Abstract: A method for processing semiconductor wafers is disclosed. A semiconductor wafer is provided to a semiconductor processing stage where a block copolymer surfactant (BCS) is applied to the wafer surface. In one embodiment, the BCS includes a hydrophobic portion and a hydrophilic portion. Alternatively, the BCS may be a silicone-containing BCS. In one embodiment, the BCS is within an aqueous solution where the concentration of the BCS within the aqueous solution is less than one percent by weight. Also disclosed is an aqueous solution including abrasive particles and a BCS having a hydrophobic portion and a hydrophilic portion. The abrasive particles may include silica, alumina, or ceria.

Abstract: The formation of a MIM (metal insulator metal) capacitor (164) and concurrent formation of a resistor (166) is disclosed. A copper diffusion barrier (124) is formed over a copper deposition (110) that serves as a bottom electrode (170) of the capacitor (164). The copper diffusion barrier (124) mitigates unwanted diffusion of copper from the copper deposition (110), and is formed via electro-less deposition such that little to none of the barrier material is deposited at locations other than over a top surface (125) of the deposition of copper/bottom electrode. Subsequently, layers of dielectric (150) and conductive (152) materials are applied to form a dielectric (172) and top electrode (174) of the MIM capacitor (164), respectively, where the layer of conductive top electrode material (152) also functions to concurrently develop the resistor (166) on the same chip as the capacitor (164).

Abstract: Dummy features (64, 65, 48a, 48b) are formed within an interlevel dielectric layer (36). Passivation layers (32 and 54) are formed by electroless deposition to protect the underlying conductive regions (44, 48a, 48b and 30) from being penetrated from the air gaps (74). In addition, the passivation layers (32 and 54) overhang the underlying conductive regions (44, 48a, 48b and 30), thereby defining dummy features (65a, 65b and 67) adjacent the conductive regions (48a, 44 and 48b). The passivation layers (32 and 54) can be formed without additional patterning steps and help minimize misaligned vias from puncturing air gaps.

Abstract: A method for processing semiconductor wafers is disclosed. A semiconductor wafer is provided to a semiconductor processing stage where a block copolymer surfactant (BCS) is applied to the wafer surface. In one embodiment, the BCS includes a hydrophobic portion and a hydrophilic portion. Alternatively, the BCS may be a silicone-containing BCS. In one embodiment, the BCS is within an aqueous solution where the concentration of the BCS within the aqueous solution is less than one percent by weight. Also disclosed is an aqueous solution including abrasive particles and a BCS having a hydrophobic portion and a hydrophilic portion. The abrasive particles may include silica, alumina, or ceria.

Abstract: Dummy features (64, 65, 48a, 48b) are formed within an interlevel dielectric layer (36). Passivation layers (32 and 54) are formed by electroless deposition to protect the underlying conductive regions (44, 48a, 48b and 30) from being penetrated from the air gaps (74). In addition, the passivation layers (32 and 54) overhang the underlying conductive regions (44, 48a, 48b and 30), thereby defining dummy features (65a, 65b and 67) adjacent the conductive regions (48a, 44 and 48b). The passivation layers (32 and 54) can be formed without additional patterning steps and help minimize misaligned vias from puncturing air gaps.