Abstract: Methods, systems, and devices for techniques for coupled host and memory dies are described. For example, to distribute memory access circuitry among multiple semiconductor dies of a stack, a first die may include a set of one or more memory arrays and a first portion of the circuitry configured to access the set of memory arrays, and a second die may include a second portion of the circuitry configured to access the set of memory arrays. The first portion and the second portion of the circuitry configured to access a set of memory arrays may be communicatively coupled between the dies using various interconnection techniques, such as a fusion of conductive contacts of the respective memory dies. In some examples, the second die may also include the host itself (e.g., a host processor).

Abstract: This document discloses techniques, apparatuses, and systems for connecting semiconductor dies through traces. A semiconductor assembly is described that includes two semiconductor dies. The first semiconductor die includes a first dielectric layer at which first circuitry is disposed. The second semiconductor die includes a second dielectric layer at which second circuitry is disposed. One or more traces extend from a side surface of the first dielectric layer and at a side surface of the second dielectric layer to electrically couple the first circuitry and the second circuitry. In doing so, rigid connective structures may not be needed to couple the first semiconductor die and the second semiconductor die.

Abstract: Methods, systems, and devices for memory with parallel main and test interfaces are described. A memory die may be configured with parallel interfaces that may individually (e.g., separately) support evaluation operations (e.g., before or as part of assembly in a multiple-die stack) or access operations (e.g., after assembly in a multiple die stack). For example, a memory die may include a first set of one or more contacts that support communicating signaling with or via another memory die in a multiple-die stack. The memory die may also include a second set of one or more contacts that support probing for pre-assembly evaluations, which may be electrically isolated from the first set of contacts. By implementing such parallel interfaces, evaluation operations may be performed using the second set of contacts without damaging the first set of contacts, which may improve capabilities for supporting a multiple-die stack in a memory device.

Abstract: Methods of making a semiconductor device assembly are provided. The methods can comprise providing a first semiconductor device having a first dielectric material at a first surface, providing a carrier wafer having a second dielectric material at a second surface, and forming a dielectric-dielectric bond between the first dielectric material and the second dielectric material. At least one of the first surface and the second surface includes a cavity configured to entrap a gas during the formation of the bond. The method can further include stacking one or more second semiconductor devices over the first semiconductor device to form the semiconductor device assembly, and removing the semiconductor device assembly from the carrier wafer.

Abstract: A semiconductor device assembly that includes carbon nanofibers (CNFs) for heat dissipation has a CNF layer. Molding compound encapsulates the CNF layer to form an encapsulated CNF layer. The molding compound extends between individual adjacent CNFs within the encapsulated CNF layer, and upper edges of at least a portion of individual CNFs within the encapsulated CNF layer are exposed along an upper surface of the encapsulated CNF layer. The upper surface of the CNF layer is removably attached to a bottom surface of a carrier wafer.

Abstract: A semiconductor device assembly that includes carbon nanofibers (CNFs) for heat dissipation has a CNF layer. Molding compound encapsulates the CNF layer to form an encapsulated CNF layer. The molding compound extends between individual adjacent CNFs within the encapsulated CNF layer, and upper edges of at least a portion of individual CNFs within the encapsulated CNF layer are exposed along an upper surface of the encapsulated CNF layer. The upper surface of the CNF layer is removably attached to a bottom surface of a carrier wafer.

Abstract: Heat spreaders for use in semiconductor device testing, such as burn-in testing, are disclosed herein. In one embodiment, a heat spreader is configured to be coupled to a burn-in testing board including a plurality of sockets. The heat spreader includes (i) a frame having a plurality of apertures, and (ii) a plurality of heat sinks movably positioned within corresponding ones of the apertures. When the heat spreader is coupled to the burn-in testing board, the heat sinks are configured to extend into corresponding ones of the sockets to thermally contact semiconductor devices positioned within the sockets. The heat spreader can promote a uniform temperature gradient across the burn-in board during testing of the semiconductor devices.

Abstract: Heat spreaders for use in semiconductor device testing, such as burn-in testing, are disclosed herein. In one embodiment, a heat spreader is configured to be coupled to a burn-in testing board including a plurality of sockets. The heat spreader includes a base portion and a plurality of protrusions extending from the base portion. When the heat spreader is coupled to the burn-in testing board, the protrusions are configured to extend into corresponding ones of the sockets to thermally contact semiconductor devices positioned within the sockets. The heat spreader can promote a uniform temperature gradient across the burn-in board during testing of the semiconductor devices.

Abstract: Heat spreaders for use in semiconductor device testing, such as burn-in testing, are disclosed herein. In one embodiment, a heat spreader is configured to be coupled to a burn-in testing board including a plurality of sockets. The heat spreader includes (i) a frame having a plurality of apertures, and (ii) a plurality of heat sinks movably positioned within corresponding ones of the apertures. When the heat spreader is coupled to the burn-in testing board, the heat sinks are configured to extend into corresponding ones of the sockets to thermally contact semiconductor devices positioned within the sockets. The heat spreader can promote a uniform temperature gradient across the burn-in board during testing of the semiconductor devices.

Abstract: Semiconductor devices including materials for thermal management, and associated systems and methods, are described herein. In some embodiments, a semiconductor package includes a first semiconductor die coupled to a second semiconductor die by a plurality of interconnect structures. A thermal material can be positioned between the first and second semiconductor dies. The thermal material can include an array of heat transfer elements embedded in a supporting matrix material. The array of heat transfer elements can include at least one vacant region aligned with at least one of the interconnect structures.

Abstract: A memory system having heat spreaders with different arrangements of projections are provided. In some embodiments, the memory system comprises a substrate, a first semiconductor device attached to a first side of the substrate, a second semiconductor device attached to a second side of the substrate, a first heat spreader attached to the first semiconductor device, and a second heat spreader attached the second semiconductor device. The first heat spreader has a plurality of first projections facing a first direction and positioned in a first arrangement, and the second heat spreader has a plurality of second projections facing a second direction and positioned in a second arrangement different than the first arrangement. In some embodiments, the first projections are aligned with a majority of the second projections in a first direction and are offset with a majority of the second projections in a second direction.

Abstract: A memory system having heat spreaders with different arrangements of projections are provided. In some embodiments, the memory system comprises a substrate, a first semiconductor device attached to a first side of the substrate, a second semiconductor device attached to a second side of the substrate, a first heat spreader attached to the first semiconductor device, and a second heat spreader attached to the second semiconductor device. The first heat spreader has a plurality of first projections facing a first direction and positioned in a first arrangement, and the second heat spreader has a plurality of second projections facing a second direction and positioned in a second arrangement different than the first arrangement. In some embodiments, the first projections are aligned with a majority of the second projections in a first direction and are offset with a majority of the second projections in a second direction.

Abstract: Heat spreaders for use in semiconductor device testing, such as burn-in testing, are disclosed herein. In one embodiment, a heat spreader is configured to be coupled to a burn-in testing board including a plurality of sockets. The heat spreader includes a base portion and a plurality of protrusions extending from the base portion. When the heat spreader is coupled to the burn-in testing board, the protrusions are configured to extend into corresponding ones of the sockets to thermally contact semiconductor devices positioned within the sockets. The heat spreader can promote a uniform temperature gradient across the burn-in board during testing of the semiconductor devices.

Abstract: Heat spreaders for use in semiconductor device testing, such as burn-in testing, are disclosed herein. In one embodiment, a heat spreader is configured to be coupled to a burn-in testing board including a plurality of sockets. The heat spreader includes (i) a frame having a plurality of apertures, and (ii) a plurality of heat sinks movably positioned within corresponding ones of the apertures. When the heat spreader is coupled to the burn-in testing board, the heat sinks are configured to extend into corresponding ones of the sockets to thermally contact semiconductor devices positioned within the sockets. The heat spreader can promote a uniform temperature gradient across the burn-in board during testing of the semiconductor devices.

Abstract: A memory system having heat spreaders with different arrangements of projections are provided. In some embodiments, the memory system comprises a substrate, a first semiconductor device attached to a first side of the substrate, a second semiconductor device attached to a second side of the substrate, a first heat spreader attached to the first semiconductor device, and a second heat spreader attached the second semiconductor device. The first heat spreader has a plurality of first projections facing a first direction and positioned in a first arrangement, and the second heat spreader has a plurality of second projections facing a second direction and positioned in a second arrangement different than the first arrangement. In some embodiments, the first projections are aligned with a majority of the second projections in a first direction and are offset with a majority of the second projections in a second direction.

Abstract: The present provides a lift and align table, having an adjustable support for positioning a piece of equipment, comprising a base frame, a middle plate, and an upper plate, a lifting mechanism disposed between the base frame and the middle plate, and a sliding mechanism disposed between the middle plate and an upper plate.