A component comprises at least one support on which is fixed at least one electronic circuit, for example a circuit of MMIC type, one or more layers of organic materials stacked on the support according to a technique of printed circuit type and forming a pre-existing cavity containing the electronic circuit, the cavity being filled with a material of low permeability to water vapor such as LCP.

A method includes adhering a voltage regulator die over a carrier through a die-attach film, with the die-attach film being in the voltage regulator die and encircles metal pillars of the voltage regulator die, encapsulating the voltage regulator die in an encapsulating material, and planarizing the encapsulating material. A back portion of the voltage regulator die is removed to expose a through-via in a semiconductor substrate of the voltage regulator die. The method further includes forming first redistribution lines over the encapsulating material and electrically coupled to the through-via, replacing the die-attach film with a dielectric material, forming second redistribution lines on an opposite side of encapsulating material than the first redistribution lines, and bonding an additional device die to the second redistribution lines. The voltage regulator die is electrically coupled to the additional device die.

A device for applying underfill material into a space between a substrate and a semiconductor chip is provided. The device includes a frame housing configured to cover at least an outer edge area of the semiconductor chip that is bonded to the substrate. The device also includes a sealant attached to the frame housing and configured to contact the outer edge area of the semiconductor chip. The device also includes an outlet made on the frame housing for evacuating the space; and an inlet made on the frame housing for injecting the underfill material to the space.

A device for applying underfill material into a space between a substrate and a semiconductor chip is provided. The device includes a frame housing configured to cover at least an outer edge area of the semiconductor chip that is bonded to the substrate. The device also includes a sealant attached to the frame housing and configured to contact the outer edge area of the semiconductor chip. The device also includes an outlet made on the frame housing for evacuating the space; and an inlet made on the frame housing for injecting the underfill material to the space.

Proximity coupling interconnect packaging systems and methods. A semiconductor package assembly comprises a substrate, a first semiconductor die disposed adjacent the substrate, and a second semiconductor die stacked over the first semiconductor die. There is at least one proximity coupling interconnect between the first semiconductor die and the second semiconductor die, the proximity coupling interconnect comprising a first conductive pad on the first coupling face on the first semiconductor die and a second conductive pad on a second coupling face of the second semiconductor die, the second conductive pad spaced apart from the first conductive pad by a gap distance and aligned with the first conductive pad. An electrical connector is positioned laterally apart from the proximity coupling interconnect and extends between the second semiconductor die and the substrate, the position of the electrical connector defining the alignment of the first conductive pad and the second conductive pad.

Proximity coupling interconnect packaging systems and methods. A semiconductor package assembly comprises a substrate, a first semiconductor die disposed adjacent the substrate, and a second semiconductor die stacked over the first semiconductor die. There is at least one proximity coupling interconnect between the first semiconductor die and the second semiconductor die, the proximity coupling interconnect comprising a first conductive pad on the first coupling face on the first semiconductor die and a second conductive pad on a second coupling face of the second semiconductor die, the second conductive pad spaced apart from the first conductive pad by a gap distance and aligned with the first conductive pad. An electrical connector is positioned laterally apart from the proximity coupling interconnect and extends between the second semiconductor die and the substrate, the position of the electrical connector defining the alignment of the first conductive pad and the second conductive pad.

An electronic element mounting substrate includes a substrate including, on a first upper surface, a mounting region in which an electronic element is mounted, a frame body located on the first upper surface of the substrate and surrounding the mounting region, a channel extending through the frame body outward from an inner wall of the frame body, and an electrode pad located on the first upper surface of the substrate or an inner surface of the frame body. The channel is located above or below the electrode pad.

A method includes forming a first electrically conductive layer on a first side of a dielectric insulation layer, forming a structured mask layer on a side of the first electrically conductive layer that faces away from the dielectric insulation layer, forming at least one trench in the first electrically conductive layer, said at least one trench extending through the entire first electrically conductive layer to the dielectric insulation layer, forming a coating which covers at least the bottom and the side walls of the at least one trench, and removing the mask layer after the coating has been formed.

A method includes forming a first electrically conductive layer on a first side of a dielectric insulation layer, forming a structured mask layer on a side of the first electrically conductive layer that faces away from the dielectric insulation layer, forming at least one trench in the first electrically conductive layer, said at least one trench extending through the entire first electrically conductive layer to the dielectric insulation layer, forming a coating which covers at least the bottom and the side walls of the at least one trench, and removing the mask layer after the coating has been formed.

A microelectronic device package may include one or more semiconductor dice coupled to a substrate. The microelectronic device package may further include a lid coupled to the substrate, the lid defining a volume over and around the one or more semiconductor die. The microelectronic device package may further include a thermally conductive dielectric filler material substantially filling the volume defined around the semiconductor die.