Fan-out panel level packages (FOPLPs) comprising warpage control structures and techniques of formation are described. An FOPLP may comprise one or more redistribution layers; a semiconductor die on the one or more redistribution layers; one or more warpage control structures adjacently located next to the semiconductor die; and a mold compound encapsulating the semiconductor die and the one or more warpage control structures on the one or more redistribution layers. The FOPLP can be coupled a board (e.g., a printed circuit board, etc.). The warpage control structures can assist with minimizing or eliminating unwanted warpage, which can occur during or after formation of an FOPLP or a packaged system. In this way, the warpage control structures can assist with reducing costs associated with semiconductor packaging and/or manufacturing of an FOPLP or a packaged system.

A semiconductor device structure and a formation method are provided. The method includes forming a sacrificial base layer over a substrate and forming a semiconductor stack over the sacrificial base layer. The semiconductor stack has multiple sacrificial layers and multiple semiconductor layers laid out alternately. The method also includes forming a gate stack to partially cover the sacrificial base layer, the semiconductor layers, and the sacrificial layers. The method further includes removing the sacrificial base layer to form a recess between the substrate and the semiconductor stack. In addition, the method includes forming a metal-containing dielectric structure to partially or completely fill the recess. The metal-containing dielectric structure has multiple sub-layers.

The present disclosure describes a method of fabricating a semiconductor structure that includes forming a dummy gate structure over a substrate, forming a first spacer on a sidewall of the dummy gate structure and a second spacer on the first spacer, forming a source/drain structure on the substrate, removing the second spacer, forming a dielectric structure over the source/drain structure, replacing the dummy gate structure with a metal gate structure and a capping structure on the metal gate structure, and forming an opening in the dielectric structure. The opening exposes the source/drain structure. The method further includes forming a dummy spacer on a sidewall of the opening, forming a contact structure in the opening, and removing the dummy spacer to form an air gap between the contact structure and the metal gate structure. The contact structure is in contact with the source/drain structure in the opening.

In a method of manufacturing a semiconductor device, a gate dielectric layer is formed over a channel region, a first conductive layer is formed over the gate dielectric layer, a shield layer is formed over the first conductive layer forming a bilayer structure, a capping layer is formed over the shield layer, a first annealing operation is performed after the capping layer is formed, the capping layer is removed after the first annealing operation, and a gate electrode layer is formed after the capping layer is removed.

A method for manufacturing a semiconductor device including: a process of applying a sealing composition for a semiconductor to a semiconductor substrate, to form a sealing layer for a semiconductor on at least the bottom face and the side face of a recess portion of an interlayer insulating layer, the sealing composition including a polymer having a cationic functional group and a weight average molecular weight of from 2,000 to 1,000,000, each of the content of sodium and the content of potassium in the sealing composition being 10 ppb by mass or less on an elemental basis; and a process of subjecting a surface of the semiconductor substrate at a side at which the sealing layer has been formed to heat treatment of from 200° C. to 425° C., to remove at least a part of the sealing layer.

Provided is a method of removing native oxide from a substrate, the method including exposing the substrate to trimethyl aluminum (TMA) or dicyclopentadienyl magnesium (MgCp.sub.2) for a predetermined time.

A performance optimized CMOS FET structure and methods of manufacture are disclosed. The method includes forming source and drain regions for a first type device and a second type device. The method further includes lowering the source and drain regions for the first type device, while protecting the source and drain regions for the second type device. The method further includes performing silicide processes to form silicide regions on the lowered source and drain regions for the first type device and the source and drain regions for the second type device.

A transistor device disclosed herein includes, among other things, a gate electrode positioned above a semiconductor material region, a sidewall spacer positioned adjacent the gate electrode, a gate insulation layer having a first portion positioned between the gate electrode and the semiconductor material region and a second portion positioned between a lower portion of the sidewall spacer and the gate electrode along a portion of a sidewall of the gate electrode, an air gap cavity located between the sidewall spacer and the gate electrode and above the second portion of the gate insulation layer, and a gate cap layer positioned above the gate electrode, wherein the gate cap layer seals an upper end of the air gap cavity so as to define an air gap positioned adjacent the gate electrode.

A method of filling STI trenches with dielectric with reduced particle formation. A method of depositing unbiased STI oxide on an integrated circuit during STI trench fill that reduces STI defects during STI CMP.

The present disclosure provides a technique including a method of manufacturing a semiconductor device, which is capable of improving the characteristics of a film formed on a substrate. The method of manufacturing a semiconductor device may include: (a) forming a first film containing a predetermined element, oxygen, carbon and nitrogen on a substrate; and (b) forming a second film thinner than the first film on a top surface of the first film, the second film having an oxygen concentration lower than an oxygen concentration of the first film or having oxygen and carbon concentrations lower than oxygen and carbon concentrations of the first film.