A layered structure comprising a substrate having a first deformation. Also one or more device layers forming a device and having a second deformation. A deformation control layer which is pseudomorphic with respect to the substrate and having a third deformation. The deformation control layer is selected such that a sum of the first, second and third deformations matches a target level of deformation. Advantageously the layered structure has a controlled, known deformation which can be compressive, tensile or zero.

A semiconductor device comprising a substrate, a channel layer over the substrate, an active layer over the channel layer and a laminate layer in contact with the active layer. The active layer has a band gap discontinuity with the channel layer.

A method of manufacturing a nitride semiconductor substrate includes providing a silicon substrate having a first surface and a second surface opposing each other, growing a nitride template on the first surface of the silicon substrate in a first growth chamber, in which a silicon compound layer is formed on the second surface of the silicon substrate in a growth process of the nitride template, removing the silicon compound layer from the second surface of the silicon substrate, growing a group III nitride single crystal on the nitride template in a second growth chamber, and removing the silicon substrate from the second growth chamber.

Systems and methods described herein may include a first semiconductor layer with a first lattice constant, a rare earth pnictide buffer epitaxially grown over the first semiconductor, wherein a first region of the rare earth pnictide buffer adjacent to the first semiconductor has a net strain that is less than 1%, a second semiconductor layer epitaxially grown over the rare earth pnictide buffer, wherein a second region of the rare earth pnictide buffer adjacent to the second semiconductor has a net strain that is a desired strain, and wherein the rare earth pnictide buffer may comprise one or more rare earth elements and one or more Group V elements. In some examples, the desired strain is approximately zero.

There are disclosed herein various implementations of semiconductor structures including III-Nitride interlayer modules. One exemplary implementation comprises a substrate and a first transition body over the substrate. The first transition body has a first lattice parameter at a first surface and a second lattice parameter at a second surface opposite the first surface. The exemplary implementation further comprises a second transition body, such as a transition module, having a smaller lattice parameter at a lower surface overlying the second surface of the first transition body and a larger lattice parameter at an upper surface of the second transition body, as well as a III-Nitride semiconductor layer over the second transition body. The second transition body may consist of two or more transition modules, and each transition module may include two or more interlayers. The first and second transition bodies reduce strain for the semiconductor structure.

A semiconductor device includes an epitaxial substrate. The epitaxial substrate includes a substrate. A strain relaxed layer covers and contacts the substrate. A III-V compound stacked layer covers and contacts the strain relaxed layer. The III-V compound stacked layer is a multilayer epitaxial structure formed by aluminum nitride, aluminum gallium nitride or a combination of aluminum nitride and aluminum gallium nitride.

Methods and structures includes providing a substrate, forming a prelayer over a substrate, forming a barrier layer over the prelayer, and forming a channel layer over the barrier layer. Forming the prelayer may include growing the prelayer at a graded temperature. Forming the barrier layer is such that the barrier layer may include GaAs or InGaAs. Forming the channel layer is such that the channel layer may include InAs or an Sb-based heterostructure. Thereby structures are formed.

A III-N semiconductor channel is compositionally graded between a transition layer and a III-N polarization layer. In embodiments, a gate stack is deposited over sidewalls of a fin including the graded III-N semiconductor channel allowing for formation of a transport channel in the III-N semiconductor channel adjacent to at least both sidewall surfaces in response to a gate bias voltage. In embodiments, a gate stack is deposited completely around a nanowire including a III-N semiconductor channel compositionally graded to enable formation of a transport channel in the III-N semiconductor channel adjacent to both the polarization layer and the transition layer in response to a gate bias voltage.

A silicon carbide epitaxial layer includes a first silicon carbide layer, a second silicon carbide layer, a third silicon carbide layer, and a fourth silicon carbide layer. A nitrogen concentration of the second silicon carbide layer is increased from the first silicon carbide layer toward the third silicon carbide layer. A value obtained by dividing, by a thickness of the second silicon carbide layer, a value obtained by subtracting a nitrogen concentration of the first silicon carbide layer from a nitrogen concentration of the third silicon carbide layer is less than or equal to 6×10.sup.23 cm.sup.−4. Assuming that the nitrogen concentration of the third silicon carbide layer is N cm.sup.−3; and a thickness of the third silicon carbide layer is X μm, X and N satisfy a Formula 1.

A method to fabricate thin-film photovoltaic devices including a photovoltaic Cu(In,Ga)Se.sub.2 or equivalent ABC absorber layer, such as an ABC.sub.2 layer, deposited onto a back-contact layer characterized in that the method includes at least five deposition steps, during which the pair of third and fourth steps are sequentially repeatable, in the presence of at least one C element over one or more steps. In the first step at least one B element is deposited, followed in the second by deposition of A and B elements at a deposition rate ratio A.sub.r/B.sub.r, in the third at a ratio A.sub.r/B.sub.r lower than the previous, in the fourth at a ratio A.sub.r/B.sub.r higher than the previous, and in the fifth depositing only B elements to achieve a final ratio A/B of total deposited elements.