Abstract: A method for stacking integrated circuit substrates and the substrates used therein are disclosed. In the method, an integrated circuit substrate having top and bottom surfaces is provided. The substrate is divided vertically into a plurality of layers including an integrated circuit layer having integrated circuit elements constructed therein and a buffer layer adjacent to the bottom surface. An alignment fiducial mark extending from the top surface of the wafer into the substrate to a depth below that of the circuit layer is constructed. The vias are arranged in a pattern that provides a fiducial mark when viewed from the bottom surface of the substrate. The pattern can be chosen such that it is recognized by a commercial stepper/scanner/contact mask aligner when viewed from said backside of said wafer. After the substrate is thinned, the alignment fiducial mark is then used to position a mask used in subsequent processing.

Abstract: A method for stacking integrated circuit substrates and the substrates used therein are disclosed. In the method, an integrated circuit substrate having top and bottom surfaces is provided. The substrate is divided vertically into a plurality of layers including an integrated circuit layer having integrated circuit elements constructed therein and a buffer layer adjacent to the bottom surface. An alignment fiducial mark extending from the top surface of the wafer into the substrate to a depth below that of the circuit layer is constructed. The vias are arranged in a pattern that provides a fiducial mark when viewed from the bottom surface of the substrate. The pattern can be chosen such that it is recognized by a commercial steeper/scanner/contact mask aligner when viewed from said backside of said wafer. After the substrate is thinned, the alignment fiducial mark is then used to position a mask used in subsequent processing.

Abstract: A method for stacking integrated circuit substrates and the substrates used therein are disclosed. In the method, an integrated circuit substrate having top and bottom surfaces is provided. The substrate is divided vertically into a plurality of layers including an integrated circuit layer having integrated circuit elements constructed therein and a buffer layer adjacent to the bottom surface. An alignment fiducial mark extending from the top surface of the wafer into the substrate to a depth below that of the circuit layer is constructed. The vias are arranged in a pattern that provides a fiducial mark when viewed from the bottom surface of the substrate. The pattern can be chosen such that it is recognized by a commercial stepper/scanner/contact mask aligner when viewed from said backside of said wafer. After the substrate is thinned, the alignment fiducial mark is then used to position a mask used in subsequent processing.

Abstract: A method for stacking integrated circuit substrates and the substrates used therein are disclosed. In the method, an integrated circuit substrate having top and bottom surfaces is provided. The substrate is divided vertically into a plurality of layers including an integrated circuit layer having integrated circuit elements constructed therein and a buffer layer adjacent to the bottom surface. An alignment fiducial mark extending from the top surface of the wafer into the substrate to a depth below that of the circuit layer is constructed. The vias are arranged in a pattern that provides a fiducial mark when viewed from the bottom surface of the substrate. The pattern can be chosen such that it is recognized by a commercial steeper/scanner/contact mask aligner when viewed from said backside of said wafer. After the substrate is thinned, the alignment fiducial mark is then used to position a mask used in subsequent processing.

Abstract: A polishing method is achieved comprising the following steps. A layer made of material containing a metal as a main component over a substrate having recessed portions on a surface thereof so as to fill the recessed portions with the metal layer is formed. The metal is Cu, a Cu alloy, Al, or an Al alloy. The metal layer is polished by a chemical mechanical polishing method using a slurry including a polishing agent. The polishing agent contains a chemical agent and an etching agent. The chemical agent includes at least a carbonyl derivative of benzotriazole and is responsible for forming a protective film on the surface of the metal layer by reacting with the material containing a metal as a main component. The etching agent is responsible for etching the material containing a metal as a main component.

Abstract: A new method of depositing a copper seed layer in the manufacture of an integrated circuit device has been achieved. The copper seed layer is thin and conformal and well-suited for subsequent electroless plating of copper. A dielectric layer, which may comprise a stack of dielectric material, is provided overlying a semiconductor substrate. The dielectric layer patterned to form vias and trenches for planned dual damascene interconnects. A barrier layer comprising tantalum, titanium, or tungsten is deposited overlying the dielectric layer to line the vias and trenches. A copper seed layer is deposited overlying the barrier layer by the reaction of CuF2 vapor with the barrier layer, and the integrated circuit is completed.