This member connection method includes a printing step. In the printing step, a coating film-formed region in which the coating film is formed, and a coating film non-formed region in which the coating film is not formed are formed in the print pattern, and the coating film-formed region is divided into a plurality of concentric regions and a plurality of radial regions by means of a plurality of line-shaped regions provided so as to connect various points, which are separated apart from one another in the marginal part of the connection region.

This member connection method includes a printing step. In the printing step, a coating film-formed region in which the coating film is formed, and a coating film non-formed region in which the coating film is not formed are formed in the print pattern, and the coating film-formed region is divided into a plurality of concentric regions and a plurality of radial regions by means of a plurality of line-shaped regions provided so as to connect various points, which are separated apart from one another in the marginal part of the connection region.

A package includes an integrated circuit that includes at least one active area and at least one secondary device area, a support configured to support the integrated circuit, and a die attach material. The integrated circuit being mounted on the support using the die attach material and the die attach material including at least one channel configured to allow gases generated during curing of the die attach material to be released from the die attach material.

A package includes an integrated circuit that includes at least one active area and at least one secondary device area, a support configured to support the integrated circuit, and a die attach material. The integrated circuit being mounted on the support using the die attach material and the die attach material including at least one channel configured to allow gases generated during curing of the die attach material to be released from the die attach material.

A packaged semiconductor device and a method and apparatus for forming the same are disclosed. In an embodiment, a method includes bonding a device die to a first surface of a substrate; depositing an adhesive on the first surface of the substrate; depositing a thermal interface material on a surface of the device die opposite the substrate; placing a lid over the device die and the substrate, the lid contacting the adhesive and the thermal interface material; applying a clamping force to the lid and the substrate; and while applying the clamping force, curing the adhesive and the thermal interface material.

A packaged semiconductor device and a method and apparatus for forming the same are disclosed. In an embodiment, a method includes bonding a device die to a first surface of a substrate; depositing an adhesive on the first surface of the substrate; depositing a thermal interface material on a surface of the device die opposite the substrate; placing a lid over the device die and the substrate, the lid contacting the adhesive and the thermal interface material; applying a clamping force to the lid and the substrate; and while applying the clamping force, curing the adhesive and the thermal interface material.

A semiconductor die stack includes a base die and core dies stacked over the base die. Each of the base die and the core dies include a semiconductor substrate, a front side passivation layer formed over a front side of the semiconductor substrate, a back side passivation layer over a back side of the semiconductor substrate, a through-via vertically penetrating the semiconductor substrate and the front side passivation layer, and a bump, a support pattern, and a bonding insulating layer formed over the front side passivation layer. Top surfaces of the bump, the support pattern, and the bonding insulating layer are co-planar. The bump is vertically aligned with the through-via. The support pattern is spaced apart from the through-via and the bump. The support pattern includes a plurality of first bars that extend in parallel with each other in a first direction and a plurality of second bars that extend in parallel with each other in a second direction.

A semiconductor device package includes a substrate, a silicon (Si) or silicon carbide (SiC) semiconductor die, and a metal layer on a surface of the semiconductor die. The metal layer includes a bonding surface that is attached to a surface of the substrate by a die attach material. The bonding surface includes opposing edges that extend along a perimeter of the semiconductor die, and one or more non-orthogonal corners that are configured to reduce stress at an interface between the bonding surface and the die attach material. Related devices and fabrication methods are also discussed.

An apparatus for manufacturing packaged semiconductor devices includes a lower plate having package platforms and clamp guide pins to align an upper plate with the lower plate, and a boat tray having windows configured to receive package devices, and a plurality of upper plates configured to be aligned to respective windows and respective package platforms. Clamping force can be applied by fasteners configured to generate a downward force upon the upper plate. Package devices on the platforms are thus subjected to a clamping force. Load cells measure the clamping force so adjustments can be made.

An apparatus for manufacturing packaged semiconductor devices includes a lower plate having package platforms and clamp guide pins to align an upper plate with the lower plate, and a boat tray having windows configured to receive package devices, and a plurality of upper plates configured to be aligned to respective windows and respective package platforms. Clamping force can be applied by fasteners configured to generate a downward force upon the upper plate. Package devices on the platforms are thus subjected to a clamping force. Load cells measure the clamping force so adjustments can be made.