A flexible printed circuit is described that includes a flexible supporting substrate having a first face and a second face. A conductive material is deposited by vacuum deposition on at least one of the first face or the second face of the flexible supporting substrate. A flexible conductive circuit is formed on the conductive material by electrical discharge machining. The flexible conductive circuit defines a plurality of electrical component placement circuits to which electrical components may be attached. The flexible printed circuit can be rolled or folded. The flexible printed circuit can also be made in sizes much larger than is currently possible with other competing technologies.

A method of forming an multi-chip carrier that includes providing a trace structure using an additive forming method. The method includes forming a metal layer on a trace structure to provide electrically conductive lines. A dielectric material may then be formed on the electrically conductive lines to encapsulate a majority of the electrically conductive lines. The ends of the electrically conductive lines that are exposed through the upper surface of the dielectric material provide a top processor mount location and the ends of the electrically conductive lines that are exposed through the sidewalls of the dielectric material provide a sidewall processor mount location.

Semiconductor layers useable for minimizing or preventing the growth of metal whiskers, as well as devices and methods utilizing the same and kits for making the same, are described.

A circuit board comprising a substrate and a circuit trace. The substrate includes a surface etched via ion milling over a circuit area such that the surface has an increased roughness. The circuit trace forms portions of an electronic circuit and may be created from a thin conductive film deposited on the surface within the circuit area. The circuit trace adheres more strongly to the roughened substrate surface, which prevents the circuit trace from peeling or becoming delaminated from the substrate surface.

A method of forming an multi-chip carrier that includes providing a trace structure using an additive forming method. The method includes forming a metal layer on a trace structure to provide electrically conductive lines. A dielectric material may then be formed on the electrically conductive lines to encapsulate a majority of the electrically conductive lines. The ends of the electrically conductive lines that are exposed through the upper surface of the dielectric material provide a top processor mount location and the ends of the electrically conductive lines that are exposed through the sidewalls of the dielectric material provide a sidewall processor mount location.

A circuit board comprising a substrate and a circuit trace. The substrate includes a surface etched via ion milling over a circuit area such that the surface has an increased roughness. The circuit trace forms portions of an electronic circuit and may be created from a thin conductive film deposited on the surface within the circuit area. The circuit trace adheres more strongly to the roughened substrate surface, which prevents the circuit trace from peeling or becoming delaminated from the substrate surface.

The present invention relates to a method for producing a stretchable conductor and/or electrical connection including providing a stretchable substrate, a liquid metal, a conductive metal and an adhesion material in a same evaporator chamber; depositing the liquid metal; depositing the adhesion material; depositing the conductive metal; wherein the liquid metal, the conductive metal and the adhesion material are deposited by evaporation; and the deposition by evaporation is made in vacuum.

An electronic circuit is made by selectively depositing an electrically conductive material seed layer conformally upon a three-dimensional substrate via the plurality of apertures of a three-dimensional mask. The substrate is then plated with more of the same electrically conductive material, or a different electrically conductive material, on the seed layer. In the case of electroplating, a nonconductive support structure is incorporated into a conductive clamp for making electrical connection to the seed layer. An environmentally protective layer may be deposited upon the electrically conductive material to such an extent that the electronic circuit remains solderable. The three-dimensional mask may be fabricated by an additive manufacturing technique.

Techniques related to microwave attenuator son high-thermal conductivity substrates for quantum applications are provided. A device can comprise a substrate that provides a thermal conductivity level that is more than a defined thermal conductivity level. The device can also comprise one or more thin film lines, on a top surface of the substrate, comprising an evaporated alloy. Further, the device can comprise one or more vias within the substrate. Respective first ends of the one or more vias are can be connected to respective thin film connectors. Further, respective second ends of the one or more vias can be connected to an electrical ground.

An evaporation apparatus (100) for depositing material on a flexible substrate (160) supported by a processing drum (170) is provided. The evaporation apparatus includes: a first set (110) of evaporation crucibles aligned in a first line (120) along a first direction for generating a cloud (151) of evaporated material to be deposited on the flexible substrate (160); and a gas supply pipe (130) extending in the first direction and being arranged between an evaporation crucible of the first set (110) of evaporation crucibles and the processing drum (170), wherein the gas supply pipe (130) includes a plurality of outlets (133) for providing a gas supply directed into the cloud of evaporated material, and wherein a position of the plurality of outlets is adjustable for changing a position of the gas supply directed into the cloud of evaporated material.