Patent application number | Description | Published |
20080246097 | METHODS FOR REDUCING WITHIN CHIP DEVICE PARAMETER VARIATIONS - A method of reducing parametric variation in an integrated circuit (IC) chip and an IC chip with reduced parametric variation. The method includes: on a first wafer having a first arrangement of chips, each IC chip divided into a second arrangement of regions, measuring a test device parameter of test devices distributed in different regions; and on a second wafer having the first arrangement of IC chips and the second arrangement of regions, adjusting a functional device parameter of identically designed field effect transistors within one or more regions of all IC chips of the second wafer based on a values of the test device parameter measured on test devices in regions of the IC chip of the first wafer by a non-uniform adjustment of physical or metallurgical polysilicon gate widths of the identically designed field effect transistors from region to region within each IC chip. | 10-09-2008 |
20080254633 | MULTIPLE EXPOSURE LITHOGRAPHY METHOD INCORPORATING INTERMEDIATE LAYER PATTERNING - A method of patterning a semiconductor substrate includes creating a first set of patterned features in a first inorganic layer; creating a second set of patterned features in one of the first inorganic layer and a second inorganic layer; and transferring, into an organic underlayer, both the first and second sets of patterned features, wherein the first and second sets of patterned features are combined into a composite set of patterned features that are transferable into the substrate by using the organic underlayer as a mask. | 10-16-2008 |
20080286683 | COMPOSITE STRUCTURES TO PREVENT PATTERN COLLAPSE - A method and a structure. The structure includes: a solid core comprising a first photoresist material, the core having a bottom surface on a substrate, a top surface and opposite first and second side surfaces between the top surface and the bottom surface; and a shell comprising a second photoresist material, the shell on the top surface of the substrate, the shell containing a cavity open to the top surface of the substrate, the shell formed over the top surface and the first and second side surfaces walls of the core, the core completely filling the cavity. The core is stiffer than the shell. The method includes: forming the core from a first photoresist layer and forming the shell from a second photoresist layer applied over the core. The core may be cross-linked to increase its stiffness. | 11-20-2008 |
20080311508 | PROCESS OF MAKING A SEMICONDUCTOR DEVICE USING MULTIPLE ANTIREFLECTIVE MATERIALS - A lithographic structure consisting essentially of: an organic antireflective material disposed on a substrate; a vapor-deposited RCHX material, wherein R is one or more elements selected from the group consisting of Si, Ge, B, Sn, Fe and Ti, and wherein X is not present or is one or more elements selected from the group consisting of O, N, S and F; and a photoresist material disposed on the RCHX material. The invention is also directed to methods of making the lithographic structure, and using the structure to pattern a substrate. | 12-18-2008 |
20090061355 | PROCESS OF MAKING A LITHOGRAPHIC STRUCTURE USING ANTIREFLECTIVE MATERIALS - A lithographic structure comprising: an organic antireflective material disposed on a substrate; and a silicon antireflective material disposed on the organic antireflective material. The silicon antireflective material comprises a crosslinked polymer with a SiO | 03-05-2009 |
20090065956 | MEMORY CELL - Methods of forming line ends and a related memory cell including the line ends are disclosed. In one embodiment, the memory cell includes fa first device having a first conductive line extending over a first active region and having a first line end of the first conductive line positioned over an isolation region adjacent to the first active region; and a second device having a second conductive line extending over one of a second active region and a contact element and having a second line end of the second conductive line positioned over the isolation region adjacent to the one of the second active region and the contact element, wherein the first line end and the second line end each include a bulbous end that is distanced from a respective active region or contact element. | 03-12-2009 |
20090068837 | LINE ENDS FORMING - Methods of forming line ends and a related memory cell including the line ends are disclosed. In one embodiment, the method includes forming a first device element and a second device element separated from the first device element by a space; and forming a first line extending from the first device element, the first line including a bulbous line end over the space and distanced from the first device element, and a second line extending from the second device element, the second line including a bulbous line end over the space and distanced from the second device element. | 03-12-2009 |
20090081563 | Integrated Circuits and Methods of Design and Manufacture Thereof - Integrated circuits and methods of manufacture and design thereof are disclosed. For example, a method of manufacturing includes depositing a gate material over a semiconductor substrate, and depositing a first resist layer over the gate material. A first mask is used to pattern the first resist layer to form first and second resist features. The first resist features include pattern for gate lines of the semiconductor device and the second resist features include printing assist features. A second mask is used to form a resist template; the second mask removes the second resist features. | 03-26-2009 |
20090117737 | POLYCONDUCTOR LINE END FORMATION AND RELATED MASK - Methods of forming adjacent polyconductor line ends and a mask therefor are disclosed. In one embodiment, the method includes forming a polyconductor layer over an isolation region; forming a mask over the polyconductor layer, the mask including shapes to create the polyconductor line ends and a correction element to ensure a designed proximity of the polyconductor line ends; and etching the polyconductor layer using the patterned photoresist mask to create the adjacent polyconductor line ends, wherein the correction element is removed during the etching. | 05-07-2009 |
20090284722 | METHOD FOR MONITORING FOCUS ON AN INTEGRATED WAFER - A method and apparatus are provided for improving the focusing of a substrate such as a wafer during the photolithography imaging procedure of a semiconductor manufacturing process. The invention is particularly useful for step-and-scan system and the CD of two features in each exposure field are measured in fields exposed at varying focus to form at least two Bossung curves. Exposure focus instructions are calculated based on the intersection point of the curves and the wafer is then scanned and imaged based on the calculated exposure focus instructions. In another aspect of the invention, when multiple wafers are being processed operational variances may cause a drift in the focus. The focus drift can be easily corrected by measuring the critical dimension of each of the features and comparing the difference to determine if any focus offset is needed to return the focus to the original calculated focus value. | 11-19-2009 |
20120076982 | STRUCTURE RESULTING FROM CHEMICAL SHRINK PROCESS OVER BARC (BOTTOM ANTI-REFLECTIVE COATING) - A structure. The structure includes: a hole layer; a hole layer including a top hole layer surface, wherein the hole layer has a thickness in a first direction that is perpendicular to the hole layer surface; a bottom antireflective coating (BARC) layer on and in direct physical contact with the hole layer at the top hole layer surface; a photoresist layer on and in direct physical contact with the BARC layer, wherein a continuous hole in the first direction extends completely through the photoresist layer, the BARC layer, and the hole layer; and a polymerized hole shrinking region in direct physical contact with the photoresist layer at a lateral surface of the photoresist layer and with the hole layer at the top hole layer surface, wherein the hole shrinking region does not extend below the hole layer surface in a direction from the BARC layer to the hole layer. | 03-29-2012 |
20120126294 | WAFER FILL PATTERNS AND USES - A method of forming a semiconductor device having a substrate, an active region and an inactive region includes: forming a hardmask layer over the substrate; transferring a first pattern into the hardmask layer in the active region of the semiconductor device; forming one or more fills in the inactive region; forming a cut-away hole within, covering, or partially covering, the one or more fills to expose a portion of the hardmask layer, the exposed portion being within the one or more fills; and exposing the hardmask layer to an etchant to divide the first pattern into a second pattern including at least two separate elements. | 05-24-2012 |
20130001193 | ALIGNMENT MARKS FOR MULTI-EXPOSURE LITHOGRAPHY - A plurality of reticles for printing structures in the same lithography level includes an alignment structure pattern within a same relative location in each reticle. Each set of process segmentations in a grating has a reticle segmentation pitch, which is common across all gratings in the plurality of reticles. Within each pair of alignment structure patterns that occupy the same relative location in any two of the plurality of reticles, the process segmentations in one reticle are shifted relative to the process segmentations in the other reticle by a fraction of a reticle segmentation pitch. After printing all patterns in the plurality of reticles, a composite printed process segmentation structure on the substrate includes printed segmentation structures that are spaced by 1/n times the printed segmentation pitch. The pattern for the next level can be aligned to the composite printed process segmentation structure in a single alignment operation. | 01-03-2013 |
20130017486 | PROCESS OF MAKING A LITHOGRAPHIC STRUCTURE USING ANTIREFLECTIVE MATERIALS - A lithographic structure comprising: an organic antireflective material disposed on a substrate, and a silicon antireflective material disposed on the organic antireflective material. The silicon antireflective material comprises a crosslinked polymer with a SiO | 01-17-2013 |
20130041494 | ALIGNMENT DATA BASED PROCESS CONTROL SYSTEM - Deformation of a substrate due to one or more processing steps is determined by measuring substrate alignment data at lithographic processing steps before and after the one or more processing steps. Any abnormal pattern in the alignment data differential is identified by comparing the calculated alignment data differential with previous data accumulated in a database. By comparing the abnormal pattern with previously identified tool-specific patterns for alignment data differential, a processing step that introduces the abnormal pattern and/or the nature of the abnormal processing can be identified, and appropriate process control measures can be taken to rectify any anomaly in the identified processing step. | 02-14-2013 |
20130177840 | ALIGNMENT MARKS FOR MULTI-EXPOSURE LITHOGRAPHY - A plurality of reticles for printing structures in the same lithography level includes an alignment structure pattern within a same relative location in each reticle. Each set of process segmentations in a grating has a reticle segmentation pitch, which is common across all gratings in the plurality of reticles. Within each pair of alignment structure patterns that occupy the same relative location in any two of the plurality of reticles, the process segmentations in one reticle are shifted relative to the process segmentations in the other reticle by a fraction of a reticle segmentation pitch. After printing all patterns in the plurality of reticles, a composite printed process segmentation structure on the substrate includes printed segmentation structures that are spaced by 1/n times the printed segmentation pitch. The pattern for the next level can be aligned to the composite printed process segmentation structure in a single alignment operation. | 07-11-2013 |