Abstract: Semiconductor devices and methods of manufacture thereof are disclosed. In some embodiments, a method of manufacturing a semiconductor device includes forming an etch stop layer over a workpiece. The etch stop layer has an etch selectivity to a material layer of the workpiece of greater than about 4 to about 30. The method includes forming an insulating material layer over the etch stop layer, and patterning the insulating material layer using the etch stop layer as an etch stop.

Abstract: In deposition devices, a precursor is directed at a substrate within a deposition chamber, and a block plate comprising a set of block plate apertures adjusts the direction and volume of the outflowing precursor. However, arrangements of block plate apertures that are suitable for some deposition scenarios (such as one type of precursor) are unsuitable for other deposition scenarios, resulting in precursor deposition that is undesirably thick, thin, or inconsistent. A set of block plate masks positioned over respective zones of the block plate are adjustable to align a set of masking apertures with respect to the block plate apertures, such as by operating a block plate motor to rotate a ring-shaped block plate mask over a cylindrical zone of the block plate. This configuration enables adjustable exposure of the block plate apertures to control the adjusted outflow of precursor through the block plate.

Abstract: Integrated circuit devices and method of forming them. The devices include a dielectric barrier layer formed over a copper-containing metal interconnect structure. The dielectric barrier layer inhibits electro-migration of Cu. The dielectric barrier layer includes a metal-containing layer that forms an interface with the interconnect structure. Incorporating metal within the interfacial layer improves adhesion of the dielectric barrier layer to copper lines and the like and provides superior electro-migration resistance over the operating lifetime of the devices.

Abstract: An interconnect structure and a method of forming an interconnect structure are disclosed. The interconnect structure includes a lower conductive feature in a lower low-k (LK) dielectric layer; a first etch stop layer (ESL) over the lower conductive feature, wherein the first ESL comprises a metal compound; an upper LK dielectric layer over the first ESL; and an upper conductive feature in the upper LK dielectric layer, wherein the upper conductive feature extends through the first ESL and connected to the lower conductive feature. The interconnect structure may further include a second ESL between the upper LK dielectric layer and the first ESL, or between the first ESL and the lower conductive feature, wherein the second ESL comprises a silicon compound.

Abstract: The present disclosure relates to a method and apparatus for improving back-end-of-the-line (BEOL) reliability. In some embodiments, the method forms an extreme low-k (ELK) dielectric layer having one or more metal layer structures over a semiconductor substrate. A first capping layer is formed over the ELK dielectric layer at a position between the one or more metal layer structures. A second capping layer is then deposited over the one or more metal layer structures at a position that is separated from the ELK dielectric layer by the first capping layer. The first capping layer has a high selectivity that limits interaction between the second capping layer and the ELK dielectric layer, reducing diffusion of the atoms from the second capping layer to the ELK dielectric layer and improving dielectric breakdown of the ELK dielectric layer.

Abstract: A structure of a porous low-k layer is described, comprising a bottom portion and a body portion of the same atomic composition, wherein the body portion is located on the bottom portion, and the bottom portion has a density higher than the density of the body portion. An interconnect structure is also described, including the above porous low-k layer, and a conductive layer filling up a damascene opening in the porous low-k layer.

Abstract: A fabrication method of an ultra low-k dielectric layer is provided. A deposition process is performed, under the control of a temperature varying program or a pressure varying program, by reacting a dielectric matrix to form porous low-k dielectric layers with a gradient density on a barrier layer over a substrate.

Abstract: A method for manufacturing a multi cap layer includes providing a substrate, forming a multi cap layer comprising a first cap layer and a second cap layer formed thereon on the substrate, forming a patterned metal hard mask layer on the multi cap layer, and performing an etching process to etch the multi cap layer through the patterned hard mask layer and to form an opening in the second cap layer.

Abstract: A structure of a porous low-k layer is described, comprising a bottom portion and a body portion of the same atomic composition, wherein the body portion is located on the bottom portion, and the bottom portion has a density higher than the density of the body portion. An interconnect structure is also described, including the above porous low-k layer, and a conductive layer filling up a damascene opening in the porous low-k layer.

Abstract: A method of forming a porous low-k layer is described. A CVD process is conducted to a substrate, wherein a framework precursor and a porogen precursor are supplied. In an end period of the supply of the framework precursor, the value of at least one deposition parameter negatively correlated with the density of the product of the CVD process is decreased.

Abstract: A method for fabricating a porous low-k dielectric film includes providing a substrate, performing a first CVD process by providing a back-bone precursor to form an interface dielectric layer, performing a second CVD process by providing a porogen precursor to form a back-bone layer, and removing the porogen material in the back-bone layer so that the back-bone layer becomes an ultra low-k dielectric layer. The interface dielectric layer and the ultra low-k dielectric layer compose a porous low-k dielectric film.

Abstract: A fabrication method of an ultra low-k dielectric layer is provided. A deposition process is performed, under the control of a temperature varying program or a pressure varying program, by reacting a dielectric matrix to form porous low-k dielectric layers with a gradient density on a barrier layer over a substrate.

Abstract: A method for manufacturing a multi cap layer includes providing a substrate, forming a multi cap layer comprising a first cap layer and a second cap layer formed thereon on the substrate, forming a patterned metal hard mask layer on the multi cap layer, and performing an etching process to etch the multi cap layer through the patterned hard mask layer and to form an opening in the second cap layer.

Abstract: A method of forming a porous low-k layer is described. A CVD process is conducted to a substrate, wherein a framework precursor and a porogen precursor are supplied. In an end period of the supply of the framework precursor, the value of at least one deposition parameter negatively correlated with the density of the product of the CVD process is decreased.

Abstract: A method of curing a porous low-k layer is described, which is applied to a substrate with a porous low-k layer formed thereon, wherein the porous low-k: layer contains a porogen. A first UV-curing treatment is performed to the porous low-k layer under a relatively milder condition, and then a second UV-curing treatment is performed to the porous low-k layer under a relatively harsher condition to finish the curing of the porous low-k layer.

Abstract: A method for fabricating a porous low-k dielectric film includes providing a substrate, performing a first CVD process by providing a back-bone precursor to form an interface dielectric layer, performing a second CVD process by providing a porogen precursor to form a back-bone layer, and removing the porogens in the back-bone layer so that the back-bone layer becomes an ultra low-k dielectric layer. The interface dielectric layer and the ultra low-k dielectric layer compose a porous low-k dielectric film.