Abstract: The present invention generally provides a method for processing a substrate having exposed surfaces of titanium and/or silicon prior to deposition of aluminum. The substrate is positioned adjacent a process zone which provides a nitrogen plasma so that exposed areas of titanium and silicon on the substrate are stuffed with nitrogen to form titanium nitride (TiN) and various compounds of silicon and nitrogen (Si.sub.x N.sub.y), respectively. The nitrogen treated surfaces, i.e, TiN and silicon/nitrogen compounds, are resistant to interaction with aluminum. In this manner, the formation of electrically insulating TiAl.sub.3 and/or the spiking of silicon is reduced or eliminated.

Abstract: A method of stabilizing a halogen-doped silicon oxide film to reduce halogen atoms migrating from said film during subsequent processing steps. A halogen-doped film is deposited over a substrate and then subjected to a degassing step in which the film is briefly heated to a temperature of between about 300 and 550.degree. C. before deposition of a diffusion barrier layer. It is believed that such a heat treatment step removes loosely bonded halogen atoms from the halogen-doped film and thus the treatment is referred to as a degassing step. In a preferred version of this embodiment, the halogen-doped silicon oxide film is an FSG film that is subjected to a degassing treatment for between about 35 and 50 seconds.

Abstract: The present invention relates generally to an improved apparatus and process for providing uniform step coverage on a substrate and planarization of metal layers to form continuous, void-free contacts or vias in sub-half micron aperture width applications. In one aspect of the invention, a dielectric layer is formed over a conducting member. A thin nucleation layer is then deposited onto the dielectric layer prior to etching high aspect ratio apertures through the nucleation and dielectric layers to expose the underlying conducting member on the aperture floor. A CVD metal layer is then deposited onto the structure to achieve selective deposition within the apertures, while preferably also forming a blanket layer on the field. The present apparatus and process reduce the number of steps necessary to fabricate CVD metal interconnects and layers that are substantially void-free and planarized.

Abstract: The present invention relates generally to an improved apparatus and process for providing uniform step coverage on a substrate and planarization of conducting layers to form continuous, void-free interconnects in sub-half micron, high aspect ratio aperture width applications and highly oriented conducting layers. In one aspect of the invention, a dielectric layer is formed over a conducting or semiconducting layer and etched to form an aperture exposing the underlying conducting or semiconducting layer on the aperture floor. An ultra-thin nucleation layer is then deposited by physical vapor deposition onto the field of the dielectric layer. A CVD metal layer is then deposited onto the structure to achieve selective deposition on the floor of the aperture, while preferably also forming a highly oriented blanket layer on the field. The present apparatus and process reduce the number of steps necessary to fabricate CVD metal interconnects and layers that are substantially void-free and planarized.

Abstract: The present invention is a method for semi-selectively depositing a material on a substrate by chemical vapor deposition to form continuous, void-free contact holes or vias in sub-half micron applications. An insulating layer is preferentially deposited on the field of a substrate to delay or inhibit nucleation of metal on the field. A CVD metal is then deposited onto the substrate and grows selectively in the contact hole or via where a barrier layer serves as a nucleation layer. The process is preferably carried out in a multi-chamber system that includes both PVD and CVD processing chambers so that once the substrate is introduced into a vacuum environment, the filling of contact holes and vias occurs without the formation of an oxide layer on a patterned substrate.

Abstract: The present invention generally provides a metallization process for forming a highly integrated interconnect. More particularly, the present invention provides a dual damascene interconnect module that incorporates a barrier layer deposited on all exposed surface of a dielectric layer which contains a dual damascene via and wire definition. A conductive metal is deposited on the barrier layer using two or more deposition methods to fill the via and wire definition prior to planarization. The invention provides the advantages of having copper wires with lower resistivity (greater conductivity) and greater electromigration resistance than aluminum, a barrier layer between the copper wire and the surrounding dielectric material, void-free, sub-half micron selective CVD Al via plugs, and a reduced number of process steps to achieve such integration.

Abstract: A process for fabricating electronic devices which includes the steps of providing a structure that includes a substrate with an overlying dielectric layer having one or more contact holes and/or vias formed therein; depositing a barrier layer over the structure so that the barrier layer penetrates into the contact holes and/or vias; plasma etching the deposited barrier layer so as to modify its surface morphology; and after modifying the surface morphology of the deposited barrier layer, depositing a metalization layer over the barrier layer. A two-step preclean to facet upper corners of the holes and/or vias and to clean bottoms of the holes and/or vias is performed prior to the deposition of the barrier layer.

Abstract: The present invention relates generally to an improved process for providing uniform step coverage on a substrate and planarization of metal layers to form continuous, void-free contacts or vias in sub-half micron applications. In one aspect of the invention, a refractory layer is deposited onto a substrate having high aspect ratio contacts or vias formed thereon. A CVD metal layer is then deposited onto the refractory layer at low temperatures to provide a conformal wetting layer for a PVD metal. Next, a PVD metal is deposited onto the previously formed CVD metal layer at a temperature below that of the melting point temperature of the metal. The resulting CVD/PVD metal layer is substantially void-free.

Abstract: A method of stabilizing a halogen-doped silicon oxide film to reduce halogen atoms migrating from said film during subsequent processing steps. A halogen-doped film is deposited over a substrate and then subjected to a degassing step in which the film is briefly heated to a temperature of between about 300.degree. and 550.degree. C. before deposition of a diffusion barrier layer. It is believed that such a heat treatment step removes loosely bonded halogen atoms from the halogen-doped film and thus the treatment is referred to as a degassing step. In a preferred version of this embodiment, the halogen-doped silicon oxide film is an FSG film that is subjected to a degassing treatment for between about 35 and 50 seconds.