A method includes forming a metal bump on a top surface of a first package component, forming a solder region on a top surface of the metal bump, forming a protection layer extending on a sidewall of the metal bump, reflowing the solder region to bond the first package component to a second package component, and dispensing an underfill between the first package component and the second package component. The underfill is in contact with the protection layer.

A semiconductor memory device may include a plurality of memory cells wherein identifiers may be provided to the memory cells. The semiconductor memory device may include a first circuit, a second circuit and a power control circuit. The first circuit may include a first power terminal and a second power terminal. The second circuit may include a third terminal and a fourth terminal. The power control circuit may be configured to apply a first power voltage or a ground voltage to the first power terminal and to apply the ground voltage to the second power terminal based on the identifiers.

Semiconductor device packages and method are provided. A semiconductor device package according to the present disclosure includes a substrate including a first region, a passive device disposed over the first region of the substrate, a contact pad disposed over the passive device, a passivation layer disposed over the contact pad, a recess through the passivation layer, and an under-bump metallization (UBM) layer. The recess exposes the contact pad and the UBM layer includes an upper portion disposed over the passivation layer and a lower portion disposed over a sidewall of the recess. A projection of the upper portion of the UBM layer along a direction perpendicular to the substrate falls within an area of the contact pad.

Disclosed are semiconductor packages and thermal management methods thereof. The semiconductor package includes an upper semiconductor chip; and a lower semiconductor chip connected via a plurality of through electrodes to the upper semiconductor chip. The lower semiconductor chip may include at least one temperature sensor configured to sense a temperature of the upper semiconductor chip, a power control unit connected to the at least one temperature sensor, a power switching element connected to at least a first one of the plurality of through electrodes, and a clock control element connected to at least a second one of the plurality of through electrodes.

A semiconductor package includes a first semiconductor chip; a lower dam structure disposed on an edge of a top surface of the first semiconductor substrate; a second semiconductor chip, which is mounted on the first semiconductor chip; an upper dam structure disposed on an edge of the bottom surface of the second semiconductor substrate; a chip connecting terminal disposed between the first semiconductor chip and the second semiconductor chip and connecting the first semiconductor chip to the second semiconductor chip; and an adhesive layer disposed between the first semiconductor chip and the second semiconductor chip and surrounding the chip connecting terminal.

A semiconductor package includes a substrate, a semiconductor die, a lid, and an adhesive layer. The semiconductor die is attached to the substrate. The lid is over the semiconductor die and the substrate. The adhesive layer is sandwiched between the lid and the semiconductor die. The adhesive layer includes a metallic thermal interface material (TIM) layer and a polymeric TIM layer adjacent to the metallic TIM layer. The polymeric TIM layer is located on corners of the semiconductor die from a top view.

A die stack includes: a first die including a first semiconductor substrate; a second die including a second semiconductor substrate; a bonding dielectric structure including a bonding polymer and that bonds the first die and the second die; a bonding interconnect structure that extends through the bonding dielectric structure to bond and electrically connect the first die and the second die; and a bonding dummy pattern that extends through the bonding dielectric structure to bond the first die and the second die. The bonding dummy pattern is electrically conductive and is electrically floated.

The present disclosure describes a semiconductor structure having bonded wafers with storage layers and a method to bond wafers with storage layers. The semiconductor structure includes a first wafer including a first storage layer with carbon, a second wafer including a second storage layer with carbon, and a bonding layer interposed between the first and second wafers and in contact with the first and second storage layers.

A method of manufacturing a device is provided. The method includes forming a first cavity in a first substrate with the first cavity having a first depth. A second cavity is formed in a second substrate with the second cavity having a second depth. The first cavity and the second cavity are aligned with each other. The first substrate is affixed to the second substrate to form a waveguide substrate having a hollow waveguide with a first dimension substantially equal to the first depth plus the second depth. A conductive layer is formed on the sidewalls of the hollow waveguide. The waveguide substrate is placed over a packaged semiconductor device, the hollow waveguide aligned with a launcher of the packaged semiconductor device.

A semiconductor device includes a substrate includes a first layer and a second layer over the first layer, a bump disposed over the second layer, a molding disposed over the second layer and surrounding the bump, and a retainer disposed over the second layer, wherein the retainer is disposed between the molding and a periphery of the substrate. Further, a method of manufacturing a semiconductor device includes providing a substrate, disposing several bumps on the substrate, disposing a retainer on the substrate and surrounding the bumps, and disposing a molding between the bumps and the retainer.