Abstract: Methods for forming an alignment mark and the resulting mark are disclosed. Embodiments may include forming a first shape having rotational symmetry; forming a second shape; and forming an alignment mark by combining the first shape and one or more of the second shape, wherein the alignment mark has rotational symmetry.

Abstract: Fabrication of through-substrate via (TSV) structures is facilitated by: forming at least one stress buffer within a substrate; forming a through-substrate via contact within the substrate, wherein the through-substrate via structure and the stress buffer(s) are disposed adjacent to or in contact with each other; and where the stress buffer(s) includes a configuration or is disposed at a location relative to the through-substrate via conductor, at least in part, according to whether the TSV structure is an isolated TSV structure, a chained TSV structure, or an arrayed TSV structure, to customize stress alleviation by the stress buffer(s) about the through-substrate via conductor based, at least in part, on the type of TSV structure.

Abstract: Approaches for simulating a photolithographic process are provided. Specifically, provided is an optical proximity correction (OPC) model that includes kernel parameters corresponding to inter-layer activity and an etch process for a connecting via of an integrated circuit (IC). A resultant intensity is determined for a corresponding plurality of process variations corresponding to the interlayer activity and the etch process. As such, the OPC model considers both interlay activity and etch process.

Abstract: A mask is disclosed which includes a plurality of first phase shift regions disposed on a first side of the mask, and a plurality of second phase shift regions disposed on a second side of the mask. The first phase shift regions and second phase shift regions may be alternating phase shift regions in which phase shift of the first phase shift regions is out of phase, for instance by 180 degrees, from phase shift of the second phase shift regions. A method for forming the mask, and a semiconductor device fabrication method using the mask is also disclosed.

Abstract: Circuit structures and methods of fabrication are provided with enhanced electrical connection between, for instance, a first metal level and a contact surface of a conductive structure. Enhanced electrical connection is achieved using a plurality of contact vias which are differently-sized, and disposed over and electrically coupled to the contact surface. The differently-sized contact vias include at least one center region contact via disposed over a center region of the contact surface, and at least one peripheral region contact via disposed over a peripheral region of the contact surface, where the at least one center region contact via is larger than the at least one peripheral region contact via.

Abstract: Circuit structures and methods of fabrication are provided with enhanced electrical connection between, for instance, a first metal level and a contact surface of a conductive structure. Enhanced electrical connection is achieved using a plurality of contact vias which are differently-sized, and disposed over and electrically coupled to the contact surface. The differently-sized contact vias include at least one center region contact via disposed over a center region of the contact surface, and at least one peripheral region contact via disposed over a peripheral region of the contact surface, where the at least one center region contact via is larger than the at least one peripheral region contact via.

Abstract: A mask is disclosed which includes a plurality of first phase shift regions disposed on a first side of the mask, and a plurality of second phase shift regions disposed on a second side of the mask. The first phase shift regions and second phase shift regions may be alternating phase shift regions in which phase shift of the first phase shift regions is out of phase, for instance by 180 degrees, from phase shift of the second phase shift regions. A method for forming the mask, and a semiconductor device fabrication method using the mask is also disclosed.

Abstract: A method and a resulting device are provided for forming stack overlay and registration monitoring structures for FEOL layers including implant layers and for forming BEOL SEM overlay and registration monitoring structures including BEOL interconnections, respectively. Embodiments include forming an active monitoring structure having first and second edges separated by a first distance in an active layer on a semiconductor substrate; forming a poly monitoring structure having first and second edges separated by a second distance in a poly layer; and forming one or more contact monitoring structures in a contact layer, collectively exposing at least the first and second edges of each of the active and poly monitoring structures; wherein the active, poly, and contact monitoring structures are formed in an area which includes no IC patterns in the active, the poly, and the contact layers, respectively.

Abstract: Methods for reducing reticle transmission differences and for optimizing layer placement for overlay in MTRs and CTRs are disclosed. Embodiments include providing a reticle having a prime area and a frame area surrounding the prime area; determining RT differences across the prime area; and providing RT adjustment structures on the reticle to decrease the RT differences. Other embodiments include grouping multiple layers of a semiconductor production flow, the layers for each group having an RT difference less than a predetermined value; and placing the layers on plural ordered reticles of a reticle set, each reticle having multiple image fields, by selecting, for each reticle, layers from a single group and optimizing placement of the layers for overlay. Other embodiments include selectively rotating image fields on a reticle having multiple image fields to improve overlay, or optimizing placement of DDLs on CTRs by placing each design orientation on a different reticle.

Abstract: Reticle and methods for forming a device or reticle are presented. A reticle is provided with a device pattern and a first monitoring pattern. The first monitoring pattern includes a plurality of first test cells having a first test cell area and a first test pattern. The first test cells have different first pitch ratios to an anchor pitch and the first test pattern fills the first test cell area of a first test cell. A wafer with a resist layer is exposed with a lithographic system using the reticle. The resist is developed to form a patterned resist layer on the wafer and the wafer is processed using the patterned resist layer.

Abstract: A mask is disclosed which includes a plurality of first phase shift regions disposed on a first side of the mask, and a plurality of second phase shift regions disposed on a second side of the mask. The first phase shift regions and second phase shift regions may be alternating phase shift regions in which phase shift of the first phase shift regions is out of phase, for instance by 180 degrees, from phase shift of the second phase shift regions. A method for forming the mask, and a semiconductor device fabrication method using the mask is also disclosed.

Abstract: The present invention provides for a method and an apparatus for implementing programmed latency for improved wafer-to-wafer uniformity. Semiconductor devices for wafer-by-wafer analysis are identified. At least one value of a controlled variable in the wafer-by-wafer analysis is identified. A trajectory of recipes for the identified semiconductor devices is created. A sequence analysis of wafer-to-wafer variations is performed using the trajectory of recipes upon the identified semiconductor devices. A latency control is performed in response to the sequence analysis. A feed-forward implementation of wafer-by-wafer latency control is performed using the trajectory of recipes upon the identified semiconductor devices.

Abstract: An automated data management system for enabling the analysis and control of the performance of photolithography steppers in a submicron fabrication facility disclosed. In a preferred embodiments, software running on each of a plurality of first personal computers (PCs), each of which is connected to one of a plurality of steppers, is used to append printer data generated by the steppers responsive to tests, performed therein to ASCII files associated with the steppers and subsequently to upload the ASCII files to a network drive at specified time intervals. Once the ASCII files have been uploaded to the VAX drive, the files may be accessed by a user outside the facility using a second PC on which is running a utility of the present invention for providing automated analysis of the data for a particular stepper as requested by a user.

Abstract: An automated data management system for enabling the analysis and control of the performance of photolithography steppers in a submicron fabrication facility is disclosed. In a preferred embodiments, software running on each of a plurality of first personal computers (PCs), each of which is connected to one of a plurality of steppers, is used to append printer data generated by the steppers responsive to tests performed therein to ASCII files associated with the steppers and subsequently to upload the ASCII files to a network drive at specified time intervals. Once the ASCII files have been uploaded to the VAX drive, the files may be accessed by a user outside the facility using a second PC on which is running a utility of the present invention for providing automated analysis of the data for a particular stepper as requested by a user.