Abstract: A method and structure for a composite stud contact interface with a decreased contact resistance and improved reliability. A selective dry etch is used which comprises a fluorine containing gas. The contact resistance is reduced by partially dry-etching back the tungsten contact after or during the M1 RIE process. The recessed contact is then subsequently metalized during the M1 liner/plating process. The tungsten contact height is reduced after it has been fully formed.

Abstract: An integrated circuit with increased electromigration lifetime and allowable current density and methods of forming same are disclosed. In one embodiment, an integrated circuit includes a conductive line connected to at least one functional via, and at least one dummy via having a first, lower end electrically connected to the conductive line and a second upper end electrically unconnected (isolated) to any conductive line. Each dummy via extends vertically upwardly from the conductive line and removes a portion of a fast diffusion path, i.e., metal to dielectric cap interface, which is replaced with a metal to metallic liner interface. As a result, each dummy via reduces metal diffusion rates and thus increases electromigration lifetimes and allows increased current density.

Abstract: The present invention addresses detection of charge-induced defects through test structures that can be easily incorporated on a wafer to detect charge-induced damage in the back-end-of-line processing of a semiconductor processing line. A test macro is designed to induce an arc from a charge accumulating antenna structure to another charge accumulating antenna structure across parallel plate electrodes. When an arc of a predetermined sufficient strength is present, the macro will experience a voltage breakdown that is measurable as a short. The parallel plate electrodes may both be at the floating potential of the microchip to monitor CMP-induced or lithographic-induced charge failure mechanisms, or have one electrode electrically connected to a ground potential structure to capture charge induced damage, hence having the capability to differentiate between the two.

Abstract: The present invention relates to a laser fuse structure for high power applications. Specifically, the laser fuse structure of the present invention comprises first and second conductive supporting elements (12a, 12b), at least one conductive fusible link (14), first and second connection elements (20a, 20b), and first and second metal lines (22a, 22b). The conductive supporting elements (12a, 12b), the conductive fusible link (14), and the metal lines (22a, 22b) are located at a first metal level (3), while the connect elements (20a, 20b) are located at a second, different metal level (4) and are connected to the conductive supporting elements (12a, 12b) and the metal lines (22a, 22b) by conductive via stacks (18a, 18b, 23a, 23b) that extend between the first and second metal levels (3, 4).

Abstract: An integrated circuit with increased electromigration lifetime and allowable current density and methods of forming same are disclosed. In one embodiment, an integrated circuit includes a conductive line connected to at least one functional via, and at least one dummy via having a first, lower end electrically connected to the conductive line and a second upper end electrically unconnected (isolated) to any conductive line. Each dummy via extends vertically upwardly from the conductive line and removes a portion of a fast diffusion path, i.e., metal to dielectric cap interface, which is replaced with a metal to metallic liner interface. As a result, each dummy via reduces metal diffusion rates and thus increases electromigration lifetimes and allows increased current density.

Abstract: A method and structure for a composite stud contact interface with a decreased contact resistance and improved reliability. A selective dry etch is used which comprises a fluorine containing gas. The contact resistance is reduced by partially dry-etching back the tungsten contact after or during the M1 RIE process. The recessed contact is then subsequently metalized during the M1 liner/plating process. The tungsten contact height is reduced after it has been fully formed.

Abstract: Methods and a system are disclosed for correcting a non-planar region during fabrication of a semiconductor product on a wafer. The invention separates an exposure of at least a portion of a fill pattern on a resist from a product exposure so that the fill pattern can be adjusted to correct the non-planar region. In one embodiment, a determination of whether a fill pattern for a metal level above the non-planar region includes a portion over the non-planar region is made. Where a portion of the fill pattern is to be placed over the non-planar region, a pattern factor for exposure of the portion of the fill pattern on a resist is adjusted to correct the non-planar region.

Abstract: A chemical mechanical polishing (CMP) step is used to remove excess conductive material (e.g., Cu) overlying a low-k or ultralow-k interlevel dielectric layer (ILD) layer having trenches filled with conductive material, for a damascene interconnect structure. A reactive ion etch (RIE) or a Gas Cluster Ion Beam (GCIB) process is used to remove a portion of a liner which is atop a hard mask. A wet etch step is used to remove an oxide portion of the hard mask overlying the ILD, followed by a final touch-up Cu CMP (CMP) step which chops the protruding Cu patterns off and lands on the SiCOH hard mask. In this manner, processes used to remove excess conductive material substantially do not affect the portion of the hard mask overlying the interlevel dielectric layer.

Abstract: Custom connections between pairs of copper wires in a last damascene wiring level are effected by creating openings in an overlying insulating layer which span a distance between portions of the two wires, then filling the openings with aluminum. The openings can be created (or completed) by a second, maskless UV laser exposure of positive photoresist which is used for patterning the insulating layer. If an opening is not created, an aluminum connecting shape overlying the insulating layer will not effect a connection between the two wires. Similar results can be achieved by laser exposure of a resist used to pattern the aluminum layer, thereby causing breaks in connecting shape when it is desired not to have a connection.

Abstract: The invention provides a method of forming a wiring layer in an integrated circuit structure that forms an organic insulator, patterns the insulator, deposits a liner on the insulator, and exposes the structure to a plasma to form pores in the insulator in regions next to the liner. The liner is formed thin enough to allow the plasma to pass through the liner and form the pores in the insulator. During the plasma processing, the plasma passes through the liner without affecting the liner. After the plasma processing, additional liner material may be deposited. After this, a conductor is deposited and excess of portions of the conductor are removed from the structure such that the conductor only remains within patterned portions of the insulator. This method produces an integrated circuit structure that has an organic insulator having patterned features, a liner lining the patterned features, and a conductor filling the patterned features.

Abstract: In damascene processing, metal hardmask sputtering redeposition that occurs during reactive ion etching (RIE) is exploited to produce, during the RIE process, a desired barrier metal liner on the etched feature.

Abstract: An advanced back-end-of-line (BEOL) interconnect structure having a hybrid dielectric is disclosed. The inter-layer dielectric (ILD) for the via level is preferably different from the ILD for the line level. In a preferred embodiment, the via-level ILD is formed of a low-k SiCOH material, and the line-level ILD is formed of a low-k polymeric thermoset material.

Abstract: A method of fabricating a semiconductor device having a dielectric structure on which an interconnect structure is optionally patterned using lithographic and etching techniques, within a single deposition chamber, is provided. The dielectric structure may optionally be covered by diffusion barrier materials prior to a sputter etching process. This sputter etching process is used to remove the native oxide on an underneath metal conductor surface and includes a directional gaseous bombardment with simultaneous deposition of metal neutral. Diffusion barrier materials may also be deposited into the pattern.