Processes for creating a two-dimensional-target structure are disclosed. An example process to create a two-dimensional-target structure may include the process of providing two-dimensional material grown on an initial substrate to create a two-dimensional-substrate structure; applying the two-dimensional-substrate structure to a target substrate via an adhesion promoter to create a lamination stack; applying a lamination process to the lamination stack; and then removing the initial substrate from the lamination stack, post-lamination, to create the two-dimensional-target structure. The two-dimensional-target structure may then be used in such rigid or flexible electronic devices and/or non-standard devices as the target substrate may be rigid or flexible and/or translucent in contrast to the initial substrate first used to grow the two-dimensional material.

Processes for laminating a conductive-lubricant coated Printed Circuit Board (PCB) are disclosed. An example laminated PCB may include a lamination stack that may further include a core, an adhesive layer, and at least one graphene-metal structure or at least one hexagonal Boron Nitride metal (h-BN-metal) structure. The materials of the PCB may change in accordance with the invention described herein, including the materials of the core, the materials of the conductive-lubricant coatings, or the metal layers of the conductive-lubricant-metal structures. Doping processes for each change in materials used are also described herein. The conductive-lubricant of the conductive-lubricant-metal structure will promote high frequency performance and heat management within the PCB. Furthermore, a removal process of those materials post-lamination is described herein to promote protection of materials and subsequent removal of protective layers without breakage or tearing.

A method for producing a prepreg, includes the steps of (1) an opening step of opening glass fiber bundles to form plural glass fiber filaments, and (2) a step of aligning the plural glass fiber filaments formed in the previous opening step, on a thermosetting resin composition-coated surface of a carrier material so as to make the filaments run nearly parallel to each other in one direction thereon to form a prepreg. A method for producing a laminate, includes a step of preparing two or more prepregs formed in the previous step (2), laminating them in such a manner that, in at least one pair of prepregs, the running direction of the plural glass fiber filaments in one prepreg differs from the running direction of the plural glass fiber filaments in the other prepreg, and heating and pressing them.

A wireless communication device includes a base sheet in a folded state, a first conductor pattern disposed on a first principal surface of the base sheet, a second conductor pattern disposed on a second principal surface of the base sheet opposite to the first principal surface, an RFIC chip disposed on the base sheet so as to electrically connect to the first conductor pattern, and a sheet-shaped connection conductor coupled to a turning part of the base sheet so as to partially overlap with an end portion of the first conductor pattern near the turning part and an end portion of the second conductor pattern near the turning part.

A component carrier with an electrically insulating layer structure has opposed main surfaces, a through-hole, and an electrically conductive bridge structure connecting opposing sidewalls delimiting the through-hole. The sidewalls have a first tapering portion extending from a first main surface and a second tapering portion extending from a second main surface. A first demarcation surface faces the first main surface and a second demarcation surface faces the second main surface. A central bridge plane extends parallel to the first main surface and the second main surface and is at a vertical center between a lowermost point of the first demarcation surface and an uppermost point of the second demarcation surface. A first intersection point is between the central bridge plane and one of the sidewalls delimiting the through hole. A length of a shortest distance from the first intersection point to the first demarcation surface is at least 8 μm.

A multilayer board insulating sheet contains a reducing agent.

A wiring board includes: first and second insulating layers; a first wiring conductor layer located between the first and second insulating layers and including a first via land; a second wiring conductor layer located on the second insulating layer and including a second via land; a via hole penetrating from the upper to lower surfaces of the second insulating layer; and a via conductor located in the via hole and electrically connecting the first second via lands. The via conductor is located on the inner surface of the via hole and on the first via land via a first base layer containing nichrome and a second base layer located on the upper surface of the first base layer and containing the same metal as the via conductor. An alloy layer containing tin and nichrome is located between the first via land and the first base layer.

A multilayer substrate includes a multilayer body in which insulating layers are laminated in a laminating direction, a front electrode that is provided on a front surface side of a first insulating layer which is positioned on a front surface side of the multilayer body among the insulating layers, a first internal electrode that is provided on an opposite side to the front electrode with the first insulating layer interposed therebetween, and a first interlayer connection conductor that electrically connects the front electrode and the first internal electrode with each other. The first interlayer connection conductor includes a front side connection surface that is electrically connected with the front electrode and a back side connection surface that is electrically connected with the first internal electrode.

A multi-layer circuit board with embedded components (100) in multiple layers and miniaturized form, with embedded electronic elements in a higher element density and shorter voltage paths includes a circuit board (10) provided with a mounting groove (101), and a plurality of elements (20). The elements (20) are arranged in the mounting groove (101), and the circuit board (10) includes several vertically-stacked circuit substrates (11, 12, 13, 14) arranged around the mounting groove (101), The multi-layer circuit board with embedded components circuit board (100) includes a conductive member (30) arranged in the mounting groove (101) and electrically connecting the elements (20) and the layers of conductive circuits.

A hard disk drive flexible printed circuit (FPC) includes a plurality of fingers extending from a main portion, with each finger having a first wiring layer including a first electrically conductive trace layout, a second wiring layer including a second electrically conductive trace layout, and a base film interposed between the first and second wiring layers, where the first conductive trace layout includes at least one thermally conductive protective island overlaying a respective portion of the second trace layout to provide a protective thermal barrier to the base film. Hence, maximum temperatures across various layers of the FPC laminate can be reduced, damage to the FPC prevented, and manufacturing yields improved.