Abstract: A test structure for integrated circuit (IC) device fabrication includes a plurality of test structure chains formed at various regions of an IC wafer, each of the plurality of test structure chains including one or more vias; each of the one or more vias in contact with a conductive line disposed thereabove, the conductive line being configured such that at least one dimension thereof varies from chain to chain so as to produce variations in seed layer and liner layer thickness from chain to chain for the same deposition process conditions.

Abstract: A microelectronic element such as a chip or microelectronic wiring substrate is provided which includes a plurality of conductive interconnects for improved resistance to thermal stress. At least some of the conductive interconnects include a metallic plate, a metallic connecting line and an upper metallic via. The metallic connecting line has an upper surface at least substantially level with an upper surface of the metallic plate, an inner end connected to the metallic plate at one of the peripheral edges, and an outer end horizontally displaced from the one peripheral edge. The metallic connecting line has a width much smaller than the width of the one peripheral edge of the metallic plate and has length greater than the width of the one peripheral edge. The upper metallic via has a bottom end in contact with the metallic connecting line at a location that is horizontally displaced from the one peripheral edge by at least about 3 microns (?m).

Abstract: A test structure for integrated circuit (IC) device fabrication includes a plurality of test structure chains formed at various regions of an IC wafer, each of the plurality of test structure chains including one or more vias; each of the one or more vias in contact with a conductive line disposed thereabove, the conductive line being configured such that at least one dimension thereof varies from chain to chain so as to produce variations in seed layer and liner layer thickness from chain to chain for the same deposition process conditions.

Abstract: A crack stop void is formed in a low-k dielectric layer between adjacent fuse structures for preventing propagation of cracks between the adjacent fuse structures during a fuse blow operation. The crack stop void is formed simultaneously with the formation of an interconnect structure.

Abstract: A method for determining a line-to-line spacing of a device. The method includes experimentally determining a slope kCA, experimentally determining a slope kSE and determining a line-to-line spacing of a device from the slope kCA and the slope kSE. A structure for performing the method includes a non-destructive line-to-line spacing characterization macro.

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 structure representative of a conductive interconnect of a microelectronic element is provided, which may include a conductive metallic plate having an upper surface, a lower surface, and a plurality of peripheral edges extending between the upper and lower surfaces, the upper surface defining a horizontally extending plane. The structure may also include a lower via having a top end in conductive communication with the metallic plate and a bottom end vertically displaced from the top end. A lower conductive or semiconductive element can be in contact with the bottom end of the lower via. An upper metallic via can lie in at least substantial vertical alignment with the lower conductive via, the upper metallic via having a bottom end in conductive communication with the metallic plate and a top end vertically displaced from the bottom end. The upper metallic via may have a width at least about ten times than the length of the metallic plate and about ten times smaller than the width of the metallic plate.

Abstract: A semiconductor interconnect structure and method providing an embedded barrier layer to prevent damage to the dielectric material during or after Chemical Mechanical Polishing. The method employs a combination of an embedded film, etchback, using either selective CoWP or a conformal cap such as a SiCNH film, to protect the dielectric material from the CMP process as well as subsequent etch, clean and deposition steps of the next interconnect level.

Abstract: The invention predicts premature dielectric breakdown in a semiconductor. At least one dielectric breakdown mode is calculated for the semiconductor wafer. If a one mode is calculated, premature dielectric breakdown will be associated with any semiconductor with a breakdown voltage less than a predetermined standard deviation of a plurality of breakdown voltages within said calculated mode. If multiple modes are calculated, the mode that most accurately represents dielectric breakdown for the semiconductor wafer is determined and premature dielectric breakdown will be associated with any semiconductor with a breakdown voltage less than a predetermined standard of the calculated mode that most accurately represents dielectric breakdown for the semiconductor wafer.

Abstract: A microelectronic element such as a chip or microelectronic wiring substrate is provided which includes a plurality of conductive interconnects for improved resistance to thermal stress. At least some of the conductive interconnects include a metallic plate, a metallic connecting line and an upper metallic via. The metallic connecting line has an upper surface at least substantially level with an upper surface of the metallic plate, an inner end connected to the metallic plate at one of the peripheral edges, and an outer end horizontally displaced from the one peripheral edge. The metallic connecting line has a width much smaller than the width of the one peripheral edge of the metallic plate and has length greater than the width of the one peripheral edge. The upper metallic via has a bottom end in contact with the metallic connecting line at a location that is horizontally displaced from the one peripheral edge by at least about 3 microns (?m).

Abstract: A semiconductor interconnect structure and method providing an embedded barrier layer to prevent damage to the dielectric material during or after Chemical Mechanical Polishing. The method employs a combination of an embedded film, etchback, using either selective CoWP or a conformal cap such as a SiCNH film, to protect the dielectric material from the CMP process as well as subsequent etch, clean and deposition steps of the next interconnect level.

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 test structure is disclosed for locating electromigration voids in a semiconductor interconnect structure having an interconnect via interconnecting a lower metallization line with an upper metallization line. In an exemplary embodiment, the test structure includes a via portion the top of the interconnect via at the upper metallization line. In addition, a line portion extends from the via portion, wherein the line portion connects to an external probing surface, in addition to a probing surface on the lower metallization line, thereby allowing the identification of any electromigration voids present in the interconnect via.

Abstract: A test structure is disclosed for locating electromigration voids in a semiconductor interconnect structure having an interconnect via interconnecting a lower metallization line with an upper metallization line. In an exemplary embodiment, the test structure includes a via portion the top of the interconnect via at the upper metallization line. In addition, a line portion extends from the via portion, wherein the line portion connects to an external probing surface, in addition to a probing surface on the lower metallization line, thereby allowing the identification of any electromigration voids present in the interconnect via.

Abstract: A method of providing sub-half-micron copper interconnections with improved electromigration and corrosion resistance. The method includes double damascene using electroplated copper, where the seed layer is deposited by chemical vapor deposition, or by physical vapor deposition in a layer less than about 800 angstroms.

Abstract: A method of providing sub-half-micron copper interconnections with improved electromigration and corrosion resistance. The method includes double damascene using electroplated copper, where the seed layer is deposited by chemical vapor deposition, or by physical vapor deposition in a layer less than about 800 angstroms.