Abstract: Stacked semiconductor die assemblies with support members and associated systems and methods are disclosed herein. In one embodiment, a semiconductor die assembly can include a package substrate, a first semiconductor die attached to the package substrate, and a plurality of support members also attached to the package substrate. The plurality of support members can include a first support member and a second support member disposed at opposite sides of the first semiconductor die, and a second semiconductor die can be coupled to the support members such that at least a portion of the second semiconductor die is over the first semiconductor die.

Abstract: A semiconductor package having a package substrate including an upper surface, a controller, a first die stack, and a second die stack. The controller, the first die stack, and the second die stack are at the upper surface. The first die stack includes a first shingled sub-stack and a first reverse-shingled sub-stack. The first die stack also includes a first bridging chip between the first shingled and reverse-shingled sub-stacks. The second die stack similarly includes a second shingled sub-stack and a second reverse-shingled sub-stack. The second die stack also includes a second bridging chip bonded to the top of the second reverse-shingled sub-stack. At least a portion of a bottom semiconductor die of the first reverse-shingled sub-stack is vertically aligned with a semiconductor die of the second shingled sub-stack and a semiconductor die of the second reverse-shingled sub-stack.

Abstract: Semiconductor devices with three-dimensional trace matching features, and related systems and methods, are disclosed herein. In some embodiments, an exemplary semiconductor device includes at least one semiconductor die and a redistribution layer disposed over the at least one semiconductor die and extending across a longitudinal plane. The redistribution layer includes first and second traces each electrically coupled to the at least one semiconductor die. The first trace is disposed in a first travel path included in a first effective path length. The second trace is disposed in a second travel path different from the first travel path. The second the second travel path includes at least one segment at a non-right, non-zero angle such that the at least one segment is neither parallel nor perpendicular to the longitudinal plane. Further, the second travel path is included in a second effective path length equal to the first path length.

Abstract: A semiconductor package including a package substrate with an upper surface, a controller, and a die stack. The controller and the die stack are at the upper surface. The die stack includes a shingled sub-stack of semiconductor dies, a reverse-shingled sub-stack of semiconductor dies, and a bridging chip. The bridging chip is bonded between the shingled sub-stack and the reverse-shingled sub-stack, and has an internal trace. A first wire segment is bonded between the controller and a first end of the bridging chip, and a second wire segment is bonded between a second end of the bridging chip and each semiconductor die of the shingled sub-stack. The internal trace electrically couples the first and second wire segments. Additionally, a third wire segment is bonded between the controller and each semiconductor die of the reverse-shingled sub-stack.

Abstract: Stacked semiconductor die assemblies with die support members and associated systems and methods are disclosed herein. In one embodiment, a semiconductor die assembly can include a package substrate, a first semiconductor die attached to the package substrate, and a support member attached to the package substrate. The support member can be separated from the first semiconductor die, and a second semiconductor die can have one region coupled to the support member and another region coupled to the first semiconductor die.

Abstract: A semiconductor device includes a rigid flex circuit that has a first rigid region and a second rigid region that are electrically connected by a flexible portion. A first die is mounted to a first side of the first rigid region. A second die is mounted to a second side of the second rigid region. The first and second sides are on opposite sides of the rigid flex circuit. The flexible portion is bent to hold the first and second rigid regions in generally vertical alignment with each other.

Abstract: An apparatus includes a primary layer of a substrate. The apparatus includes a secondary layer of the substrate having a first open area that extends through the secondary layer to an inner layer of the substrate. The apparatus includes the inner layer of the substrate that is positioned between the primary layer and the secondary layer. The inner layer includes first component bond pads that are disposed on the inner layer and that are exposed via the first open area of the secondary layer.

Abstract: A semiconductor device assembly is provided. The assembly includes a substrate having an upper surface on which is disposed a first device contact, a keep-out region extending from a first side surface of the substrate to a second side surface of the substrate opposite the first, and at least one trace coupled to the first device contact and extending across the keep out region towards a third side surface of the substrate. The assembly further includes at least one semiconductor device disposed over the upper surface of the substrate and coupled to the first device contact. The keep-out region of the substrate is free from conductive structures other than the at least one trace.

Abstract: Semiconductor device assemblies having redistribution structures, and associated systems and methods, are disclosed herein. In some embodiments, a semiconductor device assembly includes a substrate, a controller, and an interposer. The substrate has a top surface and a bottom surface. A cavity extends below the top surface. The controller has a first pin-out pattern. The interposer has a top surface with the first pin-out pattern that is directly connected to the controller and a bottom surface that has a second pin-out pattern. The interposer interconnects the first and second pin-out patterns, and the interposer and the second pin-out pattern are configured to be directly attached to a surface of the substrate in the cavity.

Abstract: An apparatus includes a primary layer of a substrate that includes an open area that extends through the primary layer to an inner layer of the substrate. The apparatus includes a secondary layer of the substrate. The apparatus also includes the inner layer of the substrate that is positioned between the primary layer and the secondary layer. The inner layer includes component bond pads that are disposed on the inner layer and that are exposed via the open area of the primary layer.

Abstract: A semiconductor device includes a rigid flex circuit that has a first rigid region and a second rigid region that are electrically connected by a flexible portion. A first die is mounted to a first side of the first rigid region. A second die is mounted to a second side of the second rigid region. The first and second sides are on opposite sides of the rigid flex circuit. The flexible portion is bent to hold the first and second rigid regions in generally vertical alignment with each other.

Abstract: Semiconductor devices with controllers under stacks of semiconductor packages and associated systems and methods are disclosed herein. In one embodiment, a semiconductor device includes a package substrate, a controller attached to the package substrate, and at least two semiconductor packages disposed over the controller. Each semiconductor package includes a plurality of semiconductor dies. The semiconductor device further includes an encapsulant material encapsulating the controller and the at least two semiconductor packages.

Abstract: Semiconductor devices having three-dimensional bonding schemes and associated systems and methods are disclosed herein. In some embodiments, the semiconductor device includes a package substrate, a stack of semiconductor dies carried by the package substrate, and an interconnect module carried by the package substrate adjacent the stack of semiconductor dies. The stack of semiconductor dies can include a first die carried by the package substrate and a second die carried by the first die. Meanwhile, the interconnect module can include at least a first tier and a second tier. The first tier can be carried by and electrically coupled to the package substrate, and the second tier can be carried by and electrically coupled to the first tier. In turn, the second die can be electrically coupled to the second tier.

Abstract: Semiconductor devices including thermally conductive structures are disclosed herein. A heat transfer structure may be thermally coupled to a semiconductor device and directly attached to a signaling layer of a substrate. The heat transfer structure may be configured to remove thermal energy from the semiconductor device and transfer at least a portion of the removed thermal energy directly into the signaling layer for dissipation within the substrate, for transfer through the substrate and out of a corresponding apparatus, or a combination thereof.

Abstract: Substrates for semiconductor packages, including hybrid substrates for decoupling capacitors, and associated devices, systems, and methods are disclosed herein. In one embodiment, a substrate includes a first pair and a second pair of electrical contacts on a first surface of the substrate. The first pair of electrical contacts can be configured to receive a first surface-mount capacitor, and the second pair of electrical contacts can be configured to receive a second surface-mount capacitor. The first pair of electrical contacts can be spaced apart by a first space, and the second pair of electrical contacts can be spaced apart by a second space. The first and second spaces can correspond to corresponding to first and second distances between electrical contacts of the first and second surface-mount capacitors.

Abstract: Semiconductor devices having multiple substrates and die stacks, and associated systems and methods, are disclosed herein. In some embodiments, a semiconductor device includes a package substrate, and a first die stack mounted on the package substrate and including a plurality of first memory dies. The device can include a substrate mounted on the first die stack, the substrate including a plurality of routing elements. The device can also include a second die stack mounted on the substrate, the second die stack including a plurality of second memory dies. The device can further include a controller die mounted on the substrate. The controller die can be configured to communicate with the second die stack via the routing elements of the substrate. The device can include a mold material encapsulating the first die stack, the second die stack, the substrate, and the controller die.

Abstract: Substrates for semiconductor packages, including hybrid substrates for decoupling capacitors, and associated devices, systems, and methods are disclosed herein. In one embodiment, a substrate includes a first pair and a second pair of electrical contacts on a first surface of the substrate. The first pair of electrical contacts can be configured to receive a first surface-mount capacitor, and the second pair of electrical contacts can be configured to receive a second surface-mount capacitor. The first pair of electrical contacts can be spaced apart by a first space, and the second pair of electrical contacts can be spaced apart by a second space. The first and second spaces can correspond to first and second distances between electrical contacts of the first and second surface-mount capacitors.

Abstract: Substrates for semiconductor packages, including hybrid substrates for decoupling capacitors, and associated devices, systems, and methods are disclosed herein. In one embodiment, a substrate includes a first pair and a second of electrical contacts on a first surface of the substrate. The first pair of electrical contacts can be configured to receive a first surface-mount capacitor, and the second pair of electrical contacts can be configured to receive a second surface-mount capacitor. The first pair of electrical contacts can be spaced apart by a first space, and the second pair of electrical contacts can be spaced apart by a second space. The first and second spaces can correspond to corresponding to first and second distances between electrical contacts of first and second surface-mount capacitors.

Abstract: A semiconductor device includes a rigid flex circuit that has a first rigid region and a second rigid region that are electrically connected by a flexible portion. A first die is mounted to a first side of the first rigid region. A second die is mounted to a second side of the second rigid region. The first and second sides are on opposite sides of the rigid flex circuit. The flexible portion is bent to hold the first and second rigid regions in generally vertical alignment with each other.

Abstract: Semiconductor devices having multiple substrates and die stacks, and associated systems and methods, are disclosed herein. In some embodiments, a semiconductor device includes a package substrate, and a first die stack mounted on the package substrate and including a plurality of first memory dies. The device can include a substrate mounted on the first die stack, the substrate including a plurality of routing elements. The device can also include a second die stack mounted on the substrate, the second die stack including a plurality of second memory dies. The device can further include a controller die mounted on the substrate. The controller die can be configured to communicate with the second die stack via the routing elements of the substrate. The device can include a mold material encapsulating the first die stack, the second die stack, the substrate, and the controller die.