A system for assembling fields from a source substrate onto a second substrate. The source substrate includes fields. The system further includes a transfer chuck that is used to pick at least four of the fields from the source substrate in parallel to be transferred to the second substrate, where the relative positions of the at least four of the fields is predetermined.

A method for manufacturing a semiconductor device includes: preparing a processed wafer having a gallium nitride (GaN) wafer and an epitaxial layer on the GaN wafer; forming a device constituent part in a portion of the processes wafer adjacent to a front surface provided by the epitaxial layer; forming a modified layer inside of the processed wafer by applying a laser beam from a back surface side opposite to the front surface side: and dividing the processed wafer at the modified layer. The processed wafer prepared includes a reflective layer for reflecting the laser beam at a position separated from a planned formation position, where the modified layer is to be formed, by a predetermined distance toward the front surface side. The reflective layer contains a layer having a refractive index different from that of a GaN single crystal of an epitaxial layer.

A method for fabricating a three-dimensional (3D) stacked integrated circuit. Pick-and-place strategies are used to stack the source wafers with device layers fabricated using standard two-dimensional (2D) semiconductor fabrication technologies. The source wafers may be stacked in either a sequential or parallel fashion. The stacking may be in a face-to-face, face-to-back, back-to-face or back-to-back fashion. The source wafers that are stacked in a face-to-back, back-to-face or back-to-back fashion may be connected using Through Silicon Vias (TSVs). Alternatively, source wafers that are stacked in a face-to-face fashion may be connected using Inter Layer Vias (ILVs).

A semiconductor device has a first substrate made of a first semiconductor material, such as silicon. A sacrificial layer is formed over a first surface of the first substrate. A seed layer is formed over the sacrificial layer. A compliant layer is formed over a second surface of the first substrate opposite the first surface of the first substrate. A first semiconductor layer made of a second semiconductor material, such as silicon carbide, dissimilar from the first semiconductor material is formed over the sacrificial layer. The first substrate and sacrificial layer are removed leaving the first semiconductor layer substantially defect-free. The first semiconductor layer containing the second semiconductor material is formed at a temperature greater than a melting point of the first semiconductor material. A second semiconductor layer is formed over the first semiconductor layer with an electrical component formed in the second semiconductor layer.

An inspection method for a divided wafer includes a wafer lamination step of stacking a transfer wafer on top of a wafer that has been divided into a plurality of chips, a particle transfer step of, after the wafer lamination step is carried out, positioning the transfer wafer on a lower side and the divided wafer on an upper side and applying a vibration to the wafer stacked on the transfer wafer, to drop particles adhering to side surfaces of the chips onto the transfer wafer, and an inspection step of, after the particle transfer step is carried out, inspecting the particles on the transfer wafer.

A method for separating a removable composite structure using a light flux includes supplying the removable composite structure, which successively comprises: a substrate that is transparent to the light flux; an optically absorbent layer for at least partially absorbing a light flux; a sacrificial layer adapted to dissociate subject to the application of a temperature higher than a dissociation temperature and made of a material different from that of the optically absorbent layer; and at least one layer to be separated. The method further includes applying a light flux through the substrate, the light flux being at least partly absorbed by the optically absorbent layer, so as to heat the optically absorbent layer; heating the sacrificial layer by thermal conduction from the optically absorbent layer, up to a temperature that is greater than or equal to the dissociation temperature; and dissociating the sacrificial layer under the effect of the heating.

Differential-movement transfer stamps for holding microelectronics substrates and/or one or more microelectronic-device dies. Each differential-movement transfer stamp is configured to temporarily securely hold corresponding respective microelectronics substrates for handling and/or during die portioning and/or to temporarily securely hold microelectronic-device dies, for example, for efficient mass transfer and precision placement of the microelectronic-device dies. In some embodiments, each differential-movement transfer stamp includes a plurality of functional units that each comprise or are otherwise associated with one or more dimension-changing components that are used for temporarily securing a microelectronics substrate to the differential-movement transfer stamp and/or for releasing the microelectronics substrate or microelectronic-device dies from the differential-movement transfer stamp. Various uses of the disclosed differential-movement transfer stamps, such as semiconductor processing and mass transfer for making electronic devices such as microLED displays, sensor arrays, and detector arrays, are also described.

Removal of substrates in a composite substrate is facilitated, and flaking of the composite substrate in an unintended process is prevented. A method for manufacturing a composite substrate includes: forming a first bonding material in a first surface of a first substrate; forming, in the first surface, at least one groove located more inward than a periphery in a plan view of the first substrate; forming the first bonding material along an inner wall of the at least one groove, the first bonding material not filling into space enclosed by the inner wall of the at least one groove; forming a second bonding material on a second surface of a second substrate; and bonding the first bonding material and the second bonding material together in a region except the at least one groove.

A semiconductor device includes a first substrate, a semiconductor layer consisting of a nitride-based compound semiconductor, and a bonding layer bonded to the first substrate and the semiconductor layer between the first substrate and the semiconductor layer, and containing at least one of constituent elements of the nitride-based compound semiconductor.

Embodiments may relate to a microelectronic package that includes a die and a backside metallization (BSM) layer positioned on the face of the die. The BSM layer may include a feature that indicates that the BSM layer was formed on the face of the die by a masked deposition technique. Other embodiments may be described or claimed.