A semiconductor device includes; a substrate including a first region and a second region, a first active pattern extending upward from the first region, a first superlattice pattern on the first active pattern, a first active fin centrally disposed on the first active pattern, a first gate electrode disposed on the first active fin, and first source/drain patterns disposed on opposing sides of the first active fin and on the first active pattern. The first superlattice pattern includes at least one first semiconductor layer and at least one first blocker-containing layer, and the first blocker-containing layer includes at least one of oxygen, carbon, fluorine and nitrogen.

Methods and structures for forming flat, continuous, planar, epitaxial layers of semipolar III-nitride materials on patterned sapphire substrates are described. Semipolar GaN may be grown from inclined c-plane facets on a patterned sapphire substrate, and coalesced to form a continuous layer of semipolar III-nitride semiconductor over the sapphire substrate. Planarization of the layer is followed by crystal regrowth using a nitrogen carrier gas to produce a flat, microfabrication-grade, process surface of semipolar III-nitride semiconductor across the substrate. Quality multiple quantum wells can be fabricated in the regrown semipolar material.

Methods and structures for forming strained-channel finFETs are described. Fin structures for finFETs may be formed in two epitaxial layers that are grown over a bulk substrate. A first thin epitaxial layer may be cut and used to impart strain to an adjacent channel region of the finFET via elastic relaxation. The structures exhibit a preferred design range for increasing induced strain and uniformity of the strain over the fin height.

Embodiments described herein generally relate to methods and apparatus for horizontal gate all around (hGAA) isolation. A superlattice structure comprising different materials arranged in an alternatingly stacked formation may be formed on a substrate. The different materials may be silicon containing materials and one or more III/V materials. In one embodiment, at least one of the layers of the superlattice structure may be oxidized to form a buried oxide layer adjacent the substrate.

A CMOS device includes a PMOS transistor with a first quantum well structure and an NMOS device with a second quantum well structure. The PMOS and NMOS transistors are formed on a substrate.

An epitaxial structure for a high-electron-mobility transistor includes a substrate, a nucleation layer, a buffer layered unit, a channel layer, and a barrier layer sequentially stacked on one another in such order. The buffer layered unit includes a plurality of p-i-n heterojunction stacks. Each of the p-i-n heterojunction stacks includes p-type, i-type, and n-type layers which are made of materials respectively represented by chemical formulas of Al.sub.xGa.sub.(1-x)N, Al.sub.yGa.sub.(1-y)N, and Al.sub.zGa.sub.(1-z)N. For each of the p-i-n heterojunction stacks, x decreases and z increases along a direction away from the nucleation layer, and y is consistent and ranges from 0 to 0.7.

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 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 method is provided for operating a fractional quantum Hall apparatus including a set of interferometers, each having a cell and a set of gate electrodes located around the cell. The method includes calibrating each one of the interferometers to confine a droplet of a 2D charge carrier gas in a fractional quantum Hall effect state of filling factor 17/5 or 12/5, while a reentrant phase of integer quantum Hall effect states of the 2D charge carrier gas is located between the area of the droplet in a fractional quantum Hall effect state and the interferometer electrodes. The calibrating includes setting a value of a magnetic field across the apparatus such that the reentrant phase and the droplet of the 2D charge carrier gas are present in at least one of the interferometers based on interference measurements on at least one of the interferometers for different values of the magnetic field.

The present invention relates to the inspection process which includes providing access to the microdevice contacts, measuring the microdevice and analyzing the data to identify defects or performance of the micro device. The invention also relates to the forming of test electrodes on microdevices. The test electrodes may be connected to hidden contacts. The type of microdevices may be vertical, lateral or a flip chip.