Abstract: A diffusion barrier stack is formed by forming a layer comprising a metal over a conductor that includes copper; and forming a first dielectric layer over the layer, wherein the dielectric layer is of a thickness that alone it can not serve as a diffusion barrier layer to the conductor and the first dielectric layer prevents oxidation of the layer. In one embodiment, the diffusion barrier stack includes two layers; the first layer is a conductive layer and the second layer is a dielectric layer. The diffusion barrier stack minimizes electromigration and copper diffusion from the conductor.

Abstract: A method for achieving a through-substrate via through a substrate having active circuitry on a first major surface begins by forming a hole into the substrate through the first major surface. The hole is lined with a conductive layer. A dielectric layer is deposited over the conductive layer. This deposition is performed in a manner that causes the dielectric layer to be substantially conformal. Conductive material is formed over first dielectric layer. A second major surface of the substrate is etched to expose the conductive material.

Abstract: A semiconductor process is taught for performing electroless plating of copper overlying at least a portion of a layer comprising cobalt, nickel, or both cobalt and nickel. The cobalt and/or nickel comprising layer may be formed using electroless plating. For some embodiments, a tin layer is then formed overlying the copper. The tin layer may be formed using immersion plating or electroless plating. A micropad may comprise the cobalt and/or nickel comprising layer and the copper layer. In some embodiments, the micropad may also comprise the tin layer. In one embodiment, the micropad may be compressed at an elevated temperature to form a copper tin intermetallic compound which provides an interconnect between a plurality of semiconductor devices.

Abstract: A semiconductor device and method has interconnects with adjoining reservoir openings. A dielectric layer is formed as part of an uppermost of the one or more interconnect layers. Openings formed in the dielectric layer result in modified portions of the dielectric layer along portions of sidewalls of the openings. The openings are filled with a conductive material, such as metal. An exposed portion of the dielectric layer is removed to form protruding pads of the conductive material extending above the dielectric layer. Reservoir openings are formed adjacent the protruding pads by removing the modified portions of the dielectric layer. When the semiconductor device is bonded with another device, either a wafer or a die, laterally flowing metal collects in the reservoir openings and ensures that a reliable electrical connection is made between the semiconductor device and the other device.

Abstract: A method is provided for creating a barrier layer (217) on a substrate comprising a dielectric layer (203) and a metal interconnect (211). In accordance with the method, the substrate is treated with a first plasma comprising helium, thereby forming a treated substrate. The treated substrate is then exposed to a second plasma selected from the group consisting of oxidizing plasmas and reducing plasmas. Next, a barrier layer is created on the treated substrate.

Abstract: A diffusion barrier stack is formed by forming a layer comprising a metal over a conductor that includes copper; and forming a first dielectric layer over the layer, wherein the dielectric layer is of a thickness that alone it can not serve as a diffusion barrier layer to the conductor and the first dielectric layer prevents oxidation of the layer. In one embodiment, the diffusion barrier stack includes two layers; the first layer is a conductive layer and the second layer is a dielectric layer. The diffusion barrier stack minimizes electromigration and copper diffusion from the conductor.