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.

Embodiments of the invention are directed to a method of forming a semiconductor device on an integrated circuit (IC). The method includes forming a containment structure having a non-sacrificial fin-containment region and a sacrificial fin-containment region, wherein the containment structure is configured to define a source or drain (S/D) cavity. A S/D region is formed in the S/D cavity. The S/D region includes a contained S/D region defined by the containment structure. The S/D region further includes a non-contained S/D region positioned above the containment structure. The IC is exposed to an etchant that is selective to the sacrificial fin-containment region, non-selective to the non-sacrificial fin-containment region, and non-selective to a plurality of spacers on the IC. Exposing the IC to the etchant selectively removes the sacrificial fin-containment region and exposes sidewalls of the contained S/D region.

Some embodiments include methods of forming voids within semiconductor constructions. In some embodiments the voids may be utilized as microstructures for distributing coolant, for guiding electromagnetic radiation, or for separation and/or characterization of materials. Some embodiments include constructions having micro-structures therein which correspond to voids, conduits, insulative structures, semiconductor structures or conductive structures.

A method for surface treatment of an at least primarily crystalline substrate surface of a substrate such that by amorphization of the substrate surface, an amorphous layer is formed at the substrate surface with a thickness d>0 nm of the amorphous layer. This invention also relates to a corresponding device for surface treatment of substrates.

An electrical isolation process, includes receiving a substrate including a layer of carbon-rich material on silicon, and selectively removing regions of the substrate to form mutually spaced islands of the carbon-rich material on the silicon. The layer of carbon-rich material on silicon includes the layer of carbon-rich material on an electrically conductive layer of silicon on an electrically insulating material. Selectively removing regions of the substrate includes removing the carbon-rich material and at least a portion of the electrically conductive layer of silicon from those regions to provide electrical isolation between the islands of carbon-rich material on silicon.

A circuit includes at least one bipolar transistor and at least one variable capacitance diode. The circuit is fabricated using a method whereby the bipolar transistor and variable capacitance diode are jointly produced on a common substrate.

Embodiments of wafer bonding method and structures thereof are disclosed. The wafer bonding method can include performing a plasma activation treatment on a front surface of a first and a front surface of a second wafer; performing a silica sol treatment on the front surfaces of the first and the second wafers; performing a preliminary bonding process of the first and second wafer; and performing a heat treatment of the first and the second wafers to bond the front surface of the first wafer to the front surface of the second wafers.

There is provided a nitride crystal substrate comprising group-III nitride crystal and containing n-type impurities, wherein an absorption coefficient α is approximately expressed by equation (1) in a wavelength range of at least 1 μm or more and 3.3 μm or less: α=n Kλ.sup.a (1) (wherein, λ(μm) is a wavelength, α(cm.sup.−1) is absorption coefficient of the nitride crystal substrate at 27° C., n (cm.sup.−3) is a free electron concentration in the nitride crystal substrate, and K and a are constants, satisfying 1.5×10.sup.−19≤K≤6.0×10.sup.−19, a=3).

A method and device for bonding a first substrate with a second substrate inside a sealed bonding chamber. The method includes: a) fixing of the first and second substrates, b) arranging of the first and second substrates, c) mutual approaching of the first and second substrates, d) contacting the first and second substrates at respective bond initiation points, e) generating a bonding wave running from the bond initiation points to side edges of the substrates, and f) influencing the bonding wave during course of the bonding wave, wherein targeted influencing of the bonding wave takes place by a regulated and/or controlled change of pressure inside the bonding chamber.

The present disclosure, in some embodiments, relates to a workpiece bonding apparatus. The workpieces bonding apparatus includes a first substrate holder having a first surface configured to receive a first workpiece, and a second substrate holder having a second surface configured to receive a second workpiece. A vacuum apparatus is positioned between the first substrate holder and the second substrate holder and is configured to selectively induce a vacuum between the first surface and the second surface. The vacuum is configured to attract the first surface and the second surface toward one another.