Abstract: In accordance with the present teachings, semiconductor devices and methods of making semiconductor devices and dielectric stack in an integrated circuit are provided. The method of forming a dielectric stack in an integrated circuit can include providing a semiconductor structure including one or more copper interconnects and forming an etch stop layer over the semiconductor structure in a first processing chamber. The method can also include forming a thin silicon oxide layer over the etch stop layer in the first processing chamber and forming an ultra low-k dielectric layer over the thin silicon oxide layer in a second processing chamber, wherein forming the thin silicon oxide layer improves adhesion between the etch stop layer and the ultra low-k dielectric as compared to a dielectric stack that is devoid of the thin silicon oxide layer between the etch stop layer and the ultra low-k dielectric.

Abstract: Disclosed is a semiconductor wafer with an array of integrated circuit chips with scribe lane structures forming edge and intra-chip seals for use in protecting the IC circuitry. Substantially parallel scribe seal structures extend around the periphery of each chip; the two scribe seal structures have a separation gap. Preferred embodiments of the invention also include wafers of ICs each having two or more distinctive circuitry blocks such as analog and digital circuitry, separated by an intra-chip seal. Preferred embodiments of also include ICs having two or more distinctive circuit blocks separated by a scribe seal structure with a separation gap and a routing channel for use in passing signals among the circuit blocks.

Abstract: In accordance with the present teachings, semiconductor devices and methods of making semiconductor devices and dielectric stack in an integrated circuit are provided. The method of forming a dielectric stack in an integrated circuit can include providing a semiconductor structure including one or more copper interconnects and forming an etch stop layer over the semiconductor structure in a first processing chamber. The method can also include forming a thin silicon oxide layer over the etch stop layer in the first processing chamber and forming an ultra low-k dielectric layer over the thin silicon oxide layer in a second processing chamber, wherein forming the thin silicon oxide layer improves adhesion between the etch stop layer and the ultra low-k dielectric as compared to a dielectric stack that is devoid of the thin silicon oxide layer between the etch stop layer and the ultra low-k dielectric.

Abstract: A semiconductor device having copper interconnecting metallization (111) protected by a first (102) and a second (120) overcoat layer (homogeneous silicon dioxide), portions of the metallization exposed in a window (103) opened through the thicknesses of the first and second overcoat layers. A patterned conductive barrier layer (130) is positioned on the exposed portion of the copper metallization and on portions of the second overcoat layer surrounding the window. A bondable metal layer (150) is positioned on the barrier layer; the thickness of this bondable layer is suitable for wire bonding. A third overcoat layer (160) consist of a homogeneous silicon nitride compound is positioned on the second overcoat layer so that the ledge (162, more than 500 nm high) of the third overcoat layer overlays the edge (150b) of the bondable metal layer. The resulting contoured chip surface improves the adhesion to plastic device encapsulation.