Methods of selectively depositing ruthenium are described. The preferred deposition surface changes based on the substrate temperature during processing. At high temperatures, ruthenium is deposited on a first surface of a conductive material over a second surface of an insulating material. At lower temperatures, ruthenium is deposited on an insulating surface over a conducting surface.

In one aspect, a system of depositing a film on a substrate is disclosed, which includes at least one metallization source for generating metal atoms, and at least one reactive source for generating at least one reactive ionic species. The system further includes a pair of inner and outer concentric cylinders, where the outer cylinder has first and second openings positioned relative to the metallization source and the reactive source to allow entry of the metal atoms and the reactive ionic species into a metallization region and a reaction region, respectively, between the two cylinders. At least one mount is coupled to the inner cylinder for mounting the substrate thereto such that said substrate is in radiative thermal communication with the inner surface of the outer cylinder, said inner cylinder being rotatable for moving the substrate between the two regions so as to expose the substrate alternatingly to said metal atoms and said reactive ionic species. Further, the outer cylinder includes at least one cooling channel through which a cooling fluid can flow for maintaining the inner surface of the outer cylinder at a temperature suitable for radiative cooling of the substrate.

In one aspect, a system for depositing a film on a substrate is disclosed, which comprises at least one metallization source for generating metal atoms, and at least one reactive source for generating at least one reactive species. The system further includes an inner cooling cylinder and a substrate cylinder, where the inner cooling cylinder is fixedly positioned relative to the substrate cylinder, and the substrate cylinder at least partially surrounds the inner cooling cylinder. At least one mount is coupled to the substrate cylinder for mounting one or more substrates to the substrate cylinder.

In one aspect, a system of depositing a film on a substrate is disclosed, which includes at least one metallization source for generating metal atoms, and at least one reactive source for generating at least one reactive ionic species. The system further includes a pair of inner and outer concentric cylinders, where the outer cylinder has first and second openings positioned relative to the metallization source and the reactive source to allow entry of the metal atoms and the reactive ionic species into a metallization region and a reaction region, respectively, between the two cylinders. At least one mount is coupled to the inner cylinder for mounting the substrate thereto such that said substrate is in radiative thermal communication with the inner surface of the outer cylinder, said inner cylinder being rotatable for moving the substrate between the two regions so as to expose the substrate alternatingly to said metal atoms and said reactive ionic species. Further, the outer cylinder includes at least one cooling channel through which a cooling fluid can flow for maintaining the inner surface of the outer cylinder at a temperature suitable for radiative cooling of the substrate.