To improve field-effect mobility and reliability in a transistor including an oxide semiconductor film. A semiconductor device includes a transistor including an oxide semiconductor film. The transistor includes a region where the maximum value of field-effect mobility of the transistor at a gate voltage of higher than 0 V and lower than or equal to 10 V is larger than or equal to 40 and smaller than 150; a region where the threshold voltage is higher than or equal to minus 1 V and lower than or equal to 1 V; and a region where the S value is smaller than 0.3 V/decade.

A method of fabricating a multi-layer epitaxial buffer layer stack for transistors includes depositing a buffer stack on a substrate. A first voided Group IIIA-N layer is deposited on the substrate, and a first essentially void-free Group IIIA-N layer is then deposited on the first voided Group IIIA-N layer. A first high roughness Group IIIA-N layer is deposited on the first essentially void-free Group IIIA-N layer, and a first essentially smooth Group IIIA-N layer is deposited on the first high roughness Group IIIA-N layer. At least one Group IIIA-N surface layer is then deposited on the first essentially smooth Group IIIA-N layer.

A production method for a semiconductor device includes: forming a dielectric oxide film on a nitride semiconductor layer, where the dielectric oxide film has a higher relative permittivity than a relative permittivity of silicon dioxide; nitriding the dielectric oxide film to form a dielectric oxynitride film; forming a first silicon nitride film on the dielectric oxynitride film by a thermal film formation method; forming a second silicon nitride film on the first silicon nitride film; forming an opening in the second silicon nitride film and the first silicon nitride film, where the opening reaches the dielectric oxynitride film; and forming a gate electrode on the second silicon nitride film, where the gate electrode is in contact with the dielectric oxynitride film through the opening.

A semiconductor structure includes a substrate, a stacked structure on the substrate, an insulating layer on the stacked structure, a passivation layer on the insulating layer, and a contact structure through the passivation layer and the insulating layer and directly contacting the stacked structure. The insulating layer has an extending portion protruding from a sidewall of the passivation layer and adjacent to a surface of the stacked structure directly contacting the contact structure.

A laminated body includes: a substrate portion composed of silicon carbide; and a graphene film disposed on a first main surface of the substrate portion, the graphene film having an atomic arrangement oriented with respect to an atomic arrangement of the silicon carbide of the substrate portion. A region in which a value of G/G in Raman spectrometry is not less than 1.2 is not less than 10% in an area ratio in an exposed surface of the graphene film, the exposed surface being a main surface of the graphene film opposite to the substrate portion.

One illustrative method disclosed herein includes, among other things, forming first and second fins, respectively, for a PMOS device and an NMOS device, each of the first and second fins comprising a lower substrate fin portion made of the substrate material and an upper fin portion that is made of a second semiconductor material that is different from the substrate material, exposing at least a portion of the upper fin portion of both the first and second fins, masking the PMOS device and forming a semiconductor material cladding on the exposed upper portion of the second fin for the NMOS device, wherein the semiconductor material cladding is a different semiconductor material than that of the second semiconductor material. The method also including forming gate structures for the PMOS FinFET device and the NMOS FinFET device.

Semiconductor device stacks and devices made there from having Ge-rich device layers. A Ge-rich device layer is disposed above a substrate, with a p-type doped Ge etch suppression layer (e.g., p-type SiGe) disposed there between to suppress etch of the Ge-rich device layer during removal of a sacrificial semiconductor layer richer in Si than the device layer. Rates of dissolution of Ge in wet etchants, such as aqueous hydroxide chemistries, may be dramatically decreased with the introduction of a buried p-type doped semiconductor layer into a semiconductor film stack, improving selectivity of etchant to the Ge-rich device layers.

In various embodiments, a method of forming a graphene structure is provided. The method may include forming a body including at least one protrusion, and forming a graphene layer at an outer peripheral surface of the at least one protrusion.

Metal quantum dots are incorporated into doped source and drain regions of a MOSFET array to assist in controlling transistor performance by altering the energy gap of the semiconductor crystal. In a first example, the quantum dots are incorporated into ion-doped source and drain regions. In a second example, the quantum dots are incorporated into epitaxially doped source and drain regions.

A semiconductor device includes a buffer layer formed with a semiconductor adapted to produce piezoelectric polarization, and a channel layer stacked on the buffer layer, wherein a two-dimensional hole gas, generated in the channel layer by piezoelectric polarization of the buffer layer, is used as a carrier of the channel layer. On a complementary semiconductor device, the semiconductor device described above and an n-type field effect transistor are formed on the same compound semiconductor substrate. Also, a level shift circuit is manufactured by using the semiconductor device. Further, a semiconductor device manufacturing method includes forming a compound semiconductor base portion, forming a buffer layer on the base portion, forming a channel layer on the buffer layer, forming a gate on the channel layer, and forming a drain and source with the gate therebetween on the channel layer.