Abstract: The present invention provides a method for producing thin nickel (Ni) monosilicide or NiSi films (having a thickness on the order of about 30 nm or less), as contacts in CMOS devices wherein an amorphous Ni alloy silicide layer is formed during annealing which eliminates (i.e., completely by-passing) the formation of metal-rich silicide layers. By eliminating the formation of the metal-rich silicide layers, the resultant NiSi film formed has improved surface roughness as compared to a NiSi film formed from a metal-rich silicide phase. The method of the present invention also forms Ni monosilicide films without experiencing any dependence of the dopant type concentration within the Si-containing substrate that exists with the prior art NiSi films.

Abstract: The present invention provides a method for producing thin nickel (Ni) monosilicide or NiSi films (having a thickness on the order of about 30 nm or less), as contacts in CMOS devices wherein an amorphous Ni alloy silicide layer is formed during annealing which eliminates (i.e., completely by-passing) the formation of metal-rich silicide layers. By eliminating the formation of the metal-rich silicide layers, the resultant NiSi film formed has improved surface roughness as compared to a NiSi film formed from a metal-rich silicide phase. The method of the present invention also forms Ni monosilicide films without experiencing any dependence of the dopant type concentration within the Si-containing substrate that exists with the prior art NiSi films.

Abstract: Semiconductor interconnect structures including a surface-repair material, e.g., a noble metal or noble metal alloy, that fills hollow-metal related defects located within a conductive material are provided. The filling of the hollow-metal related defects with the surface repair material improves the electromigration (EM) reliability of the structure as well as decreasing in-line defect related yield loss.

Abstract: An IC interconnect for high direct current (DC) that is substantially immune to electro-migration (EM) damage, a design structure of the IC interconnect and a method of manufacture of the IC interconnect is provided. The structure has electro-migration immunity and redundancy of design, which includes a plurality of wires laid out in parallel and each of which are coated with a liner material. Two adjacent of the wires are physically contacted to each other.

Abstract: The present invention provides an interconnect structure which has a high leakage resistance and substantially no metallic residues and no physical damage present at an interface between the interconnect dielectric and an overlying dielectric capping layer. The interconnect structure of the invention also has an interface between each conductive feature and the overlying dielectric capping layer that is substantially defect-free. The interconnect structure of the invention includes a non-plasma deposited dielectric capping layer which is formed utilizing a process including a thermal and chemical-only pretreatment step that removes surface oxide from atop each of the conductive features as well as metallic residues from atop the interconnect dielectric material. Following this pretreatment step, the dielectric capping layer is deposited.

Abstract: A semiconductor structure is provided that includes a lower interconnect level including a first dielectric material having at least one conductive feature embedded therein; a dielectric capping layer located on the first dielectric material and some, but not all, portions of the at least one conductive feature; and an upper interconnect level including a second dielectric material having at least one conductively filled via and an overlying conductively filled line disposed therein, wherein the conductively filled via is in contact with an exposed surface of the at least one conductive feature of the first interconnect level by an anchoring area. Moreover, the conductively filled via and conductively filled line of the inventive structure are separated from the second dielectric material by a single continuous diffusion barrier layer. As such, the second dielectric material includes no damaged regions in areas adjacent to the conductively filled line.

Abstract: Silicide is protected during MC RIE etch by first forming an oxide film over the silicide and, after performing MC RIE etch, etching the oxide film. The oxide film is formed from a film of alloyed metal-silicon (M-Si) on the layer of silicide, then wet etching the metal-silicon. An ozone plasma treatment process can be an option to densify the oxide film. The oxide film may be etched by oxide RIE or wet etch, using 500:1 DHF.

Abstract: The present invention provides a reprogrammable electrically blowable fuse and associated design structure. The electrically blowable fuse is programmed using an electro-migration effect and is reprogrammed using a reverse electro-migration effect. The state (i.e., “opened” or “closed”) of the electrically blowable fuse is determined by a sensing system which compares a resistance of the electrically blowable fuse to a reference resistance.

Abstract: A semiconductor structure in which the contact resistance in the contact opening is reduced as well as a method of forming the same are provided. This is achieved in the present invention by replacing conventional contact metallurgy, such as tungsten, or a metal silicide, such as Ni silicide or Cu silicide, with a metal germanide-containing contact material. The term “metal germanide-containing” is used in the present application to denote a pure metal germanide (i.e., MGe alloy) or a metal germanide that includes Si (i.e., MSiGe alloy).

Abstract: A system, a method and a computer program product for analyzing a circuit design provide for discretizing the circuit design into a series of pixels. A fraction of at least one constituent material is determined for each pixel. A deflection is also determined for each pixel. The deflection is predicated upon a planarizing of the pixel, and it is calculated while utilizing an algorithm that includes the fraction of the at least one constituent material. A series of deflections for the series of pixels may be mapped and evaluated.

Abstract: Stacked via pillars, such as metal via pillars, are provided at different and designated locations in IC chips to support the chip structure during processing and any related processing stresses such as thermal and mechanical stresses. These stacked via pillars connect and extend from a base substrate of the strip to a top oxide cap of the chip. The primary purpose of the stacked via pillars is to hold the chip structure together to accommodate any radial deformations and also to relieve any stress, thermal and/or mechanical, build-tip during processing or reliability testing. The stacked via pillars are generally not electrically connected to any active lines or vias, however in some embodiments the stacked via pillars can provide an additional function of providing an electrical connection in the chip.

Abstract: A structure and process are provided that are capable of reducing the occurrence of discontinuities within the metallization, such as voiding or seams, formed during electroplating at the edges of semiconductor metallization arrays. The structure includes a metallization bar located around the periphery of the array. The process employs the structure during electroplating.

Abstract: A structure and process are provided that are capable of reducing the occurrence of discontinuities within the metallization, such as voiding or seams, formed during electroplating at the edges of semiconductor metallization arrays. The structure includes a metallization bar located around the periphery of the array. The process employs the structure during electroplating.

Abstract: An electronic structure including a substrate having a having a dielectric layer with at least one metallic interconnect structure within and a dielectric barrier layer above the dielectric layer, and a multi-layer hardmask stack coated with a self-assembled layer, where the self-assembled layer is a pattern of nanoscale and/or microscale voids which are generated into the dielectric barrier layer and into the dielectric layer next to the metallic interconnect structure to create columns in the dielectric barrier layer and dielectric layer therein. Electronics structures prepared with the process are useful to prepare electronics devices, such as computers and the like.

Abstract: The present invention provides a method for producing thin nickel (Ni) monosilicide or NiSi films (having a thickness on the order of about 30 nm or less), as contacts in CMOS devices wherein an amorphous Ni alloy silicide layer is formed during annealing which eliminates (i.e., completely by-passing) the formation of metal-rich silicide layers. By eliminating the formation of the metal-rich silicide layers, the resultant NiSi film formed has improved surface roughness as compared to a NiSi film formed from a metal-rich silicide phase. The method of the present invention also forms Ni monosilicide films without experiencing any dependence of the dopant type concentration within the Si-containing substrate that exists with the prior art NiSi films.

Abstract: The present invention provides a method for producing thin nickel (Ni) monosilicide or NiSi films (having a thickness on the order of about 30 nm or less), as contacts in CMOS devices wherein an amorphous Ni alloy silicide layer is formed during annealing which eliminates (i.e., completely by-passing) the formation of metal-rich silicide layers. By eliminating the formation of the metal-rich silicide layers, the resultant NiSi film formed has improved surface roughness as compared to a NiSi film formed from a metal-rich silicide phase. The method of the present invention also forms Ni monosilicide films without experiencing any dependence of the dopant type concentration within the Si-containing substrate that exists with the prior art NiSi films.

Abstract: A semiconductor structure in which the contact resistance in the contact opening is reduced as well as a method of forming the same are provided. This is achieved in the present invention by replacing conventional contact metallurgy, such as tungsten, or a metal silicide, such as Ni silicide or Cu silicide, with a metal germanide-containing contact material. The term “metal germanide-containing” is used in the present application to denote a pure metal germanide (i.e., MGe alloy) or a metal germanide that includes Si (i.e., MSiGe alloy).

Abstract: The present invention provides a method for producing thin nickel (Ni) monosilicide or NiSi films (having a thickness on the order of about 30 nm or less), as contacts in CMOS devices wherein an amorphous Ni alloy silicide layer is formed during annealing which eliminates (i.e., completely by-passing) the formation of metal-rich silicide layers. By eliminating the formation of the metal-rich silicide layers, the resultant NiSi film formed has improved surface roughness as compared to a NiSi film formed from a metal-rich silicide phase. The method of the present invention also forms Ni monosilicide films without experiencing any dependence of the dopant type concentration within the Si-containing substrate that exists with the prior art NiSi films.

Abstract: A computer program product, comprising a computer usable medium having a computer readable program code embodied therein, said computer readable program code including an algorithm adapted to implement a method including the following steps. First, design information of the design structure is provided including a back-end-of-line layer of the integrated circuit which includes N interconnect layers, N being a positive integer. Next, each interconnect layer of the N interconnect layers is divided into multiple pixels. Next, a first path of a traveling particle in a first interconnect layer of the N interconnect layers is determined. Next, M path pixels of the multiple pixels of the first interconnect layer on the first path of the traveling particle are identified, M being a positive integer. Next, a first loss energy lost by the traveling particle due to its completely passing through a first pixel of the M path pixels is determined.

Abstract: A method of determining a stopping power of a design structure with respect to a traveling particle. The method includes (i) providing design information of the design structure comprising a back-end-of-line layer which includes N interconnect layers, N being a positive integer, (ii) dividing each interconnect layer of the N interconnect layers into multiple pixels, and (iii) determining a first path of the traveling particle in a first interconnect layer of the N interconnect layers, (iv) identifying M path pixels of the multiple pixels of the first interconnect layer on the first path of the traveling particle, M being a positive integer, and (v) determining a first loss energy lost by the traveling particle due to its completely passing through a first pixel of the M path pixels.