A method for depositing a film includes conducting electron-enhanced chemical vapor deposition with at least one hydride precursor, at least one reactive background gas, and electrons to deposit a film on a substrate with a positive substrate voltage. In an embodiment, the method is a method for depositing a silicon film, including conducting electron-enhanced chemical vapor deposition with at least one Si precursor, at least one reactive background gas, and electrons to deposit a silicon film on a substrate with a positive substrate voltage. In the embodiment, the at least one Si precursor can include Si.sub.2H.sub.6 and the at least one reactive background gas can include H.sub.2.

Semiconductor devices having necked semiconductor bodies and methods of forming semiconductor bodies of varying width are described. For example, a semiconductor device includes a semiconductor body disposed above a substrate. A gate electrode stack is disposed over a portion of the semiconductor body to define a channel region in the semiconductor body under the gate electrode stack. Source and drain regions are defined in the semiconductor body on either side of the gate electrode stack. Sidewall spacers are disposed adjacent to the gate electrode stack and over only a portion of the source and drain regions. The portion of the source and drain regions under the sidewall spacers has a height and a width greater than a height and a width of the channel region of the semiconductor body.

Embodiments of the disclosure are in the field of advanced integrated circuit structure fabrication and, in particular, 10 nanometer node and smaller integrated circuit structure fabrication and the resulting structures. In an example, an integrated circuit structure includes a first plurality of semiconductor fins having a longest dimension along a first direction. Adjacent individual semiconductor fins of the first plurality of semiconductor fins are spaced apart from one another by a first amount in a second direction orthogonal to the first direction. A second plurality of semiconductor fins has a longest dimension along the first direction. Adjacent individual semiconductor fins of the second plurality of semiconductor fins are spaced apart from one another by the first amount in the second direction, and closest semiconductor fins of the first plurality of semiconductor fins and the second plurality of semiconductor fins are spaced apart by a second amount in the second direction.

A variety of applications can include apparatus having p-channel metal-oxide-semiconductor (PMOS) transistors and n-channel metal-oxide-semiconductor (NMOS) transistors with different metal silicide contacts. The active area of the NMOS transistor can include a first metal silicide having a first metal element, where the first metal silicide is a vertical lowest portion of a contact for the NMOS. The PMOS transistor can include a stressor source/drain region to a channel region of the PMOS transistor and a second metal silicide directly contacting the stressor source/drain region without containing the first metal element. The process flow to form the PMOS and NMOS transistors can enable making simultaneous contacts by a pre-silicide in the active area of the NMOS transistor, without affecting stressor source/drain regions in the PMOS transistor. The process flow and resulting structures for PMOS transistors and NMOS transistors can be used in various integrated circuits and devices.

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.

Embodiments described herein generally relate to semiconductor device fabrication, and more particularly, to systems and methods that include initial etching and fast etching. In one or more embodiments, a method of substrate processing includes etching a layer of a substrate using a first pressure and a first composition including hydrogen chloride. The etching includes flowing the first composition for a first time period and at a first flow rate. The method includes etching the layer using a second pressure and a second composition including chlorine (Cl2) gas, and the etching includes flowing the second composition for a second time period less than the first time period and at a second flow rate less than the first flow rate. The second time period is a time ratio of the first time period, and the time ratio is 1:15 or less.

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 laser crystallization monitoring device includes a stage that supports a substrate, a laser beam generator that emits a laser beam to the substrate, a mirror that reflects the laser beam emitted from the laser beam generator and that rotates around a rotation axis, a first telecentric f-theta lens located on the laser beam path between the mirror and the substrate, a second telecentric f-theta lens through which the laser beam reflected from the substrate passes, and a monitor that inspects the laser beam passing through the second telecentric f-theta lens.

A method of manufacturing a display device includes forming a first amorphous silicon layer on a substrate on which a first area and a second area are defined, forming a mask in the second area on the first amorphous silicon layer, forming a preliminary second amorphous silicon layer on the first amorphous silicon layer and the mask, forming a second amorphous silicon layer by removing a portion of the preliminary second amorphous silicon layer on the mask, removing the mask, and forming a polycrystalline silicon layer by crystallizing the first amorphous silicon layer and the second amorphous silicon 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.