A manufacturing method for manufacturing a stacked substrate by bonding two substrates includes: acquiring information about crystal structures of a plurality of substrates; and determining a combination of two substrates to be bonded to each other, based on the information about the crystal structures. In the manufacturing method described above, the information about the crystal structures may include at least one of plane orientations of bonding surfaces and crystal orientations in a direction in parallel with the bonding surfaces. In the manufacturing methods described above, the determining may include determining a combination of the two substrates with a misalignment amount after bonding being equal to or smaller than a predetermined threshold.

A semiconductor manufacturing apparatus according to an embodiment includes a chuck configured to receive a carrier thereon, a carrier contact device configured to contact the carrier on the chuck, and a bonding head configured to transfer a semiconductor die to the carrier and configured to attach the semiconductor die on the carrier. The chuck includes a chuck reference key positioned at an edge portion thereof. The carrier contact device includes a contact position recognition key. The semiconductor manufacturing apparatus also includes a camera configured to obtaining images of the chuck reference key and the contact position recognition key.

A wet alignment method for a micro-semiconductor chip and a display transfer structure are provided. The wet alignment method for a micro-semiconductor chip includes: supplying a liquid to a transfer substrate including a plurality of grooves; supplying the micro-semiconductor chip onto the transfer substrate; scanning the transfer substrate by using an absorber capable of absorbing the liquid. According to the wet alignment method, the micro-semiconductor chip may be transferred onto a large area.

A bonding apparatus includes a first holder, a second holder, a moving unit, a housing, an interferometer, a first gas supply and a second gas supply. The first holder is configured to attract and hold a first substrate. The second holder is configured to attract and hold a second substrate. The moving unit is configured to move a first one of the first holder and the second holder in a horizontal direction with respect to a second one thereof. The interferometer is configured to radiate light to the first one or an object moved along with the first one to measure a horizontal distance thereto. The first gas supply is configured to supply a clean first gas to an inside of the housing. The second gas supply is configured to supply a second gas to a space between the interferometer and the first one or the object.

An apparatus includes a thermal spreader configured to remove thermal energy from a device to be cooled. The thermal spreader includes a ringframe having an opening, where the opening is configured to provide access to the device through the ringframe. The thermal spreader also includes a pair of thermal straps configured to fit within the opening. The pair of thermal straps is configured to be bonded to the device and to be fastened to the ringframe in order to provide the thermal energy from the device to the ringframe.

A substrate bonding apparatus for bonding a first substrate to a second substrate includes a first bonding chuck configured to fix the first substrate to a first surface of the first bonding chuck; a second bonding chuck configured to fix the second substrate to a second surface of the second bonding chuck, the second surface facing the first surface; a process gas injector surrounding at least one selected from the first bonding chuck and the second bonding chuck in a plan view, the process gas injector configured to inject a process gas between the first substrate and the second substrate when respectively disposed on the first bonding chuck and the second bonding chuck; and an air curtain generator disposed at an outside of the process gas injector in the plan view, the air curtain generator configured to inject an air curtain forming gas to form an air curtain surrounding the first substrate and the second substrate.

A method for bonding a first substrate to a second substrate on mutually facing contact surfaces of the substrates, wherein the first substrate is mounted on a first chuck and the second substrate is mounted on a second chuck, and wherein a plate is arranged between the second substrate and the second chuck, wherein the second substrate with the plate is deformed with respect to the second chuck before and/or during the bonding. Furthermore, the present invention relates to a corresponding device and a corresponding plate.

Method of assembly of a first element (I) and a second element (II) each having an assembly surface, at least one of the assembly surfaces comprising recessed metal portions (6, 106) surrounded by dielectric materials (4, 104) comprising: A) a step to bring the two assembly surfaces into contact without application of pressure such that direct bonding is obtained between the assembly surfaces, said first and second assemblies (I, II) forming a stack with a given thickness (e), B) a heat treatment step of said stack during which the back faces (10, 110) of the first (I) and the second (II) elements are held in position so that they are held at a fixed distance (E) between the given stack thickness+/−2 nm.

A method and device for bonding chips onto a substrate or onto further chips. The chips are bonded onto the substrate or the further chips by means of a direct bond.

A wet alignment method for a micro-semiconductor chip and a display transfer structure are provided. The wet alignment method for a micro-semiconductor chip includes: supplying a liquid to a transfer substrate including a plurality of grooves; supplying the micro-semiconductor chip onto the transfer substrate; scanning the transfer substrate by using an absorber capable of absorbing the liquid. According to the wet alignment method, the micro-semiconductor chip may be transferred onto a large area.