A method for formation of a transition metal dichalcogenide (TMDC) material layer on a substrate arranged in a process chamber of a molecular beam epitaxy tool is provided. The method includes evaporating metal from a solid metal source, forming a chalcogen-including gas-plasma, and introducing the evaporated metal and the chalcogen-including gas-plasma into the process chamber thereby forming a TMDC material layer on the substrate.

A p-channel tunneling field effect transistor (TFET) is selected from a group consisting of (i) a multi-layer structure of group IV layers and (ii) a multi-layer structure of group III-V layers. The p-channel TFET includes a channel region comprising one of a silicon-germanium alloy with non-zero germanium content and a ternary III-V alloy. An n-channel TFET is selected from a group consisting of (i) a multi-layer structure of group IV layers and (ii) a multi-layer structure of group III-V layers. The n-channel TFET includes an n-type region, a p-type region with a p-type delta doping, and a channel region disposed between and spacing apart the n-type region and the p-type region. The p-channel TFET and the n-channel TFET may be electrically connected to define a complementary field-effect transistor element. TFETs may be fabricated from a silicon-germanium TFET layer structure grown by low temperature molecular beam epitaxy at a growth temperature at or below 500 C.

A type III-V semiconductor substrate is provided. Semiconductor material is removed from the type III-V semiconductor substrate such that the type III-V semiconductor substrate comprises one or more alignment features extending away from a main lateral surface. Each of the alignment features includes a first lateral surface that is vertically offset from the main lateral surface, and first and second vertical sidewalls that extend between the first lateral surface and the main lateral surface. An epitaxy blocker is formed on the first and second vertical sidewalls of each alignment feature. A type III-V semiconductor regrown layer is epitaxially grown on a portion of the semiconductor wafer that includes the one or more alignment features. The epitaxy blocker prevents the type III-V semiconductor regrown layer from forming on the first and second vertical sidewalls of the one or more alignment features.

A type III-V semiconductor substrate is provided. Semiconductor material is removed from the type III-V semiconductor substrate such that the type III-V semiconductor substrate comprises one or more alignment features extending away from a main lateral surface. Each of the alignment features includes a first lateral surface that is vertically offset from the main lateral surface, and first and second vertical sidewalls that extend between the first lateral surface and the main lateral surface. An epitaxy blocker is formed on the first and second vertical sidewalls of each alignment feature. A type III-V semiconductor regrown layer is epitaxially grown on a portion of the semiconductor wafer that includes the one or more alignment features. The epitaxy blocker prevents the type III-V semiconductor regrown layer from forming on the first and second vertical sidewalls of the one or more alignment features.

A method of performing HVPE heteroepitaxy comprises exposing a substrate to a carrier gas, a first precursor gas, a Group II/III element, and ternary-forming gasses (V/VI group precursor), to form a heteroepitaxial growth of a binary, ternary, and/or quaternary compound on the substrate; wherein the carrier gas is H.sub.2, wherein the first precursor gas is HCl, the Group II/III element comprises at least one of Zn, Cd, Hg, Al, Ga, and In; and wherein the ternary-forming gasses comprise at least two or more of AsH.sub.3 (arsine), PH.sub.3 (phosphine), H.sub.2Se (hydrogen selenide), H.sub.2Te (hydrogen telluride), SbH.sub.3 (hydrogen antimonide, or antimony tri-hydride, or stibine), H.sub.2S (hydrogen sulfide), NH.sub.3 (ammonia), and HF (hydrogen fluoride); flowing the carrier gas over the Group II/III element; exposing the substrate to the ternary-forming gasses in a predetermined ratio of first ternary-forming gas to second ternary-forming gas (1tf:2tf ratio); and changing the 1tf:2tf ratio over time.

A semiconductor layered structure includes a substrate formed of a III-V compound semiconductor, a buffer layer disposed on and in contact with the substrate and formed of a III-V compound semiconductor, and a quantum well layer disposed on and in contact with the buffer layer and including a plurality of component layers formed of III-V compound semiconductors. The substrate has a diameter of 55 mm or more. At least one of the component layers is formed of a mixed crystal of three or more elements. When the compound semiconductor forming the substrate has a lattice constant d.sub.1, the compound semiconductor forming the buffer layer has a lattice constant d.sub.2, and the compound semiconductors forming the quantum well layer have an average lattice constant d.sub.3, (d.sub.2d.sub.1)/d.sub.1 is 310.sup.3 or more and 310.sup.3 or less, and (d.sub.3d.sub.1)/d.sub.1 is 310.sup.3 or more and 310.sup.3 or less.

Methods for depositing silicon include cycling dosing between 1 and 100 cycles of one or more first chlorosilane precursors on a III-V surface at a temperature between 300 C. and 500 C. to form a first layer. Methods may include desorbing chlorine from the first layer by treating the first layer with atomic hydrogen to form a second layer. Methods may include forming a silicon multilayer on the second layer by cycling dosing between 1 and 100 cycles of one or more second chlorosilane precursors and atomic hydrogen at a temperature between 300 C. and 500 C. A layered composition includes a first layer selected from the group consisting of In.sub.xGa.sub.1-xAs, In.sub.xGa.sub.1-xSb, In.sub.xGa.sub.1-xN, SiGe, and Ge, wherein X is between 0.1 and 0.99, and a second layer, wherein the second layer comprises SiH and SiOH.

A method for forming a semiconductor structure by bonding a donor substrate to a carrier substrate is disclosed herein. The donor substrate may include a plurality of semiconductor layers epitaxially grown on top of one another in, and optionally above, a trench of the donor substrate. The carrier substrate may include a first semiconductor device thereon. The method may include removing at least part of the donor substrate in such a way as to expose a semiconductor layer grown on the bottom of the trench, removing at least part of the exposed semiconductor layer, thereby modifying the plurality of semiconductor layers, and forming a second semiconductor device from the modified plurality of semiconductor layers.

The present disclosure relates to a method for smoothing a surface, where the method includes a first depositing onto a first surface of a first layer, resulting in the forming of a second layer on the first surface, where the first depositing is performed using hydride vapor phase epitaxy (HVPE). The first surface is characterized by a first surface feature height and the second layer has a second surface that is characterized by a second surface feature height that is less than the first surface feature height.

Methods of forming SOI substrates are disclosed. In some embodiments, an epitaxial layer and an oxide layer are formed on a sacrificial substrate. An etch stop layer is formed in the epitaxial layer. The sacrificial substrate is bonded to a handle substrate at the oxide layer. The sacrificial substrate is removed. The epitaxial layer is partially removed until the etch stop layer is exposed.