A method of processing a substrate, includes: loading the substrate having a silicon-containing film formed thereon into a processing container; a first process of modifying the silicon-containing film by supplying a processing gas containing a halogen-containing gas and a basic gas to the substrate, in a state in which an internal pressure of the processing container is set to a first pressure, to generate a reaction product; a second process of vaporizing the reaction product by setting the internal pressure of the processing container to a second pressure lower than the first pressure; and alternately repeating the modifying the silicon-containing film and the vaporizing the reaction product, wherein subsequent rounds of the first process following the initial first process in the alternately repeating the modifying the silicon-containing film and the vaporizing the reaction product includes supplying the processing gas to the substrate on which the reaction product remains.

Semiconductor devices and methods of fabricating semiconductor devices are provided. The present disclosure provides a semiconductor device that includes a first fin structure and a second fin structure each extending from a substrate; a first gate segment over the first fin structure and a second gate segment over the second fin structure; a first isolation feature separating the first and second gate segments; a first source/drain (S/D) feature over the first fin structure and adjacent to the first gate segment; a second S/D feature over the second fin structure and adjacent to the second gate segment; and a second isolation feature also disposed in the trench. The first and second S/D features are separated by the second isolation feature, and a composition of the second isolation feature is different from a composition of the first isolation feature.

There is provided a technique that includes: modifying a surface of first base exposed on a substrate by supplying modifying gas including the first base and second base exposed on the substrate; and selectively forming a film containing at least first element and second element different from the first element on a surface of the second base by supplying precursor gas to the substrate after the surface of the first base is modified, under condition that film-forming reaction by thermal decomposition of the precursor gas does not substantially occur, the precursor gas containing a compound in which atoms of the first element are contained in one molecule, at least one atom of the second element is interposed between two atoms of the first element, and each of the two atoms of the first element is directly bonded to one of the at least one atom of the second element.

There is provided a technique that includes: (a) modifying a surface of a first base exposed on a surface of a substrate to be terminated with a hydrocarbon group by supplying a hydrocarbon group-containing gas to the substrate having the first base and a second base exposed on the surface of the substrate; and (b) selectively forming a film on a surface of the second base by supplying an oxygen- and hydrogen-containing gas to the substrate after modifying the surface of the first base.

Systems, apparatuses, and methods related to semiconductor structure formation are described. An example apparatus includes a structural material for a semiconductor device. The structural material includes an orthosilicate derived oligomer having a number of oxygen (O) atoms each chemically bonded to one of a corresponding number of silicon (Si) atoms and a chemical bond formed between an element from group 13 of a periodic table of elements (e.g., B, Al, Ga, In, and Tl) and the number of O atoms of the orthosilicate derived oligomer. The chemical bond crosslinks chains of the orthosilicate derived oligomer to increase mechanical strength of the structural material, relative to the structural material formed without the chemical bond to crosslink the chains, among other benefits described herein.

A composition for use in selective modification of a base material surface includes a polymer having, at an end of a main chain or a side chain thereof, a group including a first functional group capable of forming a bond with a metal, and a solvent.

The present invention relates to new aromatic-amino functional siloxanes, which are compounds comprising one or two tail groups X.sub.2, and a linking group L of structure (2) linking each said tail group to said head group, wherein the head group X has structure (1), containing an optional organic moiety Y, wherein the attachment point of said tail group X.sub.2 through said linking group L to the head group X.sub.1, may be, at positions a, b, c, d, or e. Another aspect of this invention are compositions containing these novel aromatic amino functional siloxane. A further aspect of this invention are compositions comprised of the above novel aromatic-amino functional siloxanes, and also the composition resulting from the aging of these compositions at room temperature for about 1 day to about 4 weeks. Still further aspects of this invention are processes for forming self-assembled monolayers on a substrate, from the aged composition, and also the processes of coating these aged compositions on patterned porous dielectrics to cap them also the processes of metallization of these capped pattered porous dielectrics. ##STR00001##

A method for improving EUV lithographic patterning of SnO.sub.2 layers is provided. One method embodiment includes introducing a hydrophobic surface treatment compound into a processing chamber for modifying a surface of an SnO.sub.2 layer. The modification increases the hydrophobicity of the SnO.sub.2 layer. The method also provides for depositing a photoresist layer on the surface of the SnO.sub.2 layer via spin coating. The modification of the surface of the SnO.sub.2 layer enhances adhesion of contact between the photoresist and the SnO.sub.2 layer during and after spin coating.

A technique includes: (a) modifying a surface of a first base exposed on a surface of a substrate to be terminated with a hydrocarbon group by supplying a hydrocarbon group-containing gas to the substrate having the first base and a second base exposed on the surface of the substrate; and (b) forming a film on a surface of the second base by supplying an oxygen- and hydrogen-containing gas to the substrate after modifying the surface of the first base.

A method for forming a semiconductor device and a semiconductor device formed by the method are disclosed. In an embodiment, the method includes depositing a dummy dielectric layer on a fin extending from a substrate; depositing a dummy gate seed layer on the dummy dielectric layer; reflowing the dummy gate seed layer; etching the dummy gate seed layer; and selectively depositing a dummy gate material over the dummy gate seed layer, the dummy gate material and the dummy gate seed layer constituting a dummy gate.