A die placement and coupling apparatus may include a die bonding attachment. The die placement and coupling apparatus may include a compliant head unit that may be adapted to optionally couple with a semiconductor die. The compliant head unit may include a die attach surface that may include a layer of compliant material. The layer of compliant material may be coupled to the compliant head unit. The die attach surface may be adapted to mate with the semiconductor die when the semiconductor die is coupled with the compliant head unit. The layer of compliant material may be adapted to yield in response to an applied force. The die placement and coupling apparatus may include a vacuum port in communication with the die attach surface. The port may be adapted to have a vacuum applied to the port, and the vacuum temporarily holds the semiconductor die to the die attach surface.

A method of manufacturing a semiconductor package and a semiconductor package in which positional alignment between a wafer and a substrate until the wafer is mounted and packaged on the substrate is achieved accurately. A wafer is mounted on a package substrate by using first alignment marks and D-cuts as benchmarks, and then a mold resin layer is formed on the wafer in a state in which the first alignment mark is exposed. A part of the mold resin layer is removed by using the D-cuts exposed from the mold resin layer as benchmarks, so that the first alignment marks can be visually recognized. A second alignment marks are formed on the mold resin layer by using the first alignment marks as benchmarks. A Cu redistribution layer to be conducted to a pad portion is formed on a mold resin layer by using the second alignment marks as benchmarks.

The disclosure is provided with: a temporary crimping step in which one or more semiconductor chips 10 are sequentially laminated while being temporarily crimped in each of two or more locations on a substrate 30 to thereby form chip stacks ST in a temporarily crimped state; and a permanent crimping step in which the top surfaces of all of the chip stacks ST formed in the temporarily crimped state are sequentially heated, pressurized, and permanently crimped. Furthermore, a specifying step is provided prior to the temporary crimping step for specifying a separation distance Dd which is the distance from the chip stacks ST under permanent crimping to a location at which the temperature of the substrate 30, the temperature having been raised by heating for the permanent crimping, becomes less than or equal to a prescribed permissible temperature Td, and in the temporary crimping step, the chip stacks ST in the temporarily crimped state are formed separated from each other by the separation distance Dd or more.

An alignment method for aligning two substrates to be stacked, comprising measuring a position of a mark selected from plurality of marks disposed on at least one substrate of the two substrates and aligning the two substrates based on the position of the measured mark, wherein the mark to be measured is selected based on information relating to distortion of the at least one substrate. The mark may be a mark disposed in a region having a smaller distortion amount of the at least one substrate than a threshold. The mark may be a mark disposed in a region having a higher reproducibility of distortion that occurs in the at least one substrate than a threshold.

In an embodiment, a device includes: a bottom integrated circuit die having a first front side and a first back side; a top integrated circuit die having a second front side and a second back side, the second back side being bonded to the first front side, the top integrated circuit die being free from through substrate vias (TSVs); a dielectric layer surrounding the top integrated circuit die, the dielectric layer being disposed on the first front side, the dielectric layer and the bottom integrated circuit die being laterally coterminous; and a through via extending through the dielectric layer, the through via being electrically coupled to the bottom integrated circuit die, surfaces of the through via, the dielectric layer, and the top integrated circuit die being planar.

A substrate with built-in component includes: a first wiring layer having at least one reference pattern; a first insulating layer formed on the first wiring layer; and an electronic component mounted, in a cavity formed in the first insulating layer, on the first wiring layer, wherein the at least one reference pattern includes at least one first portion crossing a side surface of the electronic component in plan view, and at least one second portion crossing a side surface of the cavity in plan view.

A wafer to wafer bonding method includes performing a plasma process on a bonding surface of a first wafer, pressurizing the first wafer after performing the plasma process on the bonding surface of the first wafer, and bonding the first wafer to a second wafer. The plasma process has different plasma densities along a circumferential direction about a center of the first wafer. A middle portion of the first wafer protrudes after pressurizing the first wafer. The first wafer is bonded to the second wafer by gradually joining the first wafer to the second wafer from the middle portion of the first wafer to a peripheral region of the first wafer.

Panel level packaging (PLP) with high accuracy and high scalability is disclosed. The PLP employs an alignment carrier with a low coefficient of expansion which is configured with die regions having local die alignment marks. For example, local die alignment marks are provided for each die attach region. Depending on the size of the panel, it may be segmented into blocks, each with die regions with local die alignment marks. In addition, a block includes an alignment die region configured for attaching an alignment die. Linear and non-linear positional errors are reduced due to local die alignment marks and alignment dies. The use of local die alignment marks and alignment dies results in increase yields as well as scaling, thereby improving throughput and decreasing overall costs.

A package manufacturing having a semiconductor substrate, a bonding layer, at least one semiconductor device, a redistribution circuit structure and an insulating encapsulation. The bonding layer is disposed on the semiconductor substrate. The semiconductor device is disposed on and in contact with a portion of the bonding layer, wherein the bonding layer is located between the semiconductor substrate and the semiconductor device and adheres the semiconductor device onto the semiconductor substrate. The redistribution circuit structure is disposed on and electrically connected to the semiconductor device, wherein the semiconductor device is located between the redistribution circuit structure and the bonding layer. The insulating encapsulation wraps a sidewall of the semiconductor device, wherein a sidewall of the bonding layer is aligned with a sidewall of the insulating encapsulation and a sidewall of the redistribution circuit structure.

According to one embodiment, a controller is configured to calculate a matching rate of grid shapes between each semiconductor wafer of a first semiconductor wafer group and each semiconductor wafer of a second semiconductor wafer group, and generate pairing information, into which combinations of semiconductor wafers used in calculation of matching rates are registered when the matching rates fall within a predetermined range. Further, the controller is configured to select a first semiconductor wafer to be held by a first semiconductor wafer holder from the first semiconductor wafer group, and select a second semiconductor wafer from semiconductor wafers of the second semiconductor wafer group, which are paired with the first semiconductor wafer, with reference to the pairing information.