Abstract: A method of vertically stacking wafers is provided to form three-dimensional (3D) wafer stack. Such method comprising: selectively depositing a plurality of metallic lines on opposing surfaces of adjacent wafers; bonding the adjacent wafers, via the metallic lines, to establish electrical connections between active devices on vertically stacked wafers; and forming one or more vias to establish electrical connections between the active devices on the vertically stacked wafers and an external interconnect. Metal bonding areas on opposing surfaces of the adjacent wafers can be increased by using one or more dummy vias, tapered vias, or incorporating an existing copper (Cu) dual damascene process.

Abstract: A three-dimensional (3-D) integrated chip system is provided with a first wafer including one or more integrated circuit (IC) devices; a second wafer including one or more integrated circuit (IC) devices; and metallic lines deposited on opposing surfaces of the first and second wafers at designated locations with an interlevel dielectric (ILD) recess surrounding the metallic lines to facilitate direct metal bonding between the first and second wafers and establish electrical connections between active IC devices on the first and second wafers.

Abstract: A method of forming a silicon (Si) via in vertically stacked wafers is provided with a contact plug extending from selected metallic lines of a top wafer and an etch stop layer formed prior to the contact plug. Such a method comprises selectively etching through the silicon (Si) of the top wafer until stopped by the etch stop layer to form the Si via; depositing an oxide layer to insulate a sidewall of the Si via; forming a barrier layer on the oxide layer and on the bottom of the Si via; and depositing a conduction metal into the Si via to provide electrical connection between active IC devices located on vertically stacked wafers and an external interconnect.

Abstract: A three-dimensional (3-D) integrated chip system is provided with a first wafer including one or more integrated circuit (IC) devices; a second wafer including one or more integrated circuit (IC) devices; and a metal bonding layer deposited on opposing surfaces of the first and second wafers at designated locations to establish electrical connections between active IC devices on the first and second wafers and to provide metal bonding between the adjacent first and second wafers, when the first wafer is pressed against the second wafer using a flexible bladder press to account for height differences of the metal bonding layer across the opposing surfaces of the first and second wafers.

Abstract: A three-dimensional (3-D) integrated chip system is provided with a first wafer including one or more integrated circuit (IC) devices, metallic lines deposited via an interlevel dielectric (ILD) on a surface, and at least one barrier line deposited on an outer edge of the surface; and a second wafer including one or more integrated circuit (IC) devices, metallic lines deposited via an interlevel dielectric (ILD) on a surface, and at least one barrier line deposited on an outer edge of the surface, wherein the metallic lines and the barrier line deposited on the surface of the second wafer are bonded with the metallic lines and the barrier line deposited on the surface of the first wafer to establish electrical connections between active IC devices on adjacent wafers and to form a barrier structure on the outer edge of the adjacent wafers.

Abstract: Method for an on-chip decoupling capacitor. The capacitor includes a bottom electrode that consist of nanostructures deposited over a planarized metal, a dielectric material deposited over the nanostructures, and a top electrode deposited over the dielectric material. The shape of the bottom electrode is tunable by modulating the diameter and/or the length of the nanostructures to produce and increase in capacitance without increasing the footprint of the on-chip decoupling capacitor.

Abstract: Method and apparatus for an on-chip decoupling capacitor. The capacitor includes a bottom electrode that consist of nanostructures deposited over a planarized metal, a dielectric material deposited over the nanostructures, and a top electrode deposited over the dielectric material. The shape of the bottom electrode is tunable by modulating the diameter and/or the length of the nanostructures to produce an increase in capacitance without increasing the footprint of the on-chip decoupling capacitor.

Abstract: A three dimensional capacitor fabricated as part of a dual damascene process is disclosed. The capacitor structure comprises two barrier metal layers separated by a high k dielectric and is formed in all the via and trench openings. The upper barrier layer and dielectric is selectively removed from those openings which will have ordinary vias and conductors, the other opening remains as capaitor.