Abstract: An electronic device can include conductive regions. A void can extend between different portions of an insulating layer. Different openings can intersect the void. A liner layer can substantially block the void, substantially preventing subsequently forming an electrical leakage path along the void. In one aspect, a stressor layer can be deposited over the conductive regions prior to forming the insulating layer. The liner layer can be formed over the stressor layer within the different openings through the insulating layer. In another aspect, an etch-stop layer can be formed over a silicide layer prior to forming the insulating layer. After removing a portion of the liner layer, a portion of the etch-stop layer can be removed to expose the silicide layer within the different openings. In yet another aspect, a nitride layer can lie between a substrate and the insulating layer and include a section of the openings.

Abstract: An electronic device can include conductive regions. A void can extend between different portions of an insulating layer. Different openings can intersect the void. A liner layer can substantially block the void, substantially preventing subsequently forming an electrical leakage path along the void. In one aspect, a stressor layer can be deposited over the conductive regions prior to forming the insulating layer. The liner layer can be formed over the stressor layer within the different openings through the insulating layer. In another aspect, an etch-stop layer can be formed over a silicide layer prior to forming the insulating layer. After removing a portion of the liner layer, a portion of the etch-stop layer can be removed to expose the silicide layer within the different openings. In yet another aspect, a nitride layer can lie between a substrate and the insulating layer and include a section of the openings.

Abstract: The described invention is directed to microwave methods for burning-in, electrical stressing, thermal stressing and reducing rectifying junction leakage current in fully processed semiconductor chips individually and at wafer level, as well as burning in and stressing semiconductor chip packaging substrates and the combination of a semiconductor chip mounted onto a semiconductor chip packaging substrate. Microwaves burn-in devices in a substantially shorter period of time than conventional burn-in techniques and avoid the need for special workpiece holders which are required by conventional stress and burn-in techniques. Additionally, microwave methods are described for reducing the leakage current of recitfying junctions, such as PN junctions and Schottky barrier diode junctions of semiconductor devices on fully processed semiconductor chips and wafers.

Abstract: A multi-layer contact process is described for providing contact to a shallow semiconductor region forming a semiconductor PN junction and with a silicon semiconductor body. The multi-layer structure includes a layer of polycrystalline silicon doped with an impurity of the same conductivity type as that of the semiconductor region. A first layer of a refractory alloy is deposited over the polycrystalline silicon layer to provide electrically stable interface therewith. A second layer of another refractory metal or alloy is deposited over the first refractory metal alloy layer and serves to protect the shallow PN junction against current leakage failure. A third layer of interconnect metal is deposited over the multi-layer contact structure. The resulting structure provides a low resistance ohmic contact to a shallow semiconductor region with improved electrical characteristics.