A method for making a conductive network of sintered silver comprises preparing a conductive ink comprising a silver compound and a binder; depositing the conductive ink on a substrate and applying an external energy source to the deposited conductive ink to dry the ink; and applying an external energy source to the dried ink to decompose the ink to elemental silver and to sinter the elemental silver into a conductive network.

Depicted embodiments are directed to an Application Specific Electronics Packaging (“ASEP”) system, which enables the manufacture of additional products using reel to reel (68a, 68b) manufacturing processes as opposed to the “batch” processes used to currently manufacture electronic products and MIDs. Through certain ASEP embodiments, it is possible to integrate connectors, sensors, LEDs, thermal management, antennas, RFID devices, microprocessors, memory, impedance control, and multi-layer functionality directly into a product.

A method for producing a wired circuit board including an insulating layer and a conductive pattern, including (1), providing the insulating layer having an inclination face; (2), providing a metal thin film at least on the surface of the insulating layer; (3), providing a photoresist on the surface of the metal thin film; (4), disposing a photomask so that a first portion, where the conductive pattern is provided in the photoresist, is shielded from light, and the photoresist is exposed to light through the photomask; (5), removing the first portion to expose the metal thin film corresponding to the first portion; and (6), providing the conductive pattern on the surface of the metal thin film exposed from the photoresist. The inclination face has a second portion that allows the light reflected at the metal thin film to reach the first portion.

A circuit board according to the present disclosure includes a substrate that is composed of a ceramic(s), and an electrically conductive layer that is positioned in contact with the substrate. The substrate includes a groove around the electrically conductive layer. Furthermore, an electronic device according to the present disclosure includes a circuit board with a configuration as described above, and an electronic component that is positioned on the electrically conductive layer.

A reel-to-reel machine to fabricate a printed flexible circuit on the fly, the machine has a plurality of reels, a laser scanner to ablate a metal foil, a source of UV light or heat to curing an adhesive in a coverlay, another source of UV light or heat to debond a sacrificial liner on the fly. There is a depositor to deposit a sintering paste on the fly onto a predetermined spot for a pad on the metal foil. Removal of slugs are also possible on the fly.

A reel-to-reel method of creating pads on a layer of metal sheet or circuitry pattern on the fly. The method includes placing a sintering paste in the intended spots for pads followed by irradiation of the sintering paste by a laser.

A stretchable and transparent electronic structure may generally include a stretchable elastomer layer; optionally, a metal adhesion layer on top of the stretchable elastomer layer; a metal alloying layer on top of the metal adhesion layer; and a liquid metal, wherein the structure is colorless and transparent when viewed under visible light. Methods of making the stretchable and transparent electronic structure are also described.

A near-eye optic includes a substrate having a clear aperture for propagating light. An inconspicuous electrical circuit is supported by the substrate in the clear aperture of the substrate. The inconspicuous electrical circuit includes a plurality of inconspicuous conductive traces disposed in an inconspicuous pattern and electrically coupled to a plurality of inconspicuous electrical components. The inconspicuous pattern may include e.g. an asymmetric pattern, an aperiodic pattern, a pseudo-random pattern, a meandering pattern, a periodic pattern modulated with pseudo-random perturbations, or a non-rectangular pattern modulated with pseudo-random perturbations.

A product includes a substrate, at least one of a conductive layer or a coating layer, and an ablated surface on the substrate. The substrate is at least partially transparent to visible light. The at least one of the conductive layer or the coating layer are disposed over at least a portion of the substrate. The ablated surface includes an interleaved surface profile having a plurality of non-overlapped laser spots and a plurality of overlapped laser spots formed by subjecting the substrate to an interleaving laser ablation process.

A protective film of a conductive adhesive, a circuit board and a method for assembling a display device are provided. The protective film of conductive adhesive includes: a basic material layer; and a photoinduced peelable adhesive and a protective layer which are arranged on a first surface of the basic material layer in sequence, and the photoinduced peelable adhesive has a low adhesive force in the exposure of light with a first wavelength. The protective film further includes a light-shielding film located on a second surface of the basic material layer opposite to the first surface.