A method and an apparatus for forming an electronic device is provided. The method comprises: providing a substrate; disposing at least one electronic component on the substrate via a solder paste; applying microwave radiation to the substrate to reflow the solder paste; applying a vacuum pressure to the substrate to remove voids formed within the solder paste during the reflowing of the solder paste; solidifying the solder paste into solder bumps between the substrate and the at least one electronic component.

A selective stencil mask and a stencil printing method are provided. The stencil mask is for printing a fluid material onto a substrate, and comprises: a stencil member comprising: at least one printing region each having an array of apertures that allow the fluid material to flow therethrough and deposit onto the substrate; and a blocking region configured to prevent the fluid material from flowing therethrough; and a supporting member attached to the stencil member and configured to, when the stencil mask is placed on the substrate, contact the substrate and create a gap between the stencil member and the substrate.

A semiconductor package is provided. The semiconductor package includes a semiconductor device bonded to a base through a first conductive structure. The semiconductor device includes a carrier substrate including a conductive trace. A portion of the conductive trace is elongated. The semiconductor device also includes a second conductive structure above the carrier substrate. A portion of the second conductive structure is in contact with the portion of the conductive trace. The semiconductor device further includes a semiconductor body mounted above the conductive trace. The semiconductor body is connected to the second conductive structure.

In an embodiment, a device includes: a substrate having a first side and a second side opposite the first side; an interconnect structure adjacent the first side of the substrate; and an integrated circuit device attached to the interconnect structure; a through via extending from the first side of the substrate to the second side of the substrate, the through via being electrically connected to the integrated circuit device; an under bump metallurgy (UBM) adjacent the second side of the substrate and contacting the through via; a conductive bump on the UBM, the conductive bump and the UBM being a continuous conductive material, the conductive bump laterally offset from the through via; and an underfill surrounding the UBM and the conductive bump.

An apparatus comprising a first substrate, a dam structure disposed on a first side of the first substrate, and an integrated circuit (IC) memory chip coupled to the first side of the first substrate by a plurality of first conductive members. A second substrate is coupled to a second side of the first substrate by a plurality of second conductive members. A lid coupled to the second substrate encloses the IC memory chip and the first substrate. A thermal interface material (TIM) is coupled between the lid and the dam structure.

An electronic device structure having a shielding structure includes a substrate with an electronic component electrically connected to the substrate. The shielding structure includes conductive spaced-apart pillars that have proximate ends connected to the substrate and distal ends spaced apart from the substrate, and that are laterally spaced apart from the first electronic component. In one embodiment, the conductive pillars are conductive wires. A package body encapsulates the electronic component and the conductive pillars. In one embodiment, the shielding structure further includes a shielding layer disposed adjacent to the package body, which is electrically connected to the conductive pillars. In one embodiment, the electrical connection is made through the package body. In another embodiment, the electrical connection is made through the substrate.

A device package includes a first die directly bonded to a second die at an interface, wherein the interface comprises a conductor-to-conductor bond. The device package further includes an encapsulant surrounding the first die and the second die and a plurality of through vias extending through the encapsulant. The plurality of through vias are disposed adjacent the first die and the second die. The device package further includes a plurality of thermal vias extending through the encapsulant and a redistribution structure electrically connected to the first die, the second die, and the plurality of through vias. The plurality of thermal vias is disposed on a surface of the second die and adjacent the first die.

A method of forming one or more semiconductor packages includes mounting one or more semiconductor dies on the metal strip such that the one or more semiconductor dies are in a flip chip arrangement whereby terminals of the one or more semiconductor dies face the upper surface of the metal strip, forming an electrically insulating encapsulant material on the upper surface of the metal strip that encapsulates the one or more semiconductor dies, and forming package terminals that are electrically connected with the terminals of the one or more semiconductor dies, wherein the package terminals are formed from the metal strip or from metal that is deposited after removing the metal strip.

A stacked transistor arrangement and process of manufacture thereof are provided. Switched electrodes of first and second transistor chips are accessible on opposite sides of the first and second transistor chips. The first and second transistor chips are stacked one on top of the other. Switched electrodes of adjacent sides of the transistor chips are coupled together by a conductive layer positioned between the first and second transistor chips. Switched electrodes on sides of the first transistor chip and the second transistor chip that are opposite the adjacent sides are coupled to a lead frame by bond wires or solder bumps.

An electronic chip including a semiconductor substrate in and on which an integrated circuit is formed at least one connection metallization of the integrated circuit formed on the side of a front face of the semiconductor substrate and a first passivation layer covering the front face of the semiconductor substrate, the first passivation layer including openings in line with the connection metallization of the integrated circuit The chip having a second passivation layer covering the side flanks of the semiconductor substrate, the second passivation layer being made of a parylene, and the first passivation layer and the second passivation layer being in contact with each other on the side of the front face of the semiconductor substrate. Methods of making a device are also provided.