Abstract: The invention relates to a process for fabricating a heterostructure. This process comprises heating an intermediate heterostructure. The intermediate heterostructure comprises a crystalline strain relaxation layer interposed directly between a first substrate and a strained layer of crystalline semiconductor material. The process further comprises causing plastic deformation of the crystalline strain relaxation layer and elastic deformation of the strained layer of crystalline semiconductor material to at least partially relax the strained layer of crystalline semiconductor material.

Abstract: This invention provides composite semiconductor substrates and methods for fabricating such substrates. The composite structures include a semiconductor substrate, a semiconductor superstrate and an intermediate layer interposed between the substrate and the superstrate that comprises a material that undergoes a structural transformation when subject to a suitable heat treatment. The methods provide such a heat treatment so that the intermediate layer becomes spongy or porous, being filled with numerous micro-bubbles or micro-cavities containing a gaseous phase. The composite semiconductor substrates with structurally-transformed intermediate layers have numerous applications.

Abstract: A method for bonding a first wafer on a second wafer by molecular adhesion, where the wafers have an initial radial misalignment between them. The method includes bringing the two wafers into contact so as to initiate the propagation of a bonding wave between the two wafers while a predefined bonding curvature is imposed on at least one of the two wafers during the contacting step as a function of the initial radial misalignment.

Abstract: The invention relates to a method for transferring a layer from a donor substrate onto a handle substrate wherein, after detachment, the remainder of the donor substrate is reused. To get rid of undesired protruding edge regions which are due to the chamfered geometry of the substrates, the invention proposes to carry out an additional etching process before detachment occurs.

Abstract: Processes and systems are used to reduce undesired deposits within a reaction chamber associated with a semiconductor deposition system. A cleaning gas may be caused to flow through at least one gas flow path extending through at least one gas furnace, and the heated cleaning gas may be introduced into a reaction chamber to remove at least a portion of undesired deposits from within the reaction chamber.

Abstract: Embodiments relate to semiconductor structures and methods of forming semiconductor structures. The semiconductor structures include a substrate layer having a CTE that closely matches a CTE of one or more layers of semiconductor material formed over the substrate layer. In some embodiments, the substrate layers may comprise a composite substrate material including two or more elements. The substrate layers may comprise a metal material and/or a ceramic material in some embodiments.

Abstract: Atomic layer deposition (ALD) or ALD-like deposition processes are used to fabricate dilute nitride III-V semiconductor materials. A first composition of process gases may be caused to flow into a deposition chamber, and a group V element other than nitrogen and one or more group III elements may be adsorbed over the substrate (in atomic or molecular form). Afterward, a second composition of process gases may be caused to flow into the deposition chamber, and N and one or more group III elements may be adsorbed over the substrate in the deposition chamber. An epitaxial layer of dilute nitride III-V semiconductor material may be formed over the substrate in the deposition chamber from the sequentially adsorbed elements.

Abstract: Methods and systems are increase the number of Group V ions formed from Group V precursors in methods of forming III-V semiconductor materials to enhance the growth rate of the III-V semiconductor material. In some embodiments, a Group V precursor is heated and at least partially decomposed in a heated diffuser to form Group V ions. In additional embodiments, microwave energy is applied to a Group V precursor and the Group V precursor is at least partially decomposed to form Group V ions. Group III ions are also formed, and the Group III and Group V ions are used to form a III-V semiconductor material within a chamber.

Abstract: Methods for fabricating a semiconductor substrate include forming a first substrate layer over a surface of a first semiconductor layer, and thermally spraying a second substrate layer on a side of the first substrate layer opposite the first semiconductor layer. At least one additional semiconductor layer is epitaxially grown over the first semiconductor layer on a side thereof opposite the first substrate layer. At least one of the first substrate layer and the second substrate layer may be formulated to exhibit a Coefficient of Thermal Expansion (CTE) closely matching a CTE of at least one of the first semiconductor layer and the at least one additional semiconductor layer. Semiconductor structures are fabricated using such methods.

Abstract: Radiation-emitting semiconductor devices include a first base region comprising an n-type III-V semiconductor material, a second base region comprising a p-type III-V semiconductor material, and a multi-quantum well structure disposed between the first base region and the second base region. The multi-quantum well structure includes at least three quantum well regions and at least two barrier regions. An electron hole energy barrier between a third of the quantum well regions and a second of the quantum well regions is less than an electron hole energy barrier between the second of the quantum well regions and a first of the quantum well regions. Methods of forming such devices include sequentially epitaxially depositing layers of such a multi-quantum well structure, and selecting a composition and configuration of the layers such that the electron hole energy barriers vary across the multi-quantum well structure.

Abstract: A substrate is treated by means of at least one pulse of a luminous flux of determined wavelength. The substrate comprises an embedded layer that absorbs the luminous flux independently of the temperature. The embedded layer is interleaved between a first treatment layer, layer and a second treatment layer. The first treatment layer has a coefficient of absorption of luminous flux that is low at ambient temperature and grows as the temperature rises. The luminous flux may be applied in several places of the surface of the first layer to heat regions of the embedded layer and generate a propagating thermal front in the first layer opposite the heated regions of the embedded layer, which generate constraints within the second layer.

Abstract: Methods of fabricating semiconductor structures include implanting atom species into a carrier die or wafer to form a weakened region within the carrier die or wafer, and bonding the carrier die or wafer to a semiconductor structure. The semiconductor structure may be processed while using the carrier die or wafer to handle the semiconductor structure. The semiconductor structure may be bonded to another semiconductor structure, and the carrier die or wafer may be divided along the weakened region therein. Bonded semiconductor structures are fabricated using such methods.

Abstract: Methods of fabricating semiconductor structures and devices include bonding a seed structure to a substrate using a glass. The seed structure may comprise a crystal of semiconductor material. Thermal treatment of the seed structure bonded to the substrate using the glass may be utilized to control a strain state within the seed structure. The seed structure may be placed in a state of compressive strain at room temperature. The seed structure bonded to the substrate using the glass may be used for growth of semiconductor material, or, in additional methods, a seed structure may be bonded to a first substrate using a glass, thermally treated to control a strain state within the seed structure and a second substrate may be bonded to an opposite side of the seed structure using a non-glassy material.

Abstract: The present invention relates to a method of treating wafers comprising at least one surface layer of silicon-germanium (SiGe) and a layer of strained silicon (sSi) in contact with the SiGe layer, the sSi layer being exposed by etching of the SiGe layer, the method comprising the steps of: (a) a first selective etch of the SiGe layer, optionally followed by an oxidative cleaning step; (b) a rinsing step using deionized water; (c) drying; and (d) a second selective etch step. The present invention relates to a wafer comprising at least one surface layer of strained silicon (sSi), the at least one surface layer of sSi having a thickness of at least 5 nm and at most 100 ?m and having at most 200 defects per wafer.

Abstract: The invention relates to a method for bonding two substrates, in particular two semiconductor substrates which, in order to be able to improve the reliability of the process, provides the step of providing a gaseous flow over the bonding surfaces of the substrates. The gaseous flow is preferably a laminar flow that is essentially parallel to the bonding surfaces of the substrates, and has a temperature in a range of from room temperature up to 100° C.

Abstract: This invention provides methods that permit wafers to be loaded and unloaded in a gas-phase epitaxial growth chamber at high temperatures. Specifically, this invention provides a method for moving wafers or substrates that can bathe a substrate being moved in active gases that are optionally temperature controlled. The active gases can act to limit or prevent sublimation or decomposition of the wafer surface, and can be temperature controlled to limit or prevent thermal damage. Thereby, previously-necessary temperature ramping of growth chambers can be reduced or eliminated leading to improvement in wafer throughput and system efficiency.

Abstract: The present invention relates to a semiconductor device that has a semiconductor-on-insulator (SeOI) structure, which includes a substrate, an insulating layer such as an oxide layer on the substrate and a semiconductor layer on the insulating layer with a field-effect-transistor (FET) formed in the SeOI structure from the substrate and deposited layers, wherein the FET has a channel region in the substrate, a gate dielectric layer that is made from at least a part of the oxide layer of the SeOI structure; and a gate electrode that is formed at least partially from a part of the semiconductor layer of the SeOI structure. The invention further relates to a method of forming one or more field-effect-transistors or metal-oxide-semiconductor transistors from a semiconductor-on-insulator structure that involves patterning and etching the SeOI structure, forming shallow trench isolations, depositing insulating, metal or semiconductor layers, and removing mask and/or pattern layers.

Abstract: The invention relates to a method for fabricating a locally passivated germanium-on-insulator substrate wherein, in order to achieve good electron mobility, nitridized regions are provided at localised positions. Nitridizing is achieved using a plasma treatment. The resulting substrates also form part of the invention.

Abstract: The present invention relates to the field of semiconductor processing and provides methods that improve chemical vapor deposition (CVD) of semiconductor materials by promoting more efficient thermalization of precursor gases prior to their reaction. In preferred embodiments, the method provides heat transfer structures and their arrangement within a CVD reactor so as to promote heat transfer to flowing process gases. In certain preferred embodiments applicable to CVD reactors transparent to radiation from heat lamps, the invention provides radiation-absorbent surfaces placed to intercept radiation from the heat lamps and to transfer it to flowing process gases.

Abstract: Embodiments of the invention relate to methods of fabricating semiconductor structures, and to semiconductor structures fabricated by such methods. In some embodiments, the methods may be used to fabricate semiconductor structures of III-V materials, such as InGaN. A semiconductor layer is fabricated by growing sublayers using differing sets of growth conditions to improve the homogeneity of the resulting layer, to improve a surface roughness of the resulting layer, and/or to enable the layer to be grown to an increased thickness without the onset of strain relaxation.