A device and method for fabrication thereof is provided which results in corrosion resistance of metal flanges of a semiconductor package, such as a quad flat no-lead package (QFN). Using metal electroplating (such as electroplating of nickel (Ni) or nickel alloys on copper flanges of the QFN package), corrosion resistance for the flanges is provided using a process that allows an electric current to reach the entire backside of a substrate to permit electroplating. In addition, the method may be used to directly connect a semiconductor die to the metal substrate of the package.

A device and method for fabrication thereof is provided which results in corrosion resistance of metal flanges (802) of a semiconductor package, such as a quad flat no-lead package (QFN). Using metal electroplating (such as electroplating of nickel (Ni) or nickel alloys on copper flanges of the QFN package), corrosion resistance for the flanges is provided using a process that allows an electric current to reach the entire backside of a substrate (102) to permit electroplating. In addition, the method may be used to directly connect a semiconductor die (202) to the metal substrate (102) of the package.

In one example, a semiconductor device can comprise a substrate, a device stack, first and second internal interconnects, and an encapsulant. The substrate can comprise a first and second substrate sides opposite each other, a substrate outer sidewall between the first substrate side and the second substrate side, and a substrate inner sidewall defining a cavity between the first substrate side and the second substrate side. The device stack can be in the cavity and can comprise a first electronic device, and a second electronic device stacked on the first electronic device. The first internal interconnect can be coupled to the substrate and the device stack. The encapsulant can cover the substrate inner sidewall and the device stack and can fill the cavity. Other examples and related methods are disclosed herein.

An integrated semiconductor device and a method for manufacturing the integrated semiconductor device are disclosed. In an embodiment an integrated semiconductor device includes a supporting substrate having a first substrate face and a second substrate face opposite to the first substrate face, a semiconductor die having a first die face coupled to the first substrate face of the supporting substrate, the first die face including first die contact pads, wherein the supporting substrate has at least one through opening, wherein the first die contact pads are arranged facing the through opening, and wherein the supporting substrate comprises first substrate contact pads connected by first bonding wires to the respective first die contact pads through the through opening.

A floating die package including a cavity formed through sublimation of a sacrificial die encapsulant and sublimation or separation of die attach materials after molding assembly. A pinhole vent in the molding structure is provided as a sublimation path to allow gases to escape, whereby the die or die stack is released from the substrate and suspended in the cavity by the bond wires only.

Devices and methods are disclosed, related to shielding and packaging of radio-frequency (RF) devices on substrates. In some embodiments, a method for providing electro-magnetic interference shielding for a radio-frequency module can include applying a metal-based covering over a portion of a lead-frame package, the package having a plurality of pins with at least one pin exposed from overmold compound and in contact with the metal-based covering. The method can also include mounting the lead-frame package on a substrate. The method can further include connecting the metal-based covering to a ground plane of the substrate.

An apparatus includes a microelectromechanical system (MEMS) die having a first surface and an opposing second surface. The MEMS die includes a surface-mounted resonator on the first surface and includes a first inductor. The apparatus also includes first and second dies. The first die has a third surface and an opposing fourth surface. The first die is coupled to the MEMS die such that the third surface of the first die faces the first surface of the MEMS die. The first and second surfaces are spaced apart. The first die includes an oscillator circuit and a second inductor. The oscillator circuit is coupled to the second inductor. The second inductor is inductively coupled to the first inductor. The second die is electrically coupled to the first die.

Apparatuses relating to a microelectronic package are disclosed. In one such apparatus, a substrate has first contacts on an upper surface thereof. A microelectronic die has a lower surface facing the upper surface of the substrate and having second contacts on an upper surface of the microelectronic die. Wire bonds have bases joined to the first contacts and have edge surfaces between the bases and corresponding end surfaces. A first portion of the wire bonds are interconnected between a first portion of the first contacts and the second contacts. The end surfaces of a second portion of the wire bonds are above the upper surface of the microelectronic die. A dielectric layer is above the upper surface of the substrate and between the wire bonds. The second portion of the wire bonds have uppermost portions thereof bent over to be parallel with an upper surface of the dielectric layer.

A stack package includes a package substrate and a fan-out sub-package mounted on the package substrate using first and second connection bumps. The fan-out sub-package includes a first semiconductor die and redistributed line (RDL) patterns. Second semiconductor dies are stacked on the package substrate to provide a first step structure, and third semiconductor dies are stacked on the second semiconductor dies to provide a second step structure. The second and third semiconductor dies are connected to the package substrate by bonding wires.

A manufacturing method of a package structure is described. The method includes at least the following steps. A carrier is provided. A semiconductor die and a sacrificial structure are disposed on the carrier. The semiconductor die is electrically connected to the bonding pads on the sacrificial structure through a plurality of conductive wires. As encapsulant is formed on the carrier to encapsulate the semiconductor die, the sacrificial structure and the conductive wires. The carrier is debonded, and at least a portion of the sacrificial structure is removed through a thinning process. A redistribution layer is formed on the semiconductor die and the encapsulant. The redistribution layer is electrically connected to the semiconductor die through the conductive wires.