The present disclosure provides a method for fabricating a semiconductor structure, including forming an inter dielectric layer over a first region and a second region of a substrate, wherein the second region is adjacent to the first region, forming a high-k material over the inter dielectric layer in the first region and the second region, forming an oxygen capturing layer over the high-k material in the first region, and applying oxidizing agent over the oxygen capturing layer.

A method includes forming a silicon liner over a semiconductor device, which includes a dummy gate structure disposed over a substrate and S/D features disposed adjacent to the dummy gate structure, where the dummy gate structure traverses a channel region between the S/D features. The method further includes forming an ILD layer over the silicon liner, which includes elemental silicon, introducing a dopant species to the ILD layer, and subsequently removing the dummy gate structure to form a gate trench. Thereafter, the method proceeds to performing a thermal treatment to the doped ILD layer, thereby oxidizing the silicon liner, and forming a metal gate stack in the gate trench and over the oxidized silicon liner.

A method may include providing a substrate having, on a first surface of the substrate, a low dielectric constant layer characterized by a layer thickness. The method may include heating the substrate to a substrate temperature in a range of 200° C. to 550° C.; and directing an ion implant treatment to the low dielectric constant layer, while the substrate temperature is in the range of 200° C. to 550° C. As such, the ion implant treatment may include implanting a low weight ion species, at an ion energy generating an implant depth equal to 40% to 175% of the layer thickness.

A method includes forming a fin extending from a substrate; forming an first isolation region along opposing sidewalls of the fin; forming a gate structure over the fin; forming an epitaxial source/drain region in the fin adjacent the gate structure; forming an etch stop layer over the epitaxial source/drain region and over the gate structure; forming a protection layer over the etch stop layer, the protection layer including silicon oxynitride; and forming a second isolation material over the protection layer, wherein forming the second isolation material reduces a nitrogen concentration of the protection layer.

A semiconductor device manufacturing method of forming a trench and a via in a porous low dielectric constant film formed on a substrate as an interlayer insulating film, includes: embedding a polymer having a urea bond in pores of the porous low dielectric constant film by supplying a raw material for polymerization to the porous low dielectric constant film; forming the via by etching the porous low dielectric constant film; subsequently, embedding a protective filling material made of an organic substance in the via; subsequently, forming the trench by etching the porous low dielectric constant film; subsequently, removing the protective filling material; and after the forming a trench, removing the polymer from the pores of the porous low dielectric constant film by heating the substrate to depolymerize the polymer, wherein the embedding a polymer having a urea bond in pores is performed before the forming a trench.

The method includes forming a first dielectric layer on a substrate, forming a via in the first dielectric layer, sequentially forming a first metal pattern, a first metal oxide pattern, a second metal pattern, and an antireflective pattern on the first dielectric layer, and performing an annealing process to react the first metal oxide pattern and the second metal pattern with each other to form a second metal oxide pattern. The forming the second metal oxide pattern includes forming the second metal oxide pattern by a reaction between a metal element of the second metal pattern and an oxygen element of the first metal oxide pattern.

A semiconductor device includes a porous dielectric layer including a recessed portion, a conductive layer formed in the recessed portion, and a cap layer formed on the porous dielectric layer and on the conductive layer in the recessed portion, an upper surface of the porous dielectric layer being exposed through a gap in the cap layer.

A semiconductor may include a first inter metal dielectric (IMD) layer, a first blocking layer on the first IMD layer, a metal wiring and a second blocking layer. The first inter metal dielectric (IMD) layer may be formed on a substrate, the first IMD layer may include a low-k material having a dielectric constant lower than a dielectric constant of silicon oxide. The first blocking layer may be formed on the first IMD layer. The first blocking layer may include an oxide having a dielectric constant higher than the dielectric constant of the first IMD layer. The metal wiring may be through the first IMD layer and the first blocking layer. The second blocking layer may be formed on the metal wiring and the first blocking layer. The second blocking layer may include a nitride. The first and second blocking layers may reduce or prevent from the out gassing, so that a semiconductor device may have good characteristics.

Integrated circuit structures including an interconnect feature without a higher-resistance liner material. In absence of a liner, metal of low resistance directly contacts an adjacent dielectric material, enabling lower resistance interconnect. Even for low-k dielectric compositions, adhesion of the metal to the dielectric material is improved through the incorporation of nitrogen proximal to the interface. Prior to deposition of the metal upon a surface of the dielectric, the surface is exposed to nitrogen species to form a nitrogen-rich compound at the surface. The metal deposited upon the surface may then be nitrogen-lean, for example a substantially pure elemental metal or metal alloy.

The method includes forming a first dielectric layer on a substrate, forming a via in the first dielectric layer, sequentially forming a first metal pattern, a first metal oxide pattern, a second metal pattern, and an antireflective pattern on the first dielectric layer, and performing an annealing process to react the first metal oxide pattern and the second metal pattern with each other to form a second metal oxide pattern. The forming the second metal oxide pattern includes forming the second metal oxide pattern by a reaction between a metal element of the second metal pattern and an oxygen element of the first metal oxide pattern.