Systems, devices, and methods for high die stack packages with vertical die-to-die interconnects are provided herein. A die stack package can include a substrate, a lower die stack carried by the substrate, a spacer carried by the substrate, an upper die stack carried by the spacer, a plurality of wire bonds, and a plurality of vertical wires. The lower die stack can include a plurality of lower dies stacked in a cascading arrangement. The upper die stack can include a plurality of upper dies stacked in a cascading arrangement in a same direction as the plurality of lower dies. The wire bonds can electrically couple adjacent ones of the lower dies. An nth vertical wire can extend vertically between and electrically couple an nth upper die and an nth lower die. In some embodiments, the die stack package further includes an input-and-output extender carried by the substrate.

A semiconductor package includes a memory die stack having a clock signal shared by lower and upper bytes. Each of a plurality of memory dies constituting the memory die stack of the semiconductor package includes a first clock circuit configured to generate a read clock signal for a lower byte and an upper byte constituting a data width of the memory die, and a plurality of first die bond pads corresponding to the number of ranks of a memory system including the memory die, and each of the plurality of first die bond pads is set for each rank. The first clock circuit is connected to, among the plurality of first die bond pads, a die bond pad corresponding to a rank to which the memory die belongs.

A roll-to-roll sintering system for wide inorganic tape material may include a spool on which is wound a continuous tape material comprising a green tape material and a backing layer, a take-up reel, and a heating station including at least one furnace. The heating station is configured to receive an unwound length of the continuous tape. The heating station further includes a first curved section such that the continuous tape material is bent through a radius of curvature of 0.01 m to 13,000 m, and at least two rollers defining the first curved section over which the continuous tape material is bent. The heating station is controlled to provide at least a portion of the heating station with an air free atmosphere, that being at least one of vacuum, hydrogen, or helium.

A semiconductor package includes a package substrate, a processor chip mounted on a first region of the package substrate, a plurality of memory chips mounted on a second region of the package substrate being spaced apart from the first region of the package substrate, a signal transmission device mounted on a third region of the package substrate between the first and second regions of the package substrate, and a plurality of first bonding wires connecting the plurality of memory chips to the signal transmission device. The signal transmission device includes upper pads connected to the plurality of first bonding wires, penetrating electrodes arranged in a main body portion of the signal transmission device and connected to the upper pads, and lower pads in a lower surface portion of the signal transmission device and connected to the penetrating electrodes and connected to the package substrate via bonding balls.

A semiconductor device includes: an insulated circuit substrate including a base plate, a resin layer on the base plate, and a circuit pattern on the resin layer; a semiconductor chip that is rectangular and is bonded to the circuit pattern such that a side edge of the semiconductor chip is spaced inwardly from an outer peripheral edge of the circuit pattern by a predetermined distance; a case on the resin layer and surrounds the circuit pattern and the semiconductor chip; and a sealing material that covers the insulated circuit substrate and semiconductor chip and is surrounded by the case. The predetermined distance and thickness of the circuit pattern are greater than or equal to 0.1 of a length of one side of the semiconductor chip. A peripheral region of the case and a peripheral region of the resin layer are connected to each other via an adhesive layer.

A semiconductor package includes a package substrate including first and second power P-pads and first and second signal P-pads, a lower layer chip including first and second power L-pads and first and second signal L-pads, an upper layer chip offset from the lower layer chip and including first and second power U-pads and first and second signal U-pads. The first power and signal P-pads are alternatingly stacked, the first power and signal L-pads are alternatingly stacked, and the first power and signal U-pads are alternatingly stacked. The second power and signal P-pads are alternatingly stacked, the second power and signal L-pads are alternatingly stacked, and the second power and signal U-pads are alternatingly stacked. Bonding wires connect the first and second power U-pads, the first and second power L-pads, the second power U-pads and P-pads, and the second signal U-pads and P-pads.

A quantum computing system that includes a quantum circuit device having at least one operating frequency; a first substrate having a first surface on which the quantum circuit device is disposed; a second substrate having a first surface that defines a recess of the second substrate, the first and second substrates being arranged such that the recess of the second substrate forms an enclosure that houses the quantum circuit device; and an electrically conducting layer that covers at least a portion of the recess of the second substrate.

A semiconductor package includes a leadframe having a die pad and a plurality of pins disposed around the die pad, a metal interposer attached to a top surface of the die pad, and a semiconductor die attached to a top surface of the metal interposer. A plurality of bond wires with same function is bonded to the metal interposer. The die pad, the metal interposer and the semiconductor die are stacked in layers so as to form a pyramidal stack structure.

Implementations described herein relate to various semiconductor device assemblies. In some implementations, a semiconductor device assembly may include a base layer, a dielectric interposer coupled to the base layer and including a first outer surface facing the base layer and an opposing second outer surface facing away from the base layer and spaced apart from the first outer surface in a direction, a first electrical-connection cut-in in the second outer surface that extends, in the direction, toward the first outer surface, and one or more first electrical connections disposed within the first electrical-connection cut-in such that at least a portion of the one or more first electrical connections does not extend, in the direction, beyond the second outer surface.

The present disclosure relates to a power semiconductor module including: a carrier; a plurality of semiconductor dies mounted onto the carrier; a housing including a frame enclosing the carrier circumferentially; a first external connection electrically connected to a first subset of the semiconductor dies, the first external connection protruding laterally from the housing at a first level; and an insert including an electrically isolating material and a second external connection mounted onto the electrically isolating material. The insert is at least partially mounted to the frame and at least partially covers the carrier and/or the first subset of the plurality of semiconductor dies. The second external connection is connected to a second subset of the plurality of semiconductor dies. The second external connection protrudes from the housing.