Abstract: Methods, and products formed by such methods, of forming a self-aligned conductive pillar (16) on an interconnect (12) on a body (10) having semiconducting surfaces. A first mask (24) defines an inverse pattern for formation of an interconnect (12). The interconnect (12) is formed by additive metallization processes. A second mask (26) is formed over portions of the first mask (24) and the interconnect (12). Sidewalls of the first mask (24) which define at least one side of side of said interconnect (12) serve to also define at least one side of said conductive pillar (16). The second mask (26) also defines at least one side of the conductive pillar (16). The conductive pillar (16) is formed by additive metal deposition processes. The conductive pillar (16) is thus self-aligned to the interconnect (12) on which it is formed.

Abstract: A metal stud (24) is provided for interconnecting levels of metallization separated by an insulator on a semiconductor slice (10). A lead (12) is coated with a refractory metal (14) and a platable metal cap (16). A photoresist (18) is then applied and a cavity (22) is formed within the photoresist (18). The cavity (22) is plated to form the stud (24). The stud (24) is clad with a corrosion resistant layer (28).

Abstract: A metal stud (24) is provided for interconnecting levels of metallization separated by an insulator on a semiconductor slice (10). A lead (12) is coated with a refractory metal (14) and a platable metal cap (16). A photoresist (18 ) is then applied and a cavity (22) is formed within the photoresist (18 ). The cavity (22) is plated to form the stud (24). The stud (24) is clad with a corrosion resistant layer (28).

Abstract: Methods, of forming a self-aligned conductive pillar (16) on an interconnect (12) on a body (10) having semiconducting surfaces. A first mask (24) defines an inverse pattern for formation of an interconnect (12). The interconnect (12) is formed by additive metallization processes. A second mask (26) is formed over portions of the first mask (24) and the interconnect (12). Sidewalls of the first mask (24) which define at least one side of side of said interconnect (12) serve to also define at least one side of said conductive pillar (16). The second mask (26) also defines at least one side of the conductive pillar (16). The conductive pillar (16) is formed by additive metal deposition processes. The conductive pillar (16) is thus self-aligned to the interconnect (12) on which it is formed. A cladding layer of tungsten (40) can be used on the multiple layers of seed layer (22), e.g. molybdenum coated with thin copper, of copper interconnects (12/14), and of conductive pillars (16/18).

Abstract: Metal contacts and interconnections for integrated circuits utilize copper as the primary conductor, with the copper being totally encased in refractory metal layers on both top and bottom surfaces and also sidewalls. The contact hole in silicon oxide may be filled with a plug of refractory metal before the copper is deposited, or the first refractory metal layer may be conformally deposited to coat the sidewalls of the hole.

Abstract: Metal contacts and interconnections for integrated circuits utilize copper as the primary conductor, with the copper being totally encased in refractory metal layers on both top and bottom surfaces and also sidewalls. The contact hole in silicon oxide may be filled with a plug of refractory metal before the copper is deposited, or the first refractory metal layer may be conformally deposited to coat the sidewalls of the hole.

Abstract: A method of plating an interconnect or contact metal of higher conductivity than aluminum onto a metal layer in VLSI devices includes depositing a coating of insulator over the metal layer, patterning and etching the insulator coating into a mask of the reverse image of a desired lead pattern and then depositing the interconnect metal onto the exposed metal layer. Following depositing the insulator mask and underlaying metal is selectively removed.