A method for making a semiconductor device may include forming a plurality of stacked groups of layers on a semiconductor substrate, with each group of layers including a plurality of stacked base semiconductor monolayers defining a base semiconductor portion and at least one non-semiconductor monolayer constrained within a crystal lattice of adjacent base semiconductor portions. The method may further include implanting a dopant in the semiconductor substrate beneath the plurality of stacked groups of layers in at least one localized region, and performing an anneal of the plurality of stacked groups of layers and semiconductor substrate and with the plurality of stacked groups of layers vertically and horizontally constraining the dopant in the at least one localized region.

The present invention is directed to a semiconductor multilayer structure. A semiconductor multilayer structure comprises a silicon substrate, a buffer layer deposited on the silicon substrate, and the buffer layer is an aluminum contained nitride buffer layer; a superlattice layer deposited on the buffer layer, wherein the superlattice layer comprises at least a gallium nitride layer and at least a aluminum nitride layer stacked together in order, and a diffusion layer formed between the aluminum nitride layer and the gallium nitride layer, wherein the diffusion layer is an aluminum gallium nitride layer; and a epitaxy layer deposited on the superlattice layer. By utilizing the present invention, the lattice mismatch between MN and GaN of the superlattice layer can be reduced, and efficiently accumulated can be maintained without causing relaxation.

A superlattice cell that includes Group IV elements is repeated multiple times so as to form the superlattice. Each superlattice cell has multiple ordered atomic planes that are parallel to one another. At least two of the atomic planes in the superlattice cell have different chemical compositions. One or more of the atomic planes in the superlattice cell one or more components selected from the group consisting of carbon, tin, and lead. These superlattices make a variety of applications including, but not limited to, transistors, light sensors, and light sources.

The present invention provides stretchable, and optionally printable, semiconductors and electronic circuits capable of providing good performance when stretched, compressed, flexed or otherwise deformed. Stretchable semiconductors and electronic circuits of the present invention preferred for some applications are flexible, in addition to being stretchable, and thus are capable of significant elongation, flexing, bending or other deformation along one or more axes. Further, stretchable semiconductors and electronic circuits of the present invention may be adapted to a wide range of device configurations to provide fully flexible electronic and optoelectronic devices.

Techniques are disclosed for providing a low resistance self-aligned contacts to devices formed in a semiconductor heterostructure. The techniques can be used, for example, for forming contacts to the gate, source and drain regions of a quantum well transistor fabricated in III-V and SiGe/Ge material systems. Unlike conventional contact process flows which result in a relatively large space between the source/drain contacts to gate, the resulting source and drain contacts provided by the techniques described herein are self-aligned, in that each contact is aligned to the gate electrode and isolated therefrom via spacer material.

Disclosed herein are lateral gate material arrangements for quantum dot devices, as well as related computing devices and methods. For example, in some embodiments, a quantum dot device may include: a quantum well stack; and a gate above the quantum well stack, wherein the gate includes a gate electrode, the gate electrode includes a first material proximate to side faces of the gate and a second material proximate to a center of the gate, and the first material has a different material composition than the second material.

A method for making a semiconductor device may include forming spaced apart gate stacks on a substrate with adjacent gate stacks defining a respective trench therebetween. Each gate stack may include alternating layers of first and second semiconductor materials, with the layers of the second semiconductor material defining nanostructures. The method may further include forming respective source/drain regions within the trenches, respective insulating regions adjacent lateral ends of the layers of the first semiconductor material, and respective conductive contact liners in the trenches.

A transistor can include a substrate, an epitaxial oxide layer on the substrate, and a gate layer. The substrate can include a first crystalline material. The epitaxial oxide layer can include a second oxide material including: Li and one of Ni, Al, Ga, Mg, Zn and Ge; or Ni and one of Li, Al, Ga, Mg, Zn and Ge; or Mg and one of Ni, Al, Ga, and Ge; or Zn and one of Ni, Al, Ga, and Ge. The gate layer can include a third oxide material. A bandgap of the third oxide material of the gate can be wider than a bandgap of the second oxide material of the epitaxial oxide layer. The transistor can also include a source electrical contact coupled to the epitaxial oxide layer, a drain electrical contact coupled to the epitaxial oxide layer, and a first gate electrical contact coupled to the gate layer.

A method for making a semiconductor device may include forming spaced apart gate stacks on a substrate defining respective trenches therebetween. Each gate stack may include alternating layers of first and second semiconductor materials, with the layers of the second semiconductor material defining nanostructures. The method may further include forming respective source/drain regions within the trenches, forming respective insulating regions adjacent lateral ends of the layers of the first semiconductor material, and forming respective dopant blocking superlattices adjacent lateral ends of the nanostructures and flush with adjacent surfaces of the insulating regions. Each dopant blocking superlattice may include stacked groups of layers, with each group of layers including a plurality of stacked base semiconductor monolayers defining a base semiconductor portion, and at least one non-semiconductor monolayer constrained within a crystal lattice of adjacent base semiconductor portions.

A method for making semiconductor device may include forming spaced apart gate stacks on a substrate defining respective trenches therebetween. Each gate stack may include alternating layers of first and second semiconductor materials, with the layers of the second semiconductor material defining nanostructures. The method may further include forming respective source/drain regions within the trenches, forming respective insulating regions adjacent lateral ends of the layers of the first semiconductor material, and forming respective dopant blocking superlattices adjacent lateral ends of the nanostructures and offset outwardly from adjacent surfaces of the insulating regions. Each dopant blocking superlattice may include a plurality of stacked groups of layers, with each group of layers comprising stacked base semiconductor monolayers defining a base semiconductor portion, and at least one non-semiconductor monolayer constrained within a crystal lattice of adjacent base semiconductor portions.