In an example, a dry film solder mask (DFSM) composite laminate material is disclosed. The DFSM composite laminate material includes a printed circuit board (PCB) laminate material, a cyclic compound chemically bonded to the PCB laminate material, and a DFSM material. The DFSM material is reversibly bonded to the PCB laminate material via the cyclic compound.

A method of making a printed circuit board pallet is provided. The method of making the pallet illustratively includes the steps of: providing a base in a form of a polymer sheet stock; applying a fluid onto the base at selective locations where the pallet will be built-up to a three-dimensional form; depositing a polymer powder onto the base at the selective locations applied with the fluid; removing any excess amounts of the polymer powder not adhered to the fluid; and heating the pallet to fuse the polymer powder together and to the base.

A method of forming a flexible interconnect circuit is described. The method may comprise laminating a substrate to a conductive layer and patterning the conductive layer using a laser while the conductive layer remains laminated to the substrate thereby forming a first conductive portion and a second conductive portion of the conductive layer. The substrate maintains the orientation of the first conductive portion relative to the second conductive portion during and after patterning. The method may also comprise laminating a first insulator to the conductive layer and removing the substrate from the conductive layer such that the first insulator maintains the orientation of the first conductive portion relative to the second conductive portion while and after the substrate is removed. The method may also comprise laminating a second insulator to the second side of the conductive layer while the first insulator remains laminated to the substrate.

Provided are interconnect circuits and methods of forming thereof. A method may involve laminating a substrate to a conductive layer followed by patterning the conductive layer. This patterning operation forms individual conductive portions, which may be also referred to as traces or conductive islands. The substrate supports these portions relative to each other during and after patterning. After patterning, an insulator may be laminated to the exposed surface of the patterned conductive layer. At this point, the conductive layer portions are also supported by the insulator, and the substrate may optionally be removed, e.g., together with undesirable portions of the conductive layer. Alternatively, the substrate may be retained as a component of the circuit and the undesirable portions of the patterned conductive layer may be removed separately. These approaches allow using new patterning techniques as well as new materials for substrates and/or insulators.

A circuit substrate and a semiconductor package structure are provided. The circuit substrate includes a body and a via hole array. The via hole array includes via hole column units periodically arranged along a first direction. Each via hole column unit includes first to sixth via holes passing through the body and electrically connected to a capacitor. Any two adjacent via holes of the first to sixth via holes transmit power and ground signals. The sixth via hole of one of the via hole column units is adjacent to the first via hole of another one of the via hole column units, which is adjacent to the one of the via hole column units. The sixth via hole of one of the via hole column units and the first via hole of another one of the via hole column units transmit power and ground signals.

A circuit substrate and a semiconductor package structure are provided. The circuit substrate includes a body and a via hole array. The via hole array includes via hole column units periodically arranged along a first direction. Each via hole column unit includes first to sixth via holes passing through the body and electrically connected to a capacitor. Any two adjacent via holes of the first to sixth via holes transmit power and ground signals. The sixth via hole of one of the via hole column units is adjacent to the first via hole of another one of the via hole column units, which is adjacent to the one of the via hole column units. The sixth via hole of one of the via hole column units and the first via hole of another one of the via hole column units transmit power and ground signals.

A circuit substrate and a semiconductor package structure are provided. The circuit substrate includes a body and a via hole array. The via hole array includes via hole column units periodically arranged along a first direction. Each via hole column unit includes first to sixth via holes passing through the body and electrically connected to a capacitor. Any two adjacent via holes of the first to sixth via holes transmit power and ground signals. The sixth via hole of one of the via hole column units is adjacent to the first via hole of another one of the via hole column units, which is adjacent to the one of the via hole column units. The sixth via hole of one of the via hole column units and the first via hole of another one of the via hole column units transmit power and ground signals.

A method of forming a flexible interconnect circuit is described. A method may involve laminating a substrate to a conductive layer followed by patterning the conductive layer. This patterning operation forms individual conductive portions, which may be also referred to as traces or conductive islands. The substrate supports these portions relative to each other during and after patterning. After patterning, an insulator may be laminated to the exposed surface of the patterned conductive layer. At this point, the conductive layer portions are also supported by the insulator, and the substrate may optionally be removed, e.g., together with undesirable portions of the conductive layer. Alternatively, the substrate may be retained as a component of the circuit and the undesirable portions of the patterned conductive layer may be removed separately. These approaches allow using new patterning techniques as well as new materials for substrates and/or insulators.

High-speed interconnects for printed circuit boards and methods for forming the high-speed interconnects are described. A high-speed interconnect may comprise a region of a conductive film having a reduced surface roughness and one or more regions that have been treated for improved bonding with an adjacent insulating layer. Regions of reduced roughness may be used to carry high data rate signals within PCBs. Regions treated for bonding may include a roughened surface, adhesion-promoting chemical treatment, and/or material deposited to improve wettability of the surface and/or adhesion to a cured insulator.

A step of forming bump pads on the surface of the substrate corresponding to the cavity region, and covering the whole surface with a second insulating layer, forming a copper barrier on the surface of a second insulating layer corresponding to the cavity region for protection of the second insulating layer, forming a third insulating layer, and forming a copper layer for electrical circuit. A mask is formed on the copper later of the external circuit so that only the cavity region is exposed. The cavity is formed by laser-drilling only the surface-exposed area of the third insulating layer. The bottom copper layer protects the second insulating layer and bump pads underneath from laser damages. The copper barrier is removed by chemical etch after the laser drill. The second insulating layer with the bottom surface exposed will be removed via sand blast process, exposing the bump pads fabricated.