Provided is a wafer jig including a bottom wall and a ring-shaped side wall. The bottom wall has a supporting surface. The ring-shaped side wall is connected to a periphery of the bottom wall. The ring-shaped side wall includes at least two step portions. The two step portions include a first step portion and a second step portion. The first step portion is connected between the supporting surface and the second step portion, and the first step portion protrudes along a direction toward a center of the bottom wall. The ring-shaped side wall surrounds the center. In addition, a wafer structure and a wafer processing method are also provided.

A method of processing a semiconductor wafer includes: forming one or more epitaxial layers over a first main surface of the semiconductor wafer; forming one or more porous layers in the semiconductor wafer or in the one or more epitaxial layers, wherein the semiconductor wafer, the one or more epitaxial layers and the one or more porous layers collectively form a substrate; forming doped regions of a semiconductor device in the one or more epitaxial layers; and after forming the doped regions of the semiconductor device, separating a non-porous part of the semiconductor wafer from a remainder of the substrate along the one or more porous layers.

A glass substrate is reused. The mass productivity of a semiconductor device is increased. A glass substrate one surface of which includes a first material and a second material. The first material includes one or both of a metal and a metal oxide. The second material includes one or both of a resin and a decomposition product of a resin. A cleaning method of a glass substrate, which includes a step of preparing the glass substrate one surface of which includes a first material and a second material and a step of exposing the first material by removing at least part of the second material.

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 lift-off method includes a dividing step of dividing a buffer layer and an optical device layer stacked on a front side of a substrate to thereby form separate buffer layers and separate optical device layers, a transfer member bonding step of bonding a transfer member to a front side of the separate optical device layers, a buffer layer breaking step of applying a pulsed laser beam to the separate buffer layers to thereby break the separate buffer layers, and an optical device layer transferring step of transferring the separate optical device layers from the substrate to the transfer member. An energy density of each pulse of the pulsed laser beam is set to 1.0 to 5.0 mJ/mm.sup.2.

A coupon wafer comprising a device coupon (110) for use in a micro-transfer printing process used to fabricate an optoelectronic device. The coupon wafer includes a wafer substrate (124), and the device coupon (110) is attached to the wafer substrate via a tether (122) and the tether (122) is formed from a dielectric material.

A highly reliable display apparatus is provided at a low cost. The display apparatus includes a light-emitting diode included in a pixel circuit, a transistor included in the pixel circuit, and a transistor included in a driver circuit of the pixel circuit, which are stacked to have an overlap region. With such a structure, the display apparatus can be downsized. In addition, in the display apparatus, a plurality of light-emitting diodes can be attached to a circuit board formed with a transistor and the like in one step. Consequently, the manufacturing cost of the display apparatus can be reduced.

An AlN monocrystal plate disclosed herein may include: a first surface in a thickness direction; and a second surface opposing the first surface. A metal component containing region may be disposed substantially parallel to the first surface in an intermediate portion between the first surface and the second surface. In the metal component containing region, a plurality of metal components may be introduced and distributed. A type of the metal components may be Ga.

According to claim 1, the invention relates to a method for providing at least one solid-body layer (4). The solid-body layer (4) is separated from a solid body (1). The method according to the invention preferably has the steps of: producing a plurality of modifications (9) in the interior of the solid body (1) using laser beams in order to form a separation plane (8), compressive stresses being produced in the solid body (1) by the modifications (9); separating the solid-body layer (4) by separating the remaining solid body (1) and the solid-body layer (4) along the separation plane (8) formed by the modifications (9), wherein at least parts of the modifications (9) which produce the compressive stresses remain on the solid-body layer (4), and enough modifications (9) are produced that the solid-body layer (4) is separated from the solid body (1) on the basis of the modifications (9) or an external force is introduced into the solid body (1) in order to produce additional stresses in the solid body (1), said external force being so great that the stresses cause a crack to propagate along the separation plane (8) produced by the modifications; and producing a metal layer on the surface exposed by the separation of the solid-body layer (4) from the solid body (1) in order to at least partly, preferably greatly and particularly preferably completely, compensate for a deformation of the solid-body layer (4) produced by the compressive stresses of the remaining modification parts or at feast partly, preferably greatly or completely, compensate for the compressive stresses.

A method for manufacturing an electronic device includes at least a preparing step of preparing a structure provided with an adhesive film provided with a base material layer, an adhesive resin layer (A) provided on a first surface side of the base material layer, an adhesive resin layer (B) provided on a second surface side of the base material layer, and an unevenness-absorbing resin layer (C) provided between the base material layer and the adhesive resin layer (A) or between the base material layer and the adhesive resin layer, and an electronic component attached to the adhesive resin layer (A) of the adhesive film and having an uneven structure, a cross-linking step of cross-linking the unevenness-absorbing resin layer (C) by applying an external stimulus to the unevenness-absorbing resin layer (C) in the structure, and a sealing step of sealing the electronic component with a sealing material.