There are provided (a) heat-treating a substrate including a film containing a group 14 element at a first temperature; (b) heat-treating the substrate at a second temperature higher than the first temperature; and (c) exposing the substrate to a treatment agent containing at least one of O and H after performing (a) and before performing (b).

In a described example, an integrated circuit (IC) is disclosed that includes a transistor. The transistor includes a substrate, and a buffer structure overlying the substrate. The buffer structure has a first buffer layer, a second buffer layer overlying the first buffer layer, and a third buffer layer overlying the second buffer layer. The first buffer layer has a first carbon concentration, the second buffer layer has a second carbon concentration lower than the first carbon concentration, and the third buffer layer has a third carbon concentration higher than the second carbon concentration. An active structure overlies the buffer structure.

Disclosed are methods of forming PN junction structures, methods of fabricating semiconductor devices using the same, and semiconductor devices fabricated by the same. The method of forming a PN junction structure includes: forming on a substrate a first material layer that includes first transition metal atoms and first chalcogen atoms, loading the first material layer into a process chamber and supplying a gas of second chalcogen atoms, and forming a second material layer by substituting the second chalcogen atoms for the first chalcogen atoms on a selected portion of the first material layer. The first material layer has one of n-type conductivity and p-type conductivity. The second material layer has the other of the n-type conductivity and the p-type conductivity.

A semiconductor device includes a substrate, and a first transistor disposed on the substrate. The first transistor includes a first channel layer, a magnesium oxide layer, a first gate electrode, a first gate dielectric and first source/drain electrodes. A crystal orientation of the first channel layer is <100> or <110>. The magnesium oxide layer is located below the first channel layer and in contact with the first channel layer. The first gate electrode is located over the first channel layer. The first gate dielectric is located in between the first channel layer and the first gate electrode. The first source/drain electrodes are disposed on the first channel layer.

A method of forming a support substrate having a charge-trapping layer involves introducing a single-crystal silicon base substrate into a deposition chamber and, without removing the base substrate from the chamber and while flushing the chamber with a precursor gas, forming an intrinsic silicon epitaxial layer on the base substrate, then forming a dielectric layer on the base substrate by introducing a reactive gas into the chamber over a first time period, and then forming a polycrystalline silicon charge-trapping layer on the dielectric layer by introducing a precursor gas into the chamber over a second time period. The time for which the dielectric layer is exposed only to the carrier gas, between the first time period and the second time period, is less than 30 seconds and the formation of the charge-trapping layer is performed at a temperature of between 1010 C. and 1200 C.

A crystalline IZTO oxide semiconductor and a thin film transistor having the same are provided. The thin film transistor includes a gate electrode, a crystalline InZnSn oxide (IZTO) channel layer overlapping the upper or lower portions of the gate electrode and having hexagonal crystal grains, and a gate insulating layer disposed between the gate electrode and the IZTO channel layer, and source and drain electrodes respectively connected to both ends of the IZTO channel layer.

A heteroepitaxial semiconductor device includes a bulk semiconductor substrate, a seed layer including a first semiconductor material, the seed layer being arranged at a first side of the bulk semiconductor substrate and including a first side facing the bulk semiconductor substrate, an opposing second side and lateral sides connecting the first and second sides, a separation layer arranged between the bulk semiconductor substrate and the seed layer, a heteroepitaxial structure grown on the second side of the seed layer and including a second semiconductor material, different from the first semiconductor material, and a dielectric material layer arranged on the seed layer and at least partially encapsulating the heteroepitaxial structure, wherein the dielectric material layer also covers the lateral sides of the seed layer.

Deep trench isolation structures for high voltage semiconductor-on-insulator devices are disclosed herein. An exemplary deep trench isolation structure surrounds an active region of a semiconductor-on-insulator substrate. The deep trench isolation structure includes a first insulator sidewall spacer, a second insulator sidewall spacer, and a multilayer silicon-comprising isolation structure disposed between the first insulator sidewall spacer and the second insulator sidewall spacer. The multilayer silicon-comprising isolation structure includes a top polysilicon portion disposed over a bottom silicon portion. The bottom polysilicon portion is formed by a selective deposition process, while the top polysilicon portion is formed by a non-selective deposition process. In some embodiments, the bottom silicon portion is doped with boron.

Exemplary semiconductor structures may include a silicon-containing substrate. The structures may include a layer of a metal nitride overlying the silicon-containing substrate. The structures may include a gallium nitride structure overlying the layer of the metal nitride. The structures may include an oxygen-containing layer disposed between the layer of the metal nitride and the gallium nitride structure.

A method for manufacturing a gallium nitride film includes the steps of placing a substrate so as to face a target containing nitrogen and gallium in a vacuum chamber, supplying a sputtering gas into the vacuum chamber, supplying a nitrogen radical into the vacuum chamber, generating a plasma of the sputtering gas by application of a voltage to the target, generating a gallium ion by a collision of an ion of the sputtering gas with the target, and stopping the application of the voltage to the target and depositing gallium nitride on the substrate. The gallium nitride is generated by a reaction of the gallium ion with a nitrogen anion which is generated by a reaction of an electron in the vacuum chamber with the nitrogen radical.