties that differ from the properties of a homogeneous elastomer. The composite has applications for wearable devices and other soft matter electronics, among others.

An interconnect device may include a first center conductor of a first material that has a first durometer. The first center conductor may be surrounded by a first inner dielectric ring, which may be surrounded by a conductive region of a second material having a second durometer. The second durometer may be different from the first durometer. The conductive region may have a first end that defines a first plane and a second end that defines a second plane. An outer dielectric ring may surround the conductive region. The first center conductor may have a first bulb and a second bulb, the first bulb may extend in a direction away from the second plane and beyond the first plane, and the second bulb may extend in a direction away from the first plane and beyond the second plane.

A flexible circuit may be provided that allows for the monitoring of a physical object. The flexible circuit includes a plurality of flexible conductive segments that are disposed in a geometric pattern. The flexible conductive segments include nodes, and the physical object is monitored by analyzing changes in electrical resistance in the conductive segments between the nodes. The flexible circuit may also include sensors disposed on the nodes for monitoring additional conditions. A processor monitors the flexible conductive segments and sensors, and may provide an output regarding the status of the physical object.

An objective is to provide a stretchable conductor sheet which is useful as a material for electrical wiring and electrodes for garment-type electronic devices, the material having excellent durability in terms of washing and durability in terms of perspiration. A fabric provided with an electrode and an electrical wiring, which are formed from a stretchable conductor sheet, is obtained by: providing a film having releasability with a first stretchable conductor layer which is formed from a paste material that uses carbon-based particles as a conductive filler, while using a flexible resin as a binder resin; subsequently forming a second stretchable conductor layer, while using metal-based particles as a conductive filler; laminating a hot melt adhesive layer thereon; superposing the resulting laminate on a fabric after removing unnecessary parts from the laminate by means of partial slits; and subjecting the resulting fabric to hot pressing. Since the carbon-based particles adsorb a contamination substance of the metal-based particles, oxidation degradation and sulfuration degradation of the metal-based particles is reduced, thereby improving the durability.