Abstract: An integrated circuit (IC) structure includes a back end of line (BEOL) stack on a substrate, the BEOL stack having a plurality of metal layers therein and a plurality of inter-level dielectric (ILD) layers therein. The plurality of metal layers includes a lowermost metal layer and an uppermost metal layer. A pair of metal guard structures proximate a perimeter of the BEOL stack concentrically surrounds the active circuitry. Each metal guard structure includes a continuous metal fill between the lowermost metal layer and the uppermost metal layer of the plurality of metal layers. A set of interdigitating conductive elements within one of the plurality of metal layers includes a first plurality of conductive elements electrically coupled to one of the pair of metal guard structures interdigitating with a second plurality of conductive elements electrically coupled to the other of the pair of metal guard structures.

Abstract: An integrated circuit (IC) structure includes a back end of line (BEOL) stack on a substrate, the BEOL stack having a plurality of metal layers therein and a plurality of inter-level dielectric (ILD) layers therein. The plurality of metal layers includes a lowermost metal layer and an uppermost metal layer. A pair of metal guard structures proximate a perimeter of the BEOL stack concentrically surrounds the active circuitry. Each metal guard structure includes a continuous metal fill between the lowermost metal layer and the uppermost metal layer of the plurality of metal layers. A set of interdigitating conductive elements within one of the plurality of metal layers includes a first plurality of conductive elements electrically coupled to one of the pair of metal guard structures interdigitating with a second plurality of conductive elements electrically coupled to the other of the pair of metal guard structures.

Abstract: Disclosed herein is an integrated circuit (IC) including a first metal layer running in a first direction, a second metal layer running in a second direction perpendicular to the first direction, the second metal layer above the first metal layer and a third metal layer running in the first direction above the second metal layer. A viabar electrically connects the first metal layer to the third metal layer, the viabar running in the first direction wherein the viabar vertically extends from the first metal layer to the third metal layer. A method of manufacturing the IC is provided.

Abstract: The present disclosure relates generally to flip chip technology and more particularly, to a method for fabricating a mechanically anchored controlled collapse chip connection (C4) pad on a semiconductor structure and a structure formed thereby. In an embodiment, a method is disclosed that includes forming a C4 pad on a patterned dielectric layer having grooves therein, the grooves providing an interfacial surface area between the patterned dielectric layer and the C4 pad sufficient to inhibit the C4 pad from delaminating during thermal expansion or contraction.

Abstract: Reinforcement structures used with a thinned wafer and methods of manufacture are provided. The method includes forming trenches or vias at least partially through a backside of a thinned wafer attached to a carrier wafer. The method further includes depositing material within the trenches or vias to form reinforcement structures on the backside of the thinned wafer. The method further includes removing excess material from a surface of the thinned wafer, which was deposited during the depositing of the material within the vias.

Abstract: A semiconductor structure includes filled dual reinforcing trenches that reduce curvature of the semiconductor structure by stiffening the semiconductor structure. The filled dual reinforcing trenches reduce curvature by acting against transverse loading, axial loading, and/or torsional loading of the semiconductor structure that would otherwise result in semiconductor structure curvature. The filled dual reinforcing trenches may be located in an array throughout the semiconductor structure, in particular locations within the semiconductor structure, or at the perimeter of the semiconductor structure.

Abstract: Interconnect structures for a security application and methods of forming an interconnect structure for a security application. A sacrificial masking layer is formed that includes a plurality of particles arranged with a random distribution. An etch mask is formed using the sacrificial masking layer. A hardmask is etched while masked by the etch mask to define a plurality of mask features arranged with the random distribution. A dielectric layer is etched while masked by the hardmask to form a plurality of openings in the dielectric layer that are arranged at the locations of the mask features. The openings in the dielectric layer are filled with a conductor to define a plurality of conductive features.

Abstract: The present disclosure relates generally to flip chip technology and more particularly, to a method for fabricating a mechanically anchored controlled collapse chip connection (C4) pad on a semiconductor structure and a structure formed thereby. In an embodiment, a method is disclosed that includes forming a C4 pad on a patterned dielectric layer having grooves therein, the grooves providing an interfacial surface area between the patterned dielectric layer and the C4 pad sufficient to inhibit the C4 pad from delaminating during thermal expansion or contraction.

Abstract: Interconnect structures for a security application and methods of forming an interconnect structure for a security application. A sacrificial masking layer is formed that includes a plurality of particles arranged with a random distribution. An etch mask is formed using the sacrificial masking layer. A hardmask is etched while masked by the etch mask to define a plurality of mask features arranged with the random distribution. A dielectric layer is etched while masked by the hardmask to form a plurality of openings in the dielectric layer that are arranged at the locations of the mask features. The openings in the dielectric layer are filled with a conductor to define a plurality of conductive features.

Abstract: Disclosed herein is an integrated circuit (IC) including a first metal layer running in a first direction, a second metal layer running in a second direction perpendicular to the first direction, the second metal layer above the first metal layer and a third metal layer running in the first direction above the second metal layer. A viabar electrically connects the first metal layer to the third metal layer, the viabar running in the first direction wherein the viabar vertically extends from the first metal layer to the third metal layer. A method of manufacturing the IC is provided.

Abstract: Disclosed herein is an integrated circuit (IC) including a first metal layer running in a first direction, a second metal layer running in a second direction perpendicular to the first direction, the second metal layer above the first metal layer and a third metal layer running in the first direction above the second metal layer. A viabar electrically connects the first metal layer to the third metal layer, the viabar running in the first direction wherein the viabar vertically extends from the first metal layer to the third metal layer. A method of manufacturing the IC is provided.

Abstract: A sensor for an integrated circuit (IC) structure is disclosed. The sensor includes a sensor layer in a layer of the IC structure, the sensor layer including: a first conductive structure disposed proximate a perimeter of the IC structure; and a second conductive structure disposed parallel to the first conductive structure and proximate the perimeter of the IC structure. The sensor also includes a set of interdigitating conductive elements including a first plurality of conductive elements electrically coupled to the first conductive structure interdigitating with a second plurality of conductive elements electrically coupled to the second conductive structure.

Abstract: A sensor for an integrated circuit (IC) structure is disclosed. The sensor includes a sensor layer in a layer of the IC structure, the sensor layer including: a first conductive structure disposed proximate a perimeter of the IC structure; and a second conductive structure disposed parallel to the first conductive structure and proximate the perimeter of the IC structure. The sensor also includes a set of interdigitating conductive elements including a first plurality of conductive elements electrically coupled to the first conductive structure interdigitating with a second plurality of conductive elements electrically coupled to the second conductive structure.

Abstract: Disclosed herein is an integrated circuit (IC) including a first metal layer running in a first direction, a second metal layer running in a second direction perpendicular to the first direction, the second metal layer above the first metal layer and a third metal layer running in the first direction above the second metal layer. A viabar electrically connects the first metal layer to the third metal layer, the viabar running in the first direction wherein the viabar vertically extends from the first metal layer to the third metal layer. A method of manufacturing the IC is provided.

Abstract: Reinforcement structures used with a thinned wafer and methods of manufacture are provided. The method includes forming trenches or vias at least partially through a backside of a thinned wafer attached to a carrier wafer. The method further includes depositing material within the trenches or vias to form reinforcement structures on the backside of the thinned wafer. The method further includes removing excess material from a surface of the thinned wafer, which was deposited during the depositing of the material within the vias.

Abstract: A semiconductor structure includes filled dual reinforcing trenches that reduce curvature of the semiconductor structure by stiffening the semiconductor structure. The filled dual reinforcing trenches reduce curvature by acting against transverse loading, axial loading, and/or torsional loading of the semiconductor structure that would otherwise result in semiconductor structure curvature. The filled dual reinforcing trenches may be located in an array throughout the semiconductor structure, in particular locations within the semiconductor structure, or at the perimeter of the semiconductor structure.

Abstract: A semiconductor structure includes filled dual reinforcing trenches that reduce curvature of the semiconductor structure by stiffening the semiconductor structure. The filled dual reinforcing trenches reduce curvature by acting against transverse loading, axial loading, and/or torsional loading of the semiconductor structure that would otherwise result in semiconductor structure curvature. The filled dual reinforcing trenches may be located in an array throughout the semiconductor structure, in particular locations within the semiconductor structure, or at the perimeter of the semiconductor structure.

Abstract: Interconnect structures and related methods of manufacture improve device reliability and performance by selectively incorporating dopants into conductive lines. Multiple seed layer deposition steps or variable trench bottom areas are used to locally control the dopant concentration within the interconnect structures at the same wiring level, which provides a robust integration approach for metallizing interconnects in future-generation technology nodes.

Abstract: Reinforcement structures used with a thinned wafer and methods of manufacture are provided. The method includes forming trenches or vias at least partially through a backside of a thinned wafer attached to a carrier wafer. The method further includes depositing material within the trenches or vias to form reinforcement structures on the backside of the thinned wafer. The method further includes removing excess material from a surface of the thinned wafer, which was deposited during the depositing of the material within the vias.

Abstract: A through-silicon-via (TSV) structure is formed within a trench located within a semiconductor structure. The TSV structure may include a first electrically conductive liner layer located on an outer surface of the trench and a first electrically conductive structure located on the first electrically conductive liner layer, whereby the first electrically conductive structure partially fills the trench. A second electrically conductive liner layer is located on the first electrically conductive structure, a dielectric layer is located on the second electrically conductive liner layer, while a third electrically conductive liner layer is located on the dielectric layer. A second electrically conductive structure is located on the third electrically conductive liner layer, whereby the second electrically conductive structure fills a remaining opening of the trench.