Abstract: Semiconductor device structures and methods for forming the same are provided. A method for forming a semiconductor device structure includes forming a gate structure over a semiconductor substrate. The method also includes forming spacer elements adjoining sidewalls of the gate structure. The method further includes forming a protection material layer over the gate structure. The formation of the protection material layer includes a substantial non-plasma process. In addition, the method includes depositing a dielectric material layer over the protection material layer. The deposition of the dielectric material layer includes a plasma-involved process.

Abstract: A method includes performing an implantation on a portion of a first layer to form an implanted region, and removing un-implanted portions of the first layer. The implanted region remains after the un-implanted portions of the first layer are removed. An etching is then performed on a second layer underlying the first layer, wherein the implanted region is used as a portion of a first etching mask in the etching. The implanted region is removed. A metal mask is etched using the second layer to form a patterned mask. An inter-layer dielectric is then etched to form a contact opening, wherein the patterned mask is used as a second etching mask.

Abstract: A method includes etching a semiconductor substrate to form trenches, with a portion of the semiconductor substrate between the trenches being a semiconductor strip, and depositing a dielectric dose film on sidewalls of the semiconductor strip. The dielectric dose film is doped with a dopant of n-type or p-type. The remaining portions of the trenches are filled with a dielectric material. A planarization is performed on the dielectric material. Remaining portions of the dielectric dose film and the dielectric material form Shallow Trench Isolation (STI) regions. A thermal treatment is performed to diffuse the dopant in the dielectric dose film into the semiconductor strip.

Abstract: A method includes etching a semiconductor substrate to form trenches extending into the semiconductor substrate, and depositing a first dielectric layer into the trenches. The first dielectric layer fills lower portions of the trenches. A Ultra-Violet (UV) treatment is performed on the first dielectric layer in an oxygen-containing process gas. The method further includes depositing a second dielectric layer into the trenches. The second dielectric layer fills upper portions of the trenches. A thermal treatment is performed on the second dielectric layer in an additional oxygen-containing process gas. After the thermal treatment, an anneal is performed on the first dielectric layer and the second dielectric layer.

Abstract: A method includes performing an implantation on a portion of a first layer to form an implanted region, and removing un-implanted portions of the first layer. The implanted region remains after the un-implanted portions of the first layer are removed. An etching is then performed on a second layer underlying the first layer, wherein the implanted region is used as a portion of a first etching mask in the etching. The implanted region is removed. A metal mask is etched using the second layer to form a patterned mask. An inter-layer dielectric is then etched to form a contact opening, wherein the patterned mask is used as a second etching mask.

Abstract: A method includes etching a semiconductor substrate to form trenches, with a portion of the semiconductor substrate between the trenches being a semiconductor strip, and depositing a dielectric dose film on sidewalls of the semiconductor strip. The dielectric dose film is doped with a dopant of n-type or p-type. The remaining portions of the trenches are filled with a dielectric material. A planarization is performed on the dielectric material. Remaining portions of the dielectric dose film and the dielectric material form Shallow Trench Isolation (STI) regions. A thermal treatment is performed to diffuse the dopant in the dielectric dose film into the semiconductor strip.

Abstract: A method includes etching a semiconductor substrate to form trenches extending into the semiconductor substrate, and depositing a first dielectric layer into the trenches. The first dielectric layer fills lower portions of the trenches. A Ultra-Violet (UV) treatment is performed on the first dielectric layer in an oxygen-containing process gas. The method further includes depositing a second dielectric layer into the trenches. The second dielectric layer fills upper portions of the trenches. A thermal treatment is performed on the second dielectric layer in an additional oxygen-containing process gas. After the thermal treatment, an anneal is performed on the first dielectric layer and the second dielectric layer.

Abstract: A method for forming a semiconductor device structure is provided. The method includes forming a metal gate stack over a semiconductor substrate. The method also includes performing a hydrogen-containing plasma treatment on the metal gate stack to modify a surface of the metal gate stack. The hydrogen-containing plasma treatment includes exciting a gas mixture including a first hydrogen-containing gas and a second hydrogen-containing gas to generate a hydrogen-containing plasma.

Abstract: A method for forming a semiconductor device structure is provided. The method includes forming a metal gate stack over a semiconductor substrate. The method also includes performing a hydrogen-containing plasma treatment on the metal gate stack to modify a surface of the metal gate stack. The hydrogen-containing plasma treatment includes exciting a gas mixture including a first hydrogen-containing gas and a second hydrogen-containing gas to generate a hydrogen-containing plasma.

Abstract: A method is disclosed that includes the operations outlined below. An insulating material is disposed within a plurality of trenches on a semiconductor substrate and over the semiconductor substrate. The first layer is formed over the insulating material. The first layer and the insulating material are removed.

Abstract: A method includes forming a first polysilicon structure over a first portion of a substrate. A second polysilicon structure is formed over a second portion of the substrate. Two spacers are formed on opposite sidewalls of the second polysilicon structure. A layer of protective material is formed to cover the first and second portions of the substrate. The layer of protective material has a first thickness over the second polysilicon structure and a second thickness over the two spacers. The first thickness is equal to or greater than 500 ?, and the second thickness is equal to or less than 110% of the first thickness. A patterned photo resist layer is formed to cover a first portion of the layer of protective material that covers the first portion of the substrate. The second portion of the layer of protective material is removed.

Abstract: A method is disclosed that includes the operations outlined below. An insulating material is disposed within a plurality of trenches on a semiconductor substrate and over the semiconductor substrate. The first layer is formed over the insulating material. The first layer and the insulating material are removed.

Abstract: A method for capping over a doped dielectric. The method comprises providing a substrate and depositing a doped dielectric layer on the substrate from a gas mixture. The gas mixture comprises a silicon source gas, a dopant gas and an oxygen source gas. A cap layer is in-situ deposited on the doped dielectric layer from the gas mixture substantially in absence of the dopant gas.

Abstract: A method of reducing copper hillocks in copper metallization is described. An opening is made through a dielectric layer overlying a substrate on a wafer. A copper layer is formed overlying the dielectric layer and completely filling the opening. The copper layer is polished back to leave the copper layer only within the opening. Copper hillocks are reduced by applying F ions to the copper layer to form a buffer zone on a surface of the copper layer and in-situ depositing a capping layer overlying the copper layer. The F ions remove copper oxide naturally formed on the copper surface and the buffer zone transfers thermal vertical strain in the copper to horizontal strain thereby preventing formation of copper hillocks.