Abstract: The present disclosure relates to semiconductor structures and, more particularly, to variable space mandrel cut for self-aligned double patterning and methods of manufacture. The method includes: forming a plurality of mandrels on a substrate; forming spacers about the plurality of mandrels and exposed portions of the substrate; removing a portion of at least one of the plurality of mandrels to form an opening; and filling in the opening with material.

Abstract: The present disclosure relates to semiconductor structures and, more particularly, to variable space mandrel cut for self-aligned double patterning and methods of manufacture. The method includes: forming a plurality of mandrels on a substrate; forming spacers about the plurality of mandrels and exposed portions of the substrate; removing a portion of at least one of the plurality of mandrels to form an opening; and filling in the opening with material.

Abstract: A method for forming a pattern for interconnection lines and associated continuity dielectric blocks in an integrated circuit includes providing a structure having a mandrel layer disposed over an etch mask layer, the etch mask layer being disposed over a pattern layer and the pattern layer being disposed over a dielectric stack. Patterning an array of mandrels in the mandrel layer. Selectively etching a beta trench entirely in a mandrel of the array, the beta trench overlaying a beta block mask portion of the pattern layer. Selectively etching a gamma trench entirely in the etch mask layer, the gamma trench overlaying a gamma block mask portion of the pattern layer. Selectively etching the structure to form a pattern in the pattern layer, the pattern including the gamma and beta block mask portions.

Abstract: A method includes providing a starting interconnect structure for semiconductor device(s), the starting interconnect structure including a first metallization layer with a first power rail. The method further includes forming a second metallization layer over the first metallization layer with a second power rail, and directly electrically connecting the first power rail and the second power rail, the directly electrically connecting including forming metal-filled vias between the first power rail and the second power rail. The method further includes forming additional metallization layer(s) over the second metallization layer with additional power rail(s), and directly electrically connecting each of the additional power rail(s) to a power rail of a metallization layer directly below.

Abstract: A method includes providing a structure having a first hardmask layer, interposer layer, second hardmask layer and mandrel layer disposed respectively over a dielectric stack. An array of mandrels is patterned into the mandrel layer with a mandrel mask. An ANA trench is patterned into the mandrel layer with a first cut mask. The ANA trench is patterned into the interposer layer with a second cut mask. An organic planarization layer (OPL) is disposed over the structure. The OPL is etched to dispose it only in the ANA trench such that a top surface of the OPL is lower than the second hardmask layer. The structure is etched to form a pattern in a dielectric layer of the dielectric stack to form an array of metal lines in the dielectric layer, a portion of the pattern formed by the ANA trench forms an ANA region within the dielectric layer.

Abstract: A method for forming a pattern for interconnection lines and associated continuity dielectric blocks in an integrated circuit includes providing a structure having a mandrel layer disposed over an etch mask layer, the etch mask layer being disposed over a pattern layer and the pattern layer being disposed over a dielectric stack. Patterning an array of mandrels in the mandrel layer. Selectively etching a beta trench entirely in a mandrel of the array, the beta trench overlaying a beta block mask portion of the pattern layer. Selectively etching a gamma trench entirely in the etch mask layer, the gamma trench overlaying a gamma block mask portion of the pattern layer. Selectively etching the structure to form a pattern in the pattern layer, the pattern including the gamma and beta block mask portions.

Abstract: Various embodiments facilitate die protection for an integrated circuit. In one embodiment, a multilayer structure is formed in multiple levels and along the edges of a die to prevent and detect damages to the die. The multilayer structure includes a support layer, a first plurality of dielectric pillars overlying the support layer, a metal layer that fills spaces between the first plurality of dielectric pillars, an insulation layer overlying the first plurality of dielectric pillars and the metal layer, a second plurality of dielectric pillars overlying the insulation layer, and a second metal layer that fills spaces between the second plurality of dielectric pillars.

Abstract: Various embodiments facilitate die protection for an integrated circuit. In one embodiment, a multilayer structure is formed in multiple levels and along the edges of a die to prevent and detect damages to the die. The multilayer structure includes a support layer, a first plurality of dielectric pillars overlying the support layer, a metal layer that fills spaces between the first plurality of dielectric pillars, an insulation layer overlying the first plurality of dielectric pillars and the metal layer, a second plurality of dielectric pillars overlying the insulation layer, and a second metal layer that fills spaces between the second plurality of dielectric pillars.

Abstract: Various embodiments facilitate die protection for an integrated circuit. In one embodiment, a multilayer structure is formed in multiple levels and along the edges of a die to prevent and detect damages to the die. The multilayer structure includes a support layer, a first plurality of dielectric pillars overlying the support layer, a metal layer that fills spaces between the first plurality of dielectric pillars, an insulation layer overlying the first plurality of dielectric pillars and the metal layer, a second plurality of dielectric pillars overlying the insulation layer, and a second metal layer that fills spaces between the second plurality of dielectric pillars.

Abstract: The present invention discloses a method of forming a titanium nitride (TiN) thin film on a substrate disposed on a susceptor in a reaction chamber with low carbon content, low resistivity, and excellent step coverage. The method forming the TiN thin film includes feeding vapor of a Tetrakis Diethylamino Titanium (TDEAT) precursor and ammonia (NH3) gas into the reaction chamber, wherein a ratio of a vaporization rate of the TDEAT precursor to a flow rate of the ammonia gas is a value in the range of 1 mg/min:20 sccm to 1 mg/min:100 sccm; maintaining an atmosphere in the reaction chamber at a pressure in the range of 0.5 to 3.0 Torr; and heating the substrate to a temperature in the range of 300 to 400 degrees Celsius (° C.).

Abstract: The present invention discloses a method of forming a titanium nitride (TiN) thin film on a substrate disposed on a susceptor in a reaction chamber with low carbon content, low resistivity, and excellent step coverage. The method forming the TiN thin film includes feeding vapor of a Tetrakis Diethylamino Titanium (TDEAT) precursor and ammonia (NH3) gas into the reaction chamber, wherein a ratio of a vaporization rate of the TDEAT precursor to a flow rate of the ammonia gas is a value in the range of 1 mg/min:20 sccm to 1 mg/min:100 sccm; maintaining an atmosphere in the reaction chamber at a pressure in the range of 0.5 to 3.0 Torr; and heating the substrate to a temperature in the range of 300 to 400 degrees Celsius (° C.).