Provided are methods and structures for keeping the integrity of layers deposited on a semiconductor wafer through a thermal cycle. Deposition of a second backside layer, or a cap, with an internal stress opposite to a first backside layer may be used to reduce bow shift of a wafer during a thermal cycle. The first backside layer may have a tensile internal stress or a compressive internal stress. The second backside layer has an internal stress opposite to the first backside layer. Each of the backside layers may be deposited by a backside deposition apparatus.

A silicon-on-insulator substrate includes: (1) a high-resistivity base layer including silicon and a trap-rich region including arsenic diffused within a first side of the high-resistivity base layer, wherein the trap-rich region has a thickness that is in a range of 1 to 10 microns and a trap density that is in a range of 0.8*10.sup.10 cm.sup.2 eV.sup.1 to 1.2*10.sup.10 cm.sup.2 eV.sup.1, wherein the high-resistivity base layer has resistivity in a range of 50 to 100 ohm-meters and a thickness in a range of 500 to 700 microns; (2) a silicon dioxide layer positioned on the first side of the high-resistivity base layer and having a thickness that is in a range of 1000 to 5000 angstroms; and (3) a transfer layer positioned on the silicon dioxide layer, wherein the transfer layer comprises a silicon wafer having a thickness that is a range of 500 to 5000 angstroms.

A method for fabricating a semiconductor device includes: forming a first oxide layer containing a first element over a first electrode layer; forming a second oxide layer containing a second element over the first oxide layer; forming a stacked structure in which a plurality of first oxide layers and a plurality of second oxide layers are alternately stacked by repeating the forming of the first oxide layer and the forming of the second oxide layer a plurality of times; and forming a second electrode layer over the stacked structure, wherein a thickness of a lowermost first oxide layer among the plurality of first oxide layers is greater than a thickness of each of other first oxide layers.

A capacitor is provided for high temperature systems. The capacitor includes: a substrate formed from silicon carbide material; a dielectric stack layer, including a first layer deposited on the substrate and a second layer deposited on the first layer; a Schottky contact layer deposited on the second layer; and an Ohmic contact layer deposited on the substrate. The first layer is formed with aluminum nitride (AlN) epitaxially, and the second layer is formed with aluminum oxide (Al.sub.2O.sub.3). AlN and Al.sub.2O.sub.3 are ultrawide band gap materials, and as a result, they can be use as the dielectric in the capacitor, allowing the capacitance changes to be less than 10% between 250 C. and 600 C., which is very effective for the high temperature systems.

A method of forming a semiconductor device includes: forming a dummy gate structure over a fin structure that protrudes above a substrate, where the fin structure includes a fin and a layer stack over the fin, where the layer stack comprises alternating layers of a first semiconductor material and a second semiconductor material; forming openings in the fin structure on opposing sides of the dummy gate structure, where the openings exposes first portions of the first semiconductor material and second portions of the second semiconductor material; recessing the exposed first portions of the first semiconductor material to form sidewall recesses in the first semiconductor material; lining the sidewall recesses with a first dielectric material; depositing a second dielectric material in the sidewall recesses on the first dielectric material; after depositing the second dielectric material, annealing the second dielectric material; and after the annealing, forming source/drain regions in the openings.

A method for manufacturing a semiconductor device with high productivity is provided. The method includes a step of forming a first insulator, a second insulator, and a third insulator in this order using a multi-chamber apparatus; a step of forming a fourth insulator, a fifth insulator, a first oxide film, a second oxide film, and a third oxide film in this order using a multi-chamber apparatus; a step of forming a conductive film; a step of processing the first oxide film, the second oxide film, the third oxide film, and the conductive film, thereby forming a first oxide, a second oxide, an oxide layer, and a conductive layer each having an island shape; a step of forming a sixth insulator and an insulating film in this order using a multi-chamber apparatus; a step of planarizing the insulating film; a step of forming, in the insulating film and the sixth insulator, an opening where the second oxide is exposed; a step of forming a seventh insulator and a first conductor; and a step of forming an eighth insulator and a ninth insulator in this order using a multi-chamber apparatus.

A semiconductor device includes a substrate, a channel region, a source/drain feature, a gate structure, a dielectric structure, a first crystalline hard mask layer, and a first amorphous hard mask layer. The channel region is disposed over a substrate. The isolation feature is disposed over the substrate and alongside the channel region. The source/drain feature interfaces a sidewall of the channel region, wherein the source/drain feature and the channel region are disposed along a first direction, and along a second direction different from the first direction. The gate structure is disposed over the channel region. The dielectric structure is disposed over the isolation feature and interfaces the source/drain feature. The first crystalline hard mask layer is disposed over the dielectric structure. The first amorphous hard mask layer is disposed in the first crystalline hard mask layer.

Disclosed are a layer structure including a dielectric layer, a method of manufacturing the dielectric layer, an electronic device including the dielectric layer, and an electronic apparatus including the electronic device. The dielectric layer according to at least one embodiment includes a first layer having a dielectric constant greater than that of silicon oxide and is undoped, a second layer configured to enhance a rutile phase of the first layer, and a third layer configured to increase a bandgap of the first layer. The method of manufacturing a dielectric layer according to an embodiment includes forming a first layer having a dielectric constant greater than that of silicon oxide; forming a phase stabilization layer for stabilizing a rutile phase of the first layer and forming a high-bandgap layer for increasing a bandgap of the first layer.

A method of manufacturing a structure for power electronics which includes epitaxially growing a GaN semiconductor layer is provided. The method includes growing buffer layers formed of AlN and Al.sub.xGa.sub.(1-x)N, wherein 0<x<1, on a Si substrate before growing the semiconductor layer on the buffer layers. The method also includes growing deformation compensation layers formed of SiO.sub.2, SiC.sub.xN.sub.(1-x), SiN, SiC.sub.xO.sub.(1-x), SiC, SiN.sub.xO.sub.(1-x), Al.sub.2O.sub.3, and/or Cr.sub.2O.sub.3, wherein 0<x<1, on the substrate opposite the semiconductor layer. The deformation compensation layers compensate for deformation of the structure that occurs while growing the semiconductor and buffer layers and deformation that occurs while cooling the structure. The method further includes estimating epitaxial growth stress, interface stress, and thermal stress of the structure, and adjusting the temperature and or thickness of the layers based on the estimated epitaxial growth stress, interface stress, and/or thermal stress.

Dielectric films for semiconductor devices and methods of forming. A processing method includes forming a first film of a first dielectric material on a substrate by performing a first plurality of cycles of atomic layer deposition and, thereafter, heat-treating the first film, where a thickness of the first film is below a threshold thickness needed for spontaneous polarization in the first dielectric material. The processing method further includes forming a second film of a second dielectric material on the substrate by performing a second plurality of cycles of atomic layer deposition and, thereafter, heat-treating the second film, where a thickness of the second film is greater than the thickness of the first film, and the second film is ferroelectric or antiferroelectric. The first and second dielectric materials can include at least one metal oxide, for example zirconium oxide, hafnium oxide, or a laminate or mixture thereof.