A rare earth-containing SiC substrate includes a rare earth element and Al. A concentration of the rare earth element is from 1×10.sup.16 atoms/cm.sup.3 to 1×10.sup.19 atoms/cm.sup.3 inclusive and a concentration of Al is from 1×10.sup.16 atoms/cm.sup.3 to 1×10.sup.21 atoms/cm.sup.3 inclusive.

Methods of forming indium gallium zinc oxide (IGZO) films by vapor deposition are provided. The IGZO films may, for example, serve as a channel layer in a transistor device. In some embodiments atomic layer deposition processes for depositing IGZO films comprise an IGZO deposition cycle comprising alternately and sequentially contacting a substrate in a reaction space with a vapor phase indium precursor, a vapor phase gallium precursor, a vapor phase zinc precursor and an oxygen reactant. In some embodiments the ALD deposition cycle additionally comprises contacting the substrate with an additional reactant comprising one or more of NH.sub.3, N.sub.2O, NO.sub.2 and H.sub.2O.sub.2.

Embodiments of the present application provide a semiconductor structure and a manufacturing method therefor. A buffer layer is disposed on a substrate layer, and the buffer layer includes a first buffer layer and a second buffer layer. By doping a transition metal in the first buffer layer, a deep level trap may be formed to capture background electrons, and diffusion of free electrons toward the substrate may also be avoided. By decreasing a doping concentration of the transition metal in the second buffer layer, a tailing effect is avoided and current collapse is prevented. By doping periodically the impurity in the buffer layer, the impurity may be as an acceptor impurity to compensate the background electrons, and then a concentration of the background electrons is reduced. By using the periodic doping method, dislocations, caused by doping, in the buffer layer may be effectively reduced.

An IC structure comprises a first transistor formed on a substrate, a first interconnect structure over the first transistor, a dielectric layer over the first interconnect structure, a plurality of 2D semiconductor islands on the dielectric layer, and a plurality of second transistors formed on the plurality of 2D semiconductor islands.

The present application provides a method of manufacturing a semiconductor structure. The manufacturing method includes following steps: at step S1: forming a first epitaxial structure above a substrate, where the first epitaxial structure is doped with a doping element; at step S2: forming a sacrificial layer above the first epitaxial structure; at step S3: etching the sacrificial layer; at step S4: growing an insertion layer above the first epitaxial structure when the etching of the sacrificial layer is completed; and at step S5: growing a second epitaxial structure above the insertion layer; before proceeding to step S4, repeating step S2 and step S3, until a concentration of the doping element in the first epitaxial structure is lower than a predetermined threshold. In the present application, sacrificial layers are formed above the first epitaxial structure, and the sacrificial layers are repeatedly etched, so that the concentration of the doping element in the first epitaxial structure is lower than the predetermined threshold, thereby preventing the doping element in the first epitaxial structure from migrating upward into an upper epitaxial structure, ensuring a mobility of electrons in the upper epitaxial structure, so as to improve a performance of a device.

A system and method for growing a gallium nitride (GaN) structure that includes providing a template; and growing at least a first GaN layer on the template using a first sputtering process, wherein the first sputtering process includes: controlling a temperature of a sputtering target, and modulating between a gallium-rich condition and a gallium-lean condition, wherein the gallium-rich condition includes a gallium-to-nitrogen ratio having a first value that is greater than 1, and wherein the gallium-lean condition includes the gallium-to-nitrogen ratio having a second value that is less than the first value. Some embodiments include a load lock configured to load a substrate wafer into the system and remove the GaN structure from the system; and a plurality of deposition chambers, wherein the plurality of deposition chambers includes a GaN-deposition chamber configured to grow at least the first GaN layer on a template that includes the substrate wafer.

Various forms of Mg.sub.xGe.sub.1-xO.sub.2-x are disclosed, where the Mg.sub.xGe.sub.1-xO.sub.2-x are epitaxial layers formed on a substrate comprising a substantially single crystal substrate material. The epitaxial layer of Mg.sub.xGe.sub.1-xO.sub.2-x has a crystal symmetry compatible with the substrate material. Semiconductor structures and devices comprising the epitaxial layer of Mg.sub.xGe.sub.1-xO.sub.2-x are disclosed, along with methods of making the epitaxial layers and semiconductor structures and devices.

The present disclosure describes epitaxial oxide high electron mobility transistors (HEMTs). In some embodiments, a HEMT comprises: a substrate; a first epitaxial semiconductor layer on the substrate; and a second epitaxial semiconductor layer on the first epitaxial semiconductor layer. The first epitaxial semiconductor layer can comprise a first oxide material, wherein the first oxide material can comprise a first polar material with an orthorhombic, tetragonal or trigonal crystal symmetry, and wherein the first oxide material can comprise a first conductivity type formed via polarization. The second epitaxial semiconductor layer can comprise a second oxide material.

Various articles and devices can be manufactured to take advantage of a what is believed to be a novel thermodynamic cycle in which spontaneity is due to an intrinsic entropy equilibration. The novel thermodynamic cycle exploits the quantum phase transition between quantum thermalization and quantum localization. Preferred devices include a phonovoltaic cell, a rectifier and a conductor for use in an integrated circuit.

A method for manufacturing a semiconductor feature includes: alternatingly forming first and second dielectric layers on a semiconductor substrate along a vertical direction; forming multiple spaced-apart trenches penetrating the first and second dielectric layers; forming multiple support segments filling the trenches; removing the second dielectric layers to form multiple spaces; forming multiple conductive layers filling the spaces; removing the support segments to expose the conductive layers and the first dielectric layers; selectively forming a blocking layer covering the first dielectric layers outside of the conductive layers; forming multiple selectively-deposited sub-layers on the exposed conductive layers outside of the blocking layer and each connected to one of the conductive layers; forming multiple channel sub-layers on the selectively-deposited sub-layers outside of the blocking layer; removing the blocking layer; forming multiple isolation sub-layers filling the trenches; and forming multiple source/drain segments each connected to corresponding ones of the channel sub-layers.