A packaged electronic die having a micro-cavity and a method for forming a packaged electronic die. The packaged electronic die includes a photoresist frame secured to the electronic die and extending completely around the device. The photoresist frame is further secured to a first major surface of a substrate so as to form an enclosure around the device. Encapsulant material extends over the electronic die and around the sides of the electronic die. The encapsulant material is in contact with the first major surface of the substrate around the entire periphery of the electronic die so as to form a seal around the electronic die.

Certain embodiments of the present disclosure provide a method for soldering a chip onto a surface. The method generally includes forming a bonding pad on the surface on which the chip is to be soldered, wherein the bonding pad is surrounded, at least in part, by dielectric material. The method may also include treating the dielectric material to render the dielectric material superomniphobic, and soldering the chip onto the bonding pad.

A semiconductor chip including a semiconductor substrate having a first surface and a second surface and having an active layer in a region adjacent to the first surface, a first through electrode penetrating at least a portion of the semiconductor substrate and connected to the active layer, a second through electrode located at a greater radial location from the center of the semiconductor substrate than the first through electrode, penetrating at least a portion of the semiconductor substrate, and connected to the active layer. The semiconductor chip also including a first chip connection pad having a first height and a first width, located on the second surface of the semiconductor substrate, and connected to the first through electrode, and a second chip connection pad having a second height greater than the first height and a second width greater than the first width, located on the second surface of the semiconductor substrate, and connected to the second through electrode.

The present disclosure discloses a semiconductor device structure with an air gap for reducing capacitive coupling and a method for forming the semiconductor device structure. The semiconductor device structure includes a first conductive pad over a first semiconductor substrate, and a first conductive structure over the first conductive pad. The semiconductor device structure also includes a second conductive structure over the first conductive structure, and a second conductive pad over the second conductive structure. The second conductive pad is electrically connected to the first conductive pad through the first and the second conductive structures. The semiconductor device structure further includes a second semiconductor substrate over the second conductive pad, a first passivation layer between the first and the second semiconductor substrates and covering the first conductive structure, and a second passivation layer between the first passivation layer and the second semiconductor substrate. The first and the second passivation layers surround the second conductive structure, and a first air gap is enclosed by the first and the second passivation layers.

A semiconductor chip including a semiconductor substrate having a first surface and a second surface and having an active layer in a region adjacent to the first surface, a first through electrode penetrating at least a portion of the semiconductor substrate and connected to the active layer, a second through electrode located at a greater radial location from the center of the semiconductor substrate than the first through electrode, penetrating at least a portion of the semiconductor substrate, and connected to the active layer. The semiconductor chip also including a first chip connection pad having a first height and a first width, located on the second surface of the semiconductor substrate, and connected to the first through electrode, and a second chip connection pad having a second height greater than the first height and a second width greater than the first width, located on the second surface of the semiconductor substrate, and connected to the second through electrode.

A semiconductor device and a method of manufacturing the same are provided. The semiconductor device includes a substrate and a metal holder. The substrate includes at least one bonding pad disposed adjacent to its surface and the metal holder is disposed adjacent to the bonding pad.

A method includes placing a first package component and a second package component over a carrier. The first conductive pillars of the first package component and second conductive pillars of the second package component face the carrier. The method further includes encapsulating the first package component and the second package component in an encapsulating material, de-bonding the first package component and the second package component from the carrier, planarizing the first conductive pillars, the second conductive pillars, and the encapsulating material, and forming redistribution lines to electrically couple to the first conductive pillars and the second conductive pillars.

The present application provides a semiconductor device. The semiconductor device includes a bonding pad disposed over a semiconductor substrate; a first spacer disposed over a top surface of the bonding pad; a second spacer disposed over a sidewall of the bonding pad; a dielectric layer between the bonding pad and the semiconductor substrate. The dielectric layer includes silicon-rich oxide; and a conductive bump disposed over the first passivation layer. The conductive bump is electrically connected to a source/drain (S/D) region in the semiconductor substrate through the bonding pad. The semiconductor device also includes a dielectric liner disposed between the first spacer and the bonding pad; and a first passivation layer covering the second spacer, wherein the dielectric liner is L-shaped, and the first spacer is separated from the bonding pad by the dielectric liner.

An integrated circuit (IC) package product, e.g., system-on-chip (SoC) or system-in-package (SiP) product, may include at least one integrated inductor having a core magnetic field (B field) that extends parallel to the substrate major plane of at least one die or chiplet included in or mounted to the product, which may reduce the eddy currents within each die/chiplet substrate, and thereby reduce energy loss of the indictor. The IC package product may include a horizontally-extending IC package substrate, a horizontally-extending die mount base arranged on the IC package substrate, at least one die mounted to the die mount base in a vertical orientation, and an integrated inductor having a B field extending in a vertical direction parallel to the silicon substrate of each vertically-mounted die, thereby providing a reduced substrate loss in the integrated inductor, which provides an increased quality factor (Q) of the inductor.

A method of manufacturing a three-dimensional semiconductor device includes forming a bi-layer sacrificial stack on a top wafer and a bottom wafer each including a series of interconnects in a dielectric substrate. The bi-layer sacrificial stack includes a second sacrificial layer on a first sacrificial layer. The method also includes selectively etching the second sacrificial layers to form a first pattern of projections on the top wafer and a second pattern of projections on the bottom wafer. The first pattern of projections is configured to mesh with the second pattern of projections. The method also includes positioning the top wafer on the bottom wafer and releasing the top wafer such that engagement between the first pattern of projections and the second pattern of projections self-aligns the plurality of interconnects of the top wafer with the plurality of interconnects of the bottom wafer within a misalignment error.