Dr. Kevin Lucas Profile

Dr. Kevin Lucas

Product Engineering manager at Synopsys Inc

SPIE Involvement:

Conference Program Committee | Author | Instructor

Publications (148)

Proceedings Article | 10 April 2024 Presentation

Advancing the curvilinear ILT and OPC ecosystem for low-k1 DUV and EUV lithography

Guangming Xiao, Kevin Hooker, Yunqiang Zhang, Ji Li, Thuc Dam, Yu-Po Tang, Linghui Wu, WooJoo Sim, Kevin Lucas

Proceedings Volume 12954, 1295413 (2024) https://doi.org/10.1117/12.3014637

KEYWORDS: Photomasks, Deep ultraviolet, Optical proximity correction, Extreme ultraviolet lithography, Ecosystems, Lithography, Extreme ultraviolet, Yield improvement, Source mask optimization, Printing

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Proceedings Article | 10 April 2024 Presentation + Paper

High accuracy OPC electromagnetic full-chip modeling for curvilinear mask OPC and ILT

Enas Sakr, Zac Levinson, Rob DeLancey, C. Jay Lee, Jinguang Li, Ryan Chen, Robert Iwanow, Delian Yang, Wolfgang Hoppe, Folarin Latinwo, Kevin Lucas, Peng Liu

Proceedings Volume 12954, 129540N (2024) https://doi.org/10.1117/12.3013089

KEYWORDS: Optical proximity correction, Electromagnetism, Semiconducting wafers, Extreme ultraviolet, Cadmium, 3D mask effects, Modeling, Lithography, Computational lithography, Ranging

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Proceedings Article | 10 April 2024 Presentation + Paper

Advances in full-chip three-dimensional resist modeling for low k1 EUV and DUV lithography

Elizabeth Grubbs, Bernd Kuechler, Hyesook Hong, Enas Sakr, Lena Zavyalova, Folarin Latinwo, Delian Yang, Linghui Wu, Yan Feng, Kevin Lucas

Proceedings Volume 12954, 129540S (2024) https://doi.org/10.1117/12.3013125

KEYWORDS: 3D modeling, Modeling, Lithography, Data modeling, Calibration, Deep ultraviolet, Optical proximity correction, Extreme ultraviolet, Photoresist processing, Shrinkage

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SPIE Journal Paper | 20 December 2023

Enhancing mask synthesis for curvilinear masks in full-chip extreme ultraviolet lithography

Kevin Hooker, Guangming Xiao, Yu-Po Tang, Yunqiang Zhang, Moongyu Jeong, John Valadez, Kevin Lucas

JM3, Vol. 22, Issue 04, 041606, (December 2023) https://doi.org/10.1117/12.10.1117/1.JMM.22.4.041606

KEYWORDS: Optical proximity correction, Extreme ultraviolet lithography, Lithography, Optical lithography, Machine learning, Extreme ultraviolet, Semiconducting wafers, Education and training, Industry, Source mask optimization

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Proceedings Article | 28 April 2023 Presentation + Paper

High accuracy OPC modeling for new EUV low-K1 mask technology options

Enas Sakr, Rob DeLancey, Wolfgang Hoppe, Zac Levinson, Robert Iwanow, Ryan Chen, Delian Yang, Kevin Lucas

Proceedings Volume 12495, 124950P (2023) https://doi.org/10.1117/12.2658720

KEYWORDS: Extreme ultraviolet, Optical proximity correction, Multilayers, Optical lithography, Modeling, 3D mask effects

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EUV lithography has been ramped to successful volume manufacturing through a combination of improvements in process technology, layout design and device interactions, and also optimization of the overall product integration to reduce undesirable interactions. Because EUV has additional sources of systematic and stochastic variation that did not exist in DUV lithography, it is now even more important to have accurate predictive capability to test and understand the design and lithography process interactions. EUV-specific physical behavior such as shadowing, flare, mask topography (i.e., Mask3D) effects, mask stack reflectivity, mask absorber behavior and other effects are key differences in how EUV forms an image on the mask and subsequently on the wafer. The reflective mask substrate and EUV-specific mask absorber stack are therefore highly important technologies to optimize as the industry pushes both low NA (0.33NA) and high NA (0.55NA) technologies to cover the patterning requirements of upcoming 3nm and below technology nodes. Recently there have been substantial industry interest in optimizing EUV mask stacks to further enhance imaging behavior and achieve better pattern resolution, increase process window, lower stochastic defectivity and optimize flare. Several different options have been proposed for these new EUV mask stacks for lower K1 EUV patterning. All of these new options require excellent simulation accuracy in OPC, SrAF placement, OPC verification and ILT mask synthesis steps in order to realize the benefits of the new mask stacks. In this paper we will focus on analyzing and improving the accurate prediction of a range of new EUV mask stack options for full-chip OPC/ILT compatible compact models. We will show for advanced mask designs the accuracy requirements and capability of leading-edge compact models. The accuracy requirements and capability will be referenced to fully rigorous electromagnetic solver (e.g., Mask3D) results to ensure industry needs are met. We will also explore the mask stack options to highlight the imaging benefits for different material thickness, refractive index (n) and extinction coefficient (k) on important mask pattern feature and layer types.

Proceedings Article | 28 April 2023 Presentation + Paper

Evaluation of field stitching optimization for robust manufacturing with high-NA EUVL

Zachary Levinson, Thuc Dam, Paul Pfaeffli, C. Jay Lee, Wolfgang Hoppe, Ulrich Klostermann, Kevin Lucas

Proceedings Volume 12495, 124950B (2023) https://doi.org/10.1117/12.2659721

KEYWORDS: Reticles, Etching, Tolerancing, Extreme ultraviolet lithography, Simulations, Mirrors, Scanners, Manufacturing, Semiconducting wafers, Metals

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Proceedings Article | 13 June 2022 Presentation

Improved prediction of assist feature printing with physically-based NTD compact models

Folarin Latinwo, Yulu Chen, Cheng-En Wu, Peter Brooker, Hyesook Hong, Delian Yang, Hua Song, Kevin Lucas

Proceedings Volume 12052, 120520P (2022) https://doi.org/10.1117/12.2615990

KEYWORDS: Printing, Data modeling, Data processing, Semiconductors, Semiconducting wafers, Process control, Photoresist materials, Photoresist developing, Optical lithography, Metrology

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Proceedings Article | 25 May 2022 Presentation + Paper

Curvilinear mask solutions for full-chip EUV lithography

Kevin Hooker, Guangming Xiao, Yu-Po Tang, Yunqiang Zhang, Moongyu Jeong, John Valadez, Kevin Lucas

Proceedings Volume 12054, 1205407 (2022) https://doi.org/10.1117/12.2618392

KEYWORDS: Photomasks, Optical proximity correction, Optical lithography, Lithography, Extreme ultraviolet, Extreme ultraviolet lithography, Machine learning, Semiconducting wafers, Manufacturing, Deep ultraviolet

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Proceedings Article | 22 February 2021 Presentation

Validation of machine learning OPC compact models for advanced manufacturing

Moongyu Jeong, Marco Guajardo, Cheng-En Wu, Song-haeng Lee, Tim Fuehner, Lena Zavyalova, Li-Jin Chen, Hua Song, Kevin Lucas

Proceedings Volume 11614, 116140R (2021) https://doi.org/10.1117/12.2584940

KEYWORDS: Optical proximity correction, Machine learning, Data modeling, Manufacturing, Critical dimension metrology, Semiconductors, Photomasks, Semiconducting wafers, Optical lithography, Neural networks

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Proceedings Article | 22 February 2021 Presentation

Increased OPC modeling accuracy of deformation effects in positive-tone development photoresists

Folarin Latinwo, Yulu Chen, Delian Yang, Rob DeLancey, Owen Huang, Kevin Lucas

Proceedings Volume 11613, 116130F (2021) https://doi.org/10.1117/12.2584781

KEYWORDS: Photoresist materials, Photoresist developing, Optical proximity correction, Optical lithography, Semiconductors, Polymers, Physics, Photoresist processing, Pollution control, Logic

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Proceedings Article | 22 February 2021 Presentation

Predicting very rare stochastic defects in EUVL processes for full-chip correction and verification

Zachary Adam Levinson, Yudhishthir Kandel, Makoto Miyagi, Kevin Lucas

Proceedings Volume 11609, 1160915 (2021) https://doi.org/10.1117/12.2585068

KEYWORDS: Stochastic processes, Extreme ultraviolet lithography, Lithography, Image processing, Photoresist materials, Absorption, Photon counting, Critical dimension metrology, Statistical analysis, Source mask optimization

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Proceedings Article | 23 March 2020 Paper

Compact modeling to predict and correct stochastic hotspots in EUVL

Zachary Levinson, Yudhishthir Kandel, Yunqiang Zhang, Qiliang Yan, Makoto Miyagi, Xiaohai Li, Kevin Lucas

Proceedings Volume 11323, 1132324 (2020) https://doi.org/10.1117/12.2554099

KEYWORDS: Stochastic processes, Optical proximity correction, Extreme ultraviolet lithography, Data modeling, Critical dimension metrology, Calibration, Monte Carlo methods, Lithography, Failure analysis, Image processing

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Proceedings Article | 23 March 2020 Presentation + Paper

Multi-varied implementations with common underpinnings in design technology co-optimization

Kevin Lucas, Victor Moroz, John Kim, Soo-Han Choi, Tim Tsuei

Proceedings Volume 11328, 113280Y (2020) https://doi.org/10.1117/12.2553656

KEYWORDS: Device simulation, Optical lithography, Silicon, Semiconducting wafers, Process modeling, Visualization, Lithography, Design for manufacturing

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Fueled by higher bandwidth wireless communication and ubiquitous AI, the demand for more affordable and power efficient transistors is accelerating at a time when Dennard scaling is undeniably crawling to a halt. Escalating wafer and design cost are commonly identified as the primary culprits bringing Moore's law to its knees. However, a third component: the cost of making the wrong technology choice early in the development cycle, is equally responsible for slowing the progress of the semiconductor industry. The enormous complexity of leading edge technology nodes has been achieved incrementally over time by limiting each technology node to mostly small evolutionary steps. Forcing too much innovation in one technology node would have catastrophically disrupted the continuous learning curve. As we approach the fundamental device-physics and material-science limits of dimensional scaling, we are forced to look at far more disruptive device and interconnect innovations to achieve meaningful power-performance-area-cost (PPAC) improvement. For example, the complexity versus benefit tradeoffs of innovative 3-dimensional device architectures with non-standard power-distribution networks are so hard to quantify that rigorous yet efficient prototyping becomes indispensable even prior to committing foundry R&D resources. In this paper we present our work on developing a purpose-built suite of tools to vastly accelerate the quantitative pre-screening and optimization of technology options to help the industry maintain its relentless pace of PPAC scaling. We share several examples that demonstrate how we tune a candidate technology definition with this tool-suite. We also describe the important common technologies in successful Design Technology Co-Optimization (DTCO) flows including physical material and process modeling; electrical and circuit simulation; detailed design analysis and modification to reduce weak points; handling enormous datasets; silicon learning feedback loop and intuitive visualization.

Proceedings Article | 21 March 2019 Presentation + Paper

Improved validation and optimization of physics-based NTD compact modeling flows

Folarin Latinwo, Delian Yang, Cheng-En (Rich) Wu, Peter Brooker, Yulu Chen, Hua Song, Kevin Lucas

Proceedings Volume 10961, 109610G (2019) https://doi.org/10.1117/12.2516344

KEYWORDS: Data modeling, Calibration, 3D modeling, Photoresist developing, Photoresist materials, Lithography, Optical lithography

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Due to the semiconductor industry’s ever increasing need for finer resolution and improved critical dimension (CD) control, negative tone development (NTD) photoresists (resists) have been adopted for several advanced applications in lithographic patterning. NTD resists enable brightfield imaging by using an organic solvent developer to penetrate and remove the unexposed regions of the resist [1]. For certain critical patterning layers, such as metal trenches and vias, NTD resists are able to provide better resist imaging quality compared to the previous positive tone development (PTD) resist process. However, there are several additional engineering difficulties which must be addressed for an NTD resist process. Specifically, NTD resists have low contrast organic solvent development and in an NTD process the material remaining on the wafer substrate is exposed resist which has been substantially transformed both chemically and mechanically. Therefore, the remaining exposed resist shows significantly more complex physical behavior than the remaining PTD resist and these behaviors require substantial improvement in an OPC (compact) model’s physical modeling accuracy in order to match wafer data and trends [2,3]. Additionally, these more complex resist behaviors place further requirements on the physical validation of OPC modeling inference. In this paper, we present results of our work to understand and improve the optimization and physical validation of physics-based NTD compact modeling flows by utilizing new methods for analysis and automation. We utilize a complete compact model flow containing physics-based resist model forms for chemically amplified resist (CAR) exposure, CAR reaction-diffusion, resist top-loss due to exposure combined with post-exposure bake (PEB), low contrast organic solvent development of resist, and mechanical deformation effects in multiple process steps. We present solid evidence that this physically-based flow has been validated for accuracy and predictability by comparing it to several experimental NTD datasets and to results of rigorous 3D lithography simulation models which were trained to fit other experimental NTD data. We additionally compared key physics-based model forms from the compact model to the more complex full time-based moving surface NTD models of the rigorous 3D simulation. We next analyzed the key physics-based compact model forms for sensitivity to input testpattern type, layout and mask dimension (e.g., linearity and MEEF), traditional dose-focus variations, as well as systematic and random noise in CD metrology. We present the results of this study and make recommendations for minimum testpattern and overall process space data to include in NTD compact model datasets. We also present flow benefits obtained from automating different validation tests including the usefulness of employing rigorous lithography simulation NTD results early in the compact modeling flow to improve overall model quality. [1] S-H. Lee, et all. Understanding dissolution behavior of 193-nm photoresists in organic solvent developers.

Proceedings Article | 20 March 2019 Paper

Investigation of machine learning for dual OPC and assist feature printing optimization

Marco Guajardo, Yulu Chen, Peter Brooker, C.-E. Wu, Kevin Hooker, Folarin Latinwo, Kevin Lucas

Proceedings Volume 10962, 109620E (2019) https://doi.org/10.1117/12.2516134

KEYWORDS: Printing, Optical proximity correction, Photomasks, Calibration, 3D modeling, Semiconducting wafers, Machine learning, Data modeling, Lithography

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Proceedings Article | 8 October 2018 Presentation + Paper

3D NTD resist deformation compact model for OPC and ILT applications

Rich Wu, Delian Yang, Folarin Latinwo, Kevin Lucas, Hua Song

Proceedings Volume 10810, 108101A (2018) https://doi.org/10.1117/12.2501992

KEYWORDS: 3D modeling, Photoresist processing, Optical proximity correction, Photoresist materials, Photomasks, Optical lithography, Photoresist developing, Semiconducting wafers, Lithography, Data modeling

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Proceedings Article | 19 March 2018 Presentation + Paper

Double patterning at NA 0.33 versus high-NA single exposure in EUV lithography: an imaging comparison

Weimin Gao, Vincent Wiaux, Wolfgang Hoppe, Vicky Philipsen, Lawrence Melvin, Eric Hendrickx, Kevin Lucas, Ryoung-han Kim

Proceedings Volume 10583, 105830O (2018) https://doi.org/10.1117/12.2297677

KEYWORDS: Photomasks, Optical proximity correction, Double patterning technology, Lithography, Extreme ultraviolet lithography, Image processing

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Proceedings Article | 16 October 2017 Paper

Improved testpatterns and coverage for complex SrAF to optimize 5nm and below OPC and mask patterning

Marco Guajardo, Hesham Abdelghany, Ahmed Omran, Yu Chen, Kevin Lucas

Proceedings Volume 10451, 104511N (2017) https://doi.org/10.1117/12.2280585

KEYWORDS: SRAF, Neural networks, Optical proximity correction, Manufacturing, Neurons, Optical lithography, Machine learning, Data modeling, Control systems

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Proceedings Article | 28 September 2017 Paper

ILT optimization of EUV masks for sub-7nm lithography

Kevin Hooker, Bernd Kuechler, Aram Kazarian, Guangming Xiao, Kevin Lucas

Proceedings Volume 10446, 1044604 (2017) https://doi.org/10.1117/12.2279912

KEYWORDS: Extreme ultraviolet, Lithography, Extreme ultraviolet lithography, Photomasks, Optical lithography, Optical proximity correction, Resolution enhancement technologies

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Proceedings Article | 4 April 2017 Presentation + Paper

Cost effective solution using inverse lithography OPC for DRAM random contact layer

Jinhyuck Jun, Jaehee Hwang, Jaeseung Choi, Seyoung Oh, Chanha Park, Hyunjo Yang, Thuc Dam, Munhoe Do, Dong Chan Lee, Guangming Xiao, Jung-Hoe Choi, Kevin Lucas

Proceedings Volume 10148, 1014809 (2017) https://doi.org/10.1117/12.2257857

KEYWORDS: Lithography, Optical proximity correction, Optical lithography, Manufacturing, Photomasks, Semiconducting wafers, Atrial fibrillation, Source mask optimization, Image processing

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Proceedings Article | 24 March 2017 Presentation + Paper

New methodologies for lower-K1 EUV OPC and RET optimization

Kevin Hooker, Aram Kazarian, Xibin Zhou, Josh Tuttle, Guangming Xiao, Yunqiang Zhang, Kevin Lucas

Proceedings Volume 10143, 101431C (2017) https://doi.org/10.1117/12.2258186

KEYWORDS: Extreme ultraviolet, Optical lithography, Extreme ultraviolet lithography, Photomasks, Optical proximity correction, Resolution enhancement technologies, Reticles, SRAF, Semiconducting wafers, Lithography, Critical dimension metrology, Manufacturing, Atrial fibrillation

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Proceedings Article | 16 March 2016 Paper

Building block style recipes for productivity improvement in OPC, RET and ILT flows

Linghui Wu, Denny Kwa, Jinyin Wan, Tom Wang, Matt St. John, Steven Deeth, Xiaohui Chen, Tom Cecil, Xiaodong Meng, Kevin Lucas

Proceedings Volume 9781, 978116 (2016) https://doi.org/10.1117/12.2222591

KEYWORDS: Optical proximity correction, Photomasks, Lithography, Computer programming, Resolution enhancement technologies, Model-based design, Optical lithography, 193nm lithography, Atrial fibrillation, Software development

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Traditional model-based Optical Proximity Correction (OPC) and rule-based Resolution Enhancement Technology (RET) methods have been the workhorse mask synthesis methods in volume production for logic and memory devices for more than 15 years. Rule-based OPC methods have been in standard use for over 20 years now. With continuous technical enhancements, these methods have proven themselves robust, flexible and fast enough to meet many of the technical needs of even the most advanced nodes. Inverse Lithography Technology (ILT) methods are well known to have strong benefits in finding flexible mask pattern solutions to improve process window for the most advanced design locations where traditional methods are not sufficient.

However, OPC/RET requirements at each node have changed radically in the last 20 years beyond just technical requirements. The volume of engineering work to be done has also skyrocketed. The number of device layers which need OPC/RET can be 10X higher than in earlier nodes. Additionally, the number of mask layers per device layer is often 2X or more times higher with multiple patterning. Finally, the number of features to correct per mask increases ~2X with each node. These factors led to a large increase in the number of OPC engineers needed to develop the complex new OPC/RET recipes for advanced nodes.

In this paper, we describe new developments which significantly improve the productivity of OPC engineers to deploy Rule Based OPC (RBOPC), Model Based OPC (MBOPC), AF, and ILT recipes in modern manufacturing flows. In addition to technical improvements such as novel multiple segment hotspot fixing solvers and ILT hot-spot fixing necessary to support correction needs, we have re-architected the entire flow based on how OPC engineers now develop and maintain OPC/RET recipes. The re-architecture of the flow takes advantages of more recent developments in modular and structured programming methods which are known to benefit ease engineering software development applications. Therefore, this improved OPC/RET development methodology includes specifically targeted advanced new technical functions; new types of modular structures for much faster reuse of customizations; and new interfaces to flexible programming capabilities to enable easier development and integration of deep customizations for the most challenging technical needs.

SPIE Journal Paper | 19 February 2016

^{Rigorous assessment of patterning solution of metal layer in 7 nm technology node}

Weimin Gao, Ivan Ciofi, Yves Saad, Philippe Matagne, Michael Bachmann, Werner Gillijns, Kevin Lucas, Wolfgang Demmerle, Thomas Schmöller

JM3, Vol. 15, Issue 01, 013505, (February 2016) https://doi.org/10.1117/12.10.1117/1.JMM.15.1.013505

KEYWORDS: Optical lithography, Etching, Extreme ultraviolet lithography, Metals, Lithography, Critical dimension metrology, 3D modeling, Stochastic processes, Cadmium, Extreme ultraviolet

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Proceedings Article | 19 March 2015 Paper

Experimental validation of stochastic modeling for negative-tone develop EUV resists

Itaru Kamohara, Weimin Gao, Ulrich Klostermann, Thomas Schmöller, Wolfgang Demmerle, Kevin Lucas, Danilo De Simone, Eric Hendrickx, Geert Vandenberghe

Proceedings Volume 9422, 942223 (2015) https://doi.org/10.1117/12.2085506

KEYWORDS: Line width roughness, Stochastic processes, Calibration, Extreme ultraviolet, Extreme ultraviolet lithography, Nanoimprint lithography, Data modeling, Scanning electron microscopy, Photoresist processing, Photomasks

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Proceedings Article | 18 March 2015 Paper

Patterning process exploration of metal 1 layer in 7nm node with 3D patterning flow simulations

Weimin Gao, Ivan Ciofi, Yves Saad, Philippe Matagne, Michael Bachmann, Mohamed Oulmane, Werner Gillijns, Kevin Lucas, Wolfgang Demmerle, Thomas Schmoeller

Proceedings Volume 9426, 942606 (2015) https://doi.org/10.1117/12.2085328

KEYWORDS: Etching, Optical lithography, Extreme ultraviolet lithography, Lithography, Extreme ultraviolet, 3D modeling, Metals, Stochastic processes, Cadmium, 3D vision

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SPIE Journal Paper | 7 May 2014

Study of CD variation caused by the black border effect and out-of-band radiation in extreme ultraviolet lithography

Weimin Gao, Ardavan Niroomand, Gian Lorusso, Robert Boone, Kevin Lucas, Wolfgang Demmerle

JM3, Vol. 13, Issue 02, 023005, (May 2014) https://doi.org/10.1117/12.10.1117/1.JMM.13.2.023005

KEYWORDS: Critical dimension metrology, Extreme ultraviolet lithography, Radiation effects, Etching, Extreme ultraviolet, Photomasks, Reflectivity, Semiconducting wafers, Cadmium, Lithography

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Proceedings Article | 31 March 2014 Paper

Hybrid inverse lithography techniques for advanced hierarchical memories

Guangming Xiao, Kevin Hooker, Dave Irby, Yunqiang Zhang, Brian Ward, Tom Cecil, Brett Hall, Mindy Lee, Dave Kim, Kevin Lucas

Proceedings Volume 9052, 90522D (2014) https://doi.org/10.1117/12.2048022

KEYWORDS: Photomasks, Lithography, Optical lithography, Optical proximity correction, Chromium, Model-based design, Logic, Optimization (mathematics), Semiconducting wafers, Critical dimension metrology

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Traditional segment-based model-based OPC methods have been the mainstream mask layout optimization techniques in volume production for memory and embedded memory devices for many device generations. These techniques have been continually optimized over time to meet the ever increasing difficulties of memory and memory periphery patterning. There are a range of difficult issues for patterning embedded memories successfully. These difficulties include the need for a very high level of symmetry and consistency (both within memory cells themselves and between cells) due to circuit effects such as noise margin requirements in SRAMs. Memory cells and access structures consume a large percentage of area in embedded devices so there is a very high return from shrinking the cell area as much as possible. This aggressive scaling leads to very difficult resolution, 2D CD control and process window requirements. Additionally, the range of interactions between mask synthesis corrections of neighboring areas can extend well beyond the size of the memory cell, making it difficult to fully take advantage of the inherent designed cell hierarchy in mask pattern optimization. This is especially true for non-traditional (i.e., less dependent on geometric rule) OPC/RET methods such as inverse lithography techniques (ILT) which inherently have more model-based decisions in their optimizations. New inverse methods such as model-based SRAF placement and ILT are, however, well known to have considerable benefits in finding flexible mask pattern solutions to improve process window, improve 2D CD control, and improve resolution in ultra-dense memory patterns. They also are known to reduce recipe complexity and provide native MRC compliant mask pattern solutions. Unfortunately, ILT is also known to be several times slower than traditional OPC methods due to the increased computational lithographic optimizations it performs. In this paper, we describe and present results for a methodology to greatly improve the ability of ILT to optimize advanced embedded memory designs while retaining significant hierarchy and cell design symmetry, therefore, have good turnaround time and CD uniformity. This paper will explain the enhancements which have been developed in order to overcome the traditional difficulties listed above. These enhancements are in the categories of local CD control, global chip processing options, process window benefit, turn-around time and hierarchy retention.

Proceedings Article | 31 March 2014 Paper

Experimental validation of rigorous, 3D profile models for negative-tone develop resists

Weimin Gao, Ulrich Klostermann, Itaru Kamohara, Thomas Schmoeller, Kevin Lucas, Wolfgang Demmerle, Peter De Bisschop, Julien Mailfert

Proceedings Volume 9052, 90520C (2014) https://doi.org/10.1117/12.2046522

KEYWORDS: 3D modeling, Etching, Atrial fibrillation, Scanning electron microscopy, Semiconducting wafers, Photoresist processing, Data modeling, Calibration, Optical proximity correction, Optical lithography

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Proceedings Article | 1 October 2013 Paper

Model-driven target optimization to resolve design hotspots through image quality enhancement

Sung-Woo Lee, Tom Cecil, Guangming Xiao, Mindy Lee, Jung-Hoe Choi, Seung-Hee Baek, Jin-Hyuck Jeon, Chan Ha Park, Dave Kim, Kevin Lucas

Proceedings Volume 8880, 88801U (2013) https://doi.org/10.1117/12.2026140

KEYWORDS: Optical proximity correction, Image quality, Optimization (mathematics), Nanoimprint lithography, Image enhancement, Image processing, Design for manufacturing, Resolution enhancement technologies, Neodymium, Nano opto mechanical systems

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Proceedings Article | 1 October 2013 Paper

Simulation study of CD variation caused by field edge effects and out-of-band radiation in EUVL

Weimin Gao, Ardavan Niroomand, Gian Lorusso, Robert Boone, Kevin Lucas, Wolfgang Demmerle

Proceedings Volume 8880, 88800H (2013) https://doi.org/10.1117/12.2027880

KEYWORDS: Etching, Extreme ultraviolet, Extreme ultraviolet lithography, Critical dimension metrology, Photomasks, Radiation effects, Reflectivity, Semiconducting wafers, Cadmium, Ions

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Proceedings Article | 12 April 2013 Paper

Avoiding wafer-print artifacts in spacer is dielectric (SID) patterning

Gerard Luk-Pat, Ben Painter, Alex Miloslavsky, Peter De Bisschop, Adam Beacham, Kevin Lucas

Proceedings Volume 8683, 868312 (2013) https://doi.org/10.1117/12.2011539

KEYWORDS: Metals, Photomasks, Printing, Optical lithography, Dielectrics, Etching, Lithography, Double patterning technology, Semiconducting wafers, Connectors

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Proceedings Article | 12 April 2013 Paper

Mask compensation for process flare in 193nm very low k1 lithography

Jeonkyu Lee, Taehyeong Lee, Sangjin Oh, Chunsoo Kang, Jungchan Kim, Jaeseung Choi, Chanha Park, Hyunjo Yang, Donggyu Yim, Munhoe Do, Irene Su, Hua Song, Jung-Hoe Choi, Yongfa Fan, Anthony Wang, Sung-Woo Lee, Robert Boone, Kevin Lucas

Proceedings Volume 8683, 86830F (2013) https://doi.org/10.1117/12.2012463

KEYWORDS: Optical proximity correction, Lithography, Extreme ultraviolet, Transistors, Critical dimension metrology, Model-based design, 193nm lithography, Cadmium, Photomasks, Optical lithography

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Proceedings Article | 15 March 2012 Paper

Computational lithography work flows and design rule exploration automation

S. Sethi, William Stanton, Kevin Lucas, Jay Hiserote, Duck-Hyung Hur, Rooli Choi

Proceedings Volume 8327, 83270O (2012) https://doi.org/10.1117/12.918057

KEYWORDS: Source mask optimization, Optical proximity correction, Optimization (mathematics), Computational lithography, Resolution enhancement technologies, Atrial fibrillation, Lithography, Computing systems, Manufacturing, Process engineering

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Proceedings Article | 13 March 2012 Paper

Binary modeling method to check the sub-resolution assist features (SRAFs) printability

Jianliang Li, Weimin Gao, Yongfa Fan, Jing Xue, Qiliang Yan, Kevin Lucas, Peter De Bisschop, Lawrence Melvin

Proceedings Volume 8326, 83261D (2012) https://doi.org/10.1117/12.916466

KEYWORDS: SRAF, Semiconducting wafers, Binary data, Printing, Optical proximity correction, Calibration, Photomasks, Scanning electron microscopy, Cadmium, Optical lithography

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Proceedings Article | 13 March 2012 Paper

Design compliance for spacer is dielectric (SID) patterning

Gerard Luk-Pat, Alex Miloslavsky, Ben Painter, Li Lin, Peter De Bisschop, Kevin Lucas

Proceedings Volume 8326, 83260D (2012) https://doi.org/10.1117/12.917986

KEYWORDS: Metals, Photomasks, Dielectrics, Optical lithography, Etching, Double patterning technology, Lithography, Photoresist materials, Capacitance, Tolerancing

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Proceedings Article | 7 March 2012 Open Access

Implications of triple patterning for 14nm node design and patterning

Kevin Lucas, Chris Cork, Bei Yu, Gerard Luk-Pat, Ben Painter, David Pan

Proceedings Volume 8327, 832703 (2012) https://doi.org/10.1117/12.920028

KEYWORDS: Optical lithography, Photomasks, Logic, Lithography, Double patterning technology, Etching, Immersion lithography, Cadmium sulfide, Metals, Dielectrics

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Proceedings Article | 5 April 2011 Paper

Investigation of EUV tapeout flow issues, requirements, and options for volume manufacturing

Jonathan Cobb, Sunghoon Jang, Junghoon Ser, Insung Kim, Johnny Yeap, Kevin Lucas, Munhoe Do, Young-Chang Kim

Proceedings Volume 7969, 79690S (2011) https://doi.org/10.1117/12.880230

KEYWORDS: Optical proximity correction, Extreme ultraviolet, Photomasks, Reticles, Extreme ultraviolet lithography, 193nm lithography, Lithography, Manufacturing, Optical lithography, Model-based design

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Although technical issues remain to be resolved, EUV lithography is now a serious contender for critical layer patterning of upcoming 2X node memory and 14nm Logic technologies in manufacturing. If improvements continue in defectivity, throughput and resolution, then EUV lithography appears that it will be the most extendable and the cost-effective manufacturing lithography solution for sub-78nm pitch complex patterns. EUV lithography will be able to provide a significant relaxation in lithographic K1 factor (and a corresponding simplification of process complexity) vs. existing 193nm lithography. The increased K1 factor will result in some complexity reduction for mask synthesis flow elements (including illumination source shape optimization, design pre-processing, RET, OPC and OPC verification). However, EUV does add well known additional complexities and issues to mask synthesis flows such as across-lens shadowing variation, across reticle flare variation, new proximity effects to be modeled, significant increase in pre-OPC and fracture file size, etc. In this paper, we investigate the expected EUV-specific issues and new requirements for a production tapeout mask synthesis flow. The production EUV issues and new requirements are in the categories of additional physical effects to be corrected for; additional automation or flow steps needed; and increase in file size at different parts in the flow. For example, OASIS file sizes after OPC of 250GigaBytes (GB) and files sizes after mask data prep of greater than three TeraBytes (TB) are expected to be common. These huge file sizes will place significant stress on post-processing methods, OPC verification, mask data fracture, file read-in/read-out, data transfer between sites (e.g., to the maskshop), etc. With current methods and procedures, it is clear that the hours/days needed to complete EUV mask synthesis mask data flows would significantly increase if steps are not taken to make efficiency improvements. Therefore, we also analyze different options for reducing or alleviating the EUV specific issues mentioned above and the expected cost/benefit tradeoffs associated with these options. The options include understanding the accuracy vs. run-time benefit of different rule-based and model-based approaches for several correction issues; predicting the implications and improvements expected with different flow automation options; and estimating possible productivity improvements with different flow parallelization choices and upcoming multi-core processors. Optimal combinations of options and accuracy/effort/runtime results can be seen to enable EUV lithography tapeout flows to achieve equal or better total time when compared to current 193nm optical lithography tapeout flow times.

Proceedings Article | 4 April 2011 Paper

Layout decomposition of self-aligned double patterning for 2D random logic patterning

Yongchan Ban, Alex Miloslavsky, Kevin Lucas, Soo-Han Choi, Chul-Hong Park, David Pan

Proceedings Volume 7974, 79740L (2011) https://doi.org/10.1117/12.879500

KEYWORDS: Photomasks, Metals, Lithography, Optical lithography, Logic, Etching, Double patterning technology, Manufacturing, Semiconducting wafers, Lithographic illumination

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Proceedings Article | 23 March 2010 Paper

EUV modeling accuracy and integration requirements for the 16nm node

Lena Zavyalova, Irene Su, Stephen Jang, Jonathan Cobb, Brian Ward, Jacob Sorensen, Hua Song, Weimin Gao, Kevin Lucas, Gian Lorusso, Eric Hendrickx

Proceedings Volume 7636, 763627 (2010) https://doi.org/10.1117/12.848290

KEYWORDS: Extreme ultraviolet, Optical proximity correction, Photomasks, Calibration, Optical lithography, Data modeling, Extreme ultraviolet lithography, Point spread functions, Reticles, 3D modeling

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Proceedings Article | 10 March 2010 Paper

Suppressing ringing effects from very strong off-axis illumination with novel OPC approaches for low k1 lithography

Chris Cork, Frank Amoroso, Amyn Poonawala, Stephen Jang, Kevin Lucas

Proceedings Volume 7640, 76401C (2010) https://doi.org/10.1117/12.847977

KEYWORDS: Optical proximity correction, Lithographic illumination, Lithography, Photomasks, Image segmentation, Neodymium, Scanners, Optical lithography, Manufacturing, Far-field diffraction

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Proceedings Article | 4 March 2010 Paper

Implementing and validating double patterning in 22-nm to 16-nm product design and patterning flows

Myung-Soo Noh, Beom-Seok Seo, Suk-Joo Lee, Alex Miloslavsky, Christopher Cork, Levi Barnes, Kevin Lucas

Proceedings Volume 7640, 76400S (2010) https://doi.org/10.1117/12.848194

KEYWORDS: Double patterning technology, Optical lithography, Photomasks, Logic, Product engineering, Parallel processing, Electronics, 193nm lithography, Electronic design automation, Resolution enhancement technologies

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SPIE Journal Paper | 1 July 2009

Double-patterning interactions with wafer processing, optical proximity correction, and physical design flows

Kevin Lucas, Christopher Cork, Alexander Miloslavsky, Gerard Luk-Pat, Levi Barnes, John Hapli, John Lewellen, Gregory Rollins, Vincent Wiaux, Staf Verhaegen

JM3, Vol. 8, Issue 03, 033002, (July 2009) https://doi.org/10.1117/12.10.1117/1.3158061

KEYWORDS: Semiconducting wafers, Double patterning technology, Lithography, Optical lithography, Etching, Photomasks, Optical proximity correction, Metals, Standards development, Critical dimension metrology

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Proceedings Article | 11 May 2009 Paper

Double patterning addressing imaging challenges for near- and sub-k1=0.25 node layouts

Beom-Seok Seo, Dae-Kwon Kang, Myung-Soo Noh, Sung-Ho Lee, Christopher Cork, Gerald LukPat, Alexander Miloslavsky, Xiaohai Li, Kevin Lucas, Sooryong Lee

Proceedings Volume 7379, 73791N (2009) https://doi.org/10.1117/12.824300

KEYWORDS: Double patterning technology, Optical proximity correction, Silicon, Optical lithography, Photomasks, Logic, Etching, Manufacturing, Metals, Lithography

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A variety of innovations including the reduction of actinic wavelength, an increase in lens NA, an introduction of immersion process, and an aggressive OPC/RET technique have enabled device shrinkage down to the current 45nm node. The immaturity of EUV and high index immersion, have made logic manufacturers look at other ways of leveraging existing exposure technologies as they strive to develop process technology for 32nm and below. For design rules for sub-nodes from 32nm to 22nm, the need to define critical layers with double photolithography and etch process becomes increasingly evident. Double patterning can come in a variety of forms or 'flavors'. For 32/28nm node, the patterning of 2D features is so challenging that opposing line-ends can only be defined using an additional litho and etch step to cut them. For 22nm node, even line/space gratings are below the theoretical k1=0.25 imaging limit. Therefore pitch-doubling double patterning decomposition is absolutely required. Each double patterning technology has its own set of challenges. Most of all, an existing design often cannot be shrunk blindly and then successfully decomposed, so an additional set of restrictions is required to make layouts double patterning compliant. To decompose a logic layout into two masks, polygons often need to be cut so that they can be patterned using both masks. The electric performance of this cut circuitry may be highly dependent on the quality of layout decomposition, the circuit characteristics and its sensitivity to misalignment between the two patterning steps. We used representative logic layouts of metal level and realistic models to demonstrate the issues involved and attempt to define formal rules to help enable lineend splitting and pitch-doubling double patterning decomposition. This study used a variety of shrink approaches to existing legacy layouts to evaluate double patterning compliance and a careful set-up of parameters for the pitch splitting decomposition engine. The quality of the resultant imaging was tuned using double patterning aware OPC and printability verification tools.

Proceedings Article | 18 March 2009 Paper

Requirements and results of a full-field EUV OPC flow

Stephen Jang, Lena Zavyalova, Brian Ward, Kevin Lucas

Proceedings Volume 7271, 72711A (2009) https://doi.org/10.1117/12.815255

KEYWORDS: Optical proximity correction, Extreme ultraviolet, Photomasks, 3D modeling, Extreme ultraviolet lithography, Scanners, Optical lithography, Diffraction, TCAD, Convolution

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Proceedings Article | 16 March 2009 Paper

Double-patterning-friendly OPC

Xiaohai Li, Gerry Luk-Pat, Chris Cork, Levi Barnes, Kevin Lucas

Proceedings Volume 7274, 727414 (2009) https://doi.org/10.1117/12.815175

KEYWORDS: Optical proximity correction, Photomasks, Etching, Optical lithography, Double patterning technology, Semiconducting wafers, Critical dimension metrology, Model-based design, Printing, Resolution enhancement technologies

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Proceedings Article | 16 March 2009 Paper

Resist development modeling for OPC accuracy improvement

Yongfa Fan, Lena Zavyalova, Yunqiang Zhang, Charlie Zhang, Kevin Lucas, Brad Falch, Ebo Croffie, Jianliang Li, Lawrence Melvin, Brian Ward

Proceedings Volume 7274, 727418 (2009) https://doi.org/10.1117/12.814902

KEYWORDS: Optical proximity correction, Lithography, Data modeling, Photoresist processing, Semiconducting wafers, Photoresist developing, Process modeling, Photomasks, Calibration, 3D modeling

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A precise lithographic model has always been a critical component for the technique of Optical Proximity Correction (OPC) since it was introduced a decade ago ^[1]. As semiconductor manufacturing moves to 32nm and 22nm technology nodes with 193nm wafer immersion lithography, the demand for more accurate models is unprecedented to predict complex imaging phenomena at high numerical aperture (NA) with aggressive illumination conditions necessary for these nodes. An OPC model may comprise all the physical processing components from mask e-beam writing steps to final CDSEM measurement of the feature dimensions. In order to provide a precise model, it is desired that every component involved in the processing physics be accurately modeled using minimum metrology data. In the past years, much attention has been paid to studying mask 3-D effects, mask writing limitations, laser spectrum profile, lens pupil polarization/apodization, source shape characterization, stage vibration, and so on. However, relatively fewer studies have been devoted to modeling of the development process of resist film though it is an essential processing step that cannot be neglected. Instead, threshold models are commonly used to approximate resist development behavior. While resist models capable of simulating development path are widely used in many commercial lithography simulators, the lack of this component in current OPC modeling lies in the fact that direct adoption of those development models into OPC modeling compromises its capability of full chip simulation. In this work, we have successfully incorporated a photoresist development model into production OPC modeling software without sacrificing its full chip capability. The resist film development behavior is simulated in the model to incorporate observed complex resist phenomena such as surface inhibition, developer mass transport, HMDS poisoning, development contrast, etc. The necessary parameters are calibrated using metrology data in the same way that current model calibration is done. The method is validated with a rigorous lithography process simulation tool which is based on physical models to simulate and predict effects during the resist PEB and development process. Furthermore, an experimental lithographic process was modeled using this new methodology, showing significant improvement in modeling accuracy in compassion to a traditional model. Layout correction test has shown that the new model form is equivalent to traditional model forms in terms of correction convergence and speed.

Proceedings Article | 13 March 2009 Paper

Large-scale double-patterning compliant layouts for DP engine and design rule development

Christopher Cork, Kevin Lucas, John Hapli, Herve Raffard, Levi Barnes

Proceedings Volume 7275, 72751K (2009) https://doi.org/10.1117/12.815213

KEYWORDS: Double patterning technology, Metals, Optical lithography, Optical proximity correction, Standards development, Photomasks, Neodymium, Lithium, Field emission displays, Extreme ultraviolet

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Double Patterning is seen as the prime technology to keep Moore's law on path while EUV technology is still maturing into production worthiness. As previously seen for alternating-Phase Shift Mask technology[1], layout compliance of double patterning is not trivial [2,3] and blind shrinks of anything but the most simplistic existing layouts, will not be directly suitable for double patterning. Evaluating a production worthy double patterning engine with highly non-compliant layouts would put unrealistic expectations on that engine and provide metrics with poor applicability for eventual large designs. The true production use-case would be for designs that have at least some significant double patterning compliance already enforced at the design stage. With this in mind a set of ASIC design blocks of different sizes and complexities were created that were double patterning compliant. To achieve this, a set of standard cells were generated, which individually and in isolation were double patterning compliant, for multiple layers simultaneously. This was done using the automated Standard Cell creation tool Cadabra^TM [4]. To create a full ASIC, however, additional constraints were added to make sure compliance would not be broken across the boundaries between standard cells when placed next to each other [5]. These standard cells were then used to create a variety of double patterning compliant ASICs using iCCompiler^TM to place the cells correctly. Now with a compliant layout, checks were made to see if the constraints made at the micro level really do ensure a fully compliant layout on the whole chip and if the coloring engine could cope with such large datasets. A production worthy double patterning engine is ideally distributable over multiple processors [6,7] so that fast turn-around time can be achievable on even the largest designs. We demonstrate the degree of linearity of scaling achievable with our double patterning engine. These results can be understood together with metrics such as the distribution of the sizes of networks requiring coloring resulting from these designs.

Proceedings Article | 13 March 2009 Paper

Process variation aware OPC modeling for leading edge technology nodes

Qiaolin Zhang, Ebo Croffie, Yongfa Fan, Jianliang Li, Kevin Lucas, Brad Falch, Lawerence Melvin

Proceedings Volume 7275, 72751J (2009) https://doi.org/10.1117/12.815094

KEYWORDS: Calibration, Optical proximity correction, Process modeling, Lithography, Data modeling, Finite element methods, Semiconducting wafers, Optical lithography, Performance modeling, Metals

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As the semiconductor industry moves to the 45nm node and beyond, the tolerable lithography process window significantly shrinks due to the combined use of high NA and low k1 factor. This is exacerbated by the fact that the usable depth of focus at 45nm node for critical layer is 200nm or less. Traditional Optical Proximity Correction (OPC) only computes the optimal pattern layout to optimize its lithography patterning at nominal process condition (nominal defocus and nominal exposure dose) according to an OPC model calibrated at this nominal condition, and this may put the post-OPC layout at non-negligible patterning failure risk due to the inevitable process variation (mainly defocus and dose variations). With a little sacrifice at the nominal condition, process variation aware OPC can greatly enhance the robustness of post-OPC layout patterning in the presence of defocus and dose variation. There is also an increasing demand for through process window lithography verification for post-OPC circuit layout. The corner stone for successful process variation aware OPC and lithography verification is an accurately calibrated continuous process window model which is a continuous function of defocus and dose. This calibrated model needs to be able to interpolate and extrapolate in the usable process window. Based on Synopsys' OPC modeling software package-ProGen and ProGenPlus, we developed an automated process window (PW) modeling module, which can build process variation aware process window OPC model with continuously adjustable process parameters: defocus and dose. The calibration of this continuous PW model was performed in a single calibration process using silicon measurement at nominal condition and off-focus-off-dose conditions. Through the example of several process window models for layers at 45nm technology nodes, we demonstrated that this novel continuous PW modeling approach can achieve very good performance both at nominal condition and at interpolated or extrapolated off-focus-off-dose conditions.

Proceedings Article | 4 December 2008 Paper

Optimization of RET flow using test layout

Yunqiang Zhang, Satyendra Sethi, Kevin Lucas

Proceedings Volume 7140, 71402D (2008) https://doi.org/10.1117/12.804621

KEYWORDS: Atrial fibrillation, Optical proximity correction, Resolution enhancement technologies, Lithography, Diffractive optical elements, Accuracy assessment, Lithographic illumination, Argon, Printing, Roads

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Proceedings Article | 17 October 2008 Paper

32nm design rule and process exploration flow

Yunqiang Zhang, Jonathan Cobb, Amy Yang, Ji Li, Kevin Lucas, Satyendra Sethi

Proceedings Volume 7122, 71223Z (2008) https://doi.org/10.1117/12.801593

KEYWORDS: Optical proximity correction, Atrial fibrillation, Lithography, Lithographic illumination, Manufacturing, Resolution enhancement technologies, Optical lithography, Process modeling, Semiconductors, Semiconducting wafers

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Proceedings Article | 17 October 2008 Paper

Focus blur model to enhance lithography model for optical proximity correction

Qiaolin Zhang, Hua Song, Kevin Lucas

Proceedings Volume 7122, 71223Y (2008) https://doi.org/10.1117/12.802509

KEYWORDS: Chromatic aberrations, Optical proximity correction, Calibration, Lithography, Optical lithography, Scanners, Laser scanners, 3D scanning, Semiconducting wafers, Laser development

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Proceedings Article | 17 October 2008 Paper

Printability verification for double-patterning technology

Gerard Luk-Pat, Petrisor Panaite, Kevin Lucas, Christopher Cork, Vincent Wiaux, Staf Verhaegen, Mireille Maenhoudt

Proceedings Volume 7122, 71220Q (2008) https://doi.org/10.1117/12.801545

KEYWORDS: Etching, Lithography, Printing, Double patterning technology, Optical proximity correction, Critical dimension metrology, Resolution enhancement technologies, Scanning electron microscopy, Bridges, Extreme ultraviolet

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Proceedings Article | 19 May 2008 Paper

Modeling mask pellicle effects for OPC/RET

Lena Zavyalova, Hua Song, Kevin Lucas, Qiaolin Zhang, James Shiely

Proceedings Volume 7028, 70283B (2008) https://doi.org/10.1117/12.793118

KEYWORDS: Pellicles, Optical proximity correction, Photomasks, Lithography, Polarization, Data modeling, Scanners, Apodization, Thin films, Reticles

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Proceedings Article | 19 May 2008 Paper

Rigorous vectorial modeling for polarized illumination and projection pupil in OPC

Qiaolin Zhang, Hua Song, Kevin Lucas, Brian Ward, James Shiely

Proceedings Volume 7028, 702813 (2008) https://doi.org/10.1117/12.793044

KEYWORDS: Polarization, Optical proximity correction, Scanners, Lithographic illumination, Mathematical modeling, Lithography, Light sources, Fiber optic illuminators, Semiconducting wafers, Thin films

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High NA and Ultra-High NA (NA>1.0) applications for low k₁ imaging strongly demand the adoption of polarized illumination as a resolution enhancement technology since proper illumination polarization configuration can greatly improve the image contrast hence pattern printing fidelity and the effectiveness of optical proximity correction (OPC). However, current OPC/RET modeling software can only model the light source polarization of simple types, such as TE, TM, X, Y, or sector polarization with relatively simple configuration. Realistic polarized light used in scanners is more complex than the aforementioned simple ones. As a result, simulation accuracy and quality of the OPC result will be compromised by the simplification of the light source polarization modeling in the traditional approach. With ever shrinking CD error budget in the manufacturing of IC's at advanced technology nodes, more accurate and comprehensive illumination source modeling for lithography simulations and OPC/RET is needed. On the other hand, for polarized illumination to be fully effective, ideally all the components in the optical lithography system should not alter the polarization state of light during its propagation from illuminator to wafer surface. In current OPC modeling tools, it is typically assumed that the amplitude and polarization state of the light do not change as it passes through the projection lens pupil, i.e. the polarization aberration of projection lens pupil is ignored. However, in reality, the projection lens pupil of the scanner does change the amplitude and the polarization state to some extent, and ignorance of projection pupil induced polarization state and amplitude changes will cause CD errors un-tolerable at the 45nm device generation and beyond. We developed an OPC-deployable modeling approach to model arbitrarily polarized light source and arbitrarily polarized projection lens pupil. Based on polarization state vector descriptions of a general illumination source, this modeling approach unifies optical simulations of unpolarized, partially polarized, and completely polarized illuminations. The polarization aberration imposed by the projection lens pupil is modeled via Jones matrix format, and it is applicable to arbitrary polarization aberrations imposed by any components in the lithography system that can be characterized in Jones matrix format. Numerical experiments were performed to study CD impact from illumination polarization and projection lens pupil polarization aberrations, and up to several nanometers impact on optical proximity effect (OPE) was observed, which is not negligible given the extremely stringent CD error budget at 45nm node and beyond. Based on an experimentally measured Jones matrix pupil which intrinsically provides a much better approximation to the physical scanner projection pupil, we propose a more physics-centric methodology to evaluate the optical model accuracy of OPC simulator.

Proceedings Article | 19 May 2008 Paper

Hybrid resist model to enhance continuous process window model for OPC

Qiaolin Zhang, Kevin Lucas

Proceedings Volume 7028, 70280L (2008) https://doi.org/10.1117/12.793028

KEYWORDS: Process modeling, Optical proximity correction, Calibration, Data modeling, Performance modeling, Semiconducting wafers, Finite element methods, Lithography, Metrology, Manufacturing

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Proceedings Article | 11 April 2008 Paper

Analysis of OPC optical model accuracy with detailed scanner information

Lena Zavyalova, Kevin Lucas, Qiaolin Zhang, Yongfa Fan, Satyendra Sethi, Hua Song, Jacek Tyminski

Proceedings Volume 6924, 69241D (2008) https://doi.org/10.1117/12.774116

KEYWORDS: Optical proximity correction, TCAD, Metrology, Lithography, Scanners, Systems modeling, Photomasks, Data modeling, Wafer-level optics, Semiconducting wafers

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Proceedings Article | 20 March 2008 Paper

Interactions of double patterning technology with wafer processing, OPC and design flows

Kevin Lucas, Chris Cork, Alex Miloslavsky, Gerry Luk-Pat, Levi Barnes, John Hapli, John Lewellen, Greg Rollins, Vincent Wiaux, Staf Verhaegen

Proceedings Volume 6924, 692403 (2008) https://doi.org/10.1117/12.778267

KEYWORDS: Semiconducting wafers, Optical lithography, Photomasks, Double patterning technology, Lithography, Etching, Metals, Optical proximity correction, 193nm lithography, Standards development

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Proceedings Article | 19 March 2008 Paper

Continuous process window modeling for process variation aware OPC and lithography verification

Qiaolin Zhang, Qiliang Yan, Yunqiang Zhang, Kevin Lucas

Proceedings Volume 6925, 69251A (2008) https://doi.org/10.1117/12.772737

KEYWORDS: Calibration, Process modeling, Optical proximity correction, Data modeling, Finite element methods, Lithography, Semiconducting wafers, Critical dimension metrology, Optical lithography, Statistical modeling

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As the semiconductor industry moves to the 45nm node and beyond, the tolerable lithography process window significantly shrinks due to the combined use of high NA and low k₁ factor. This is exacerbated by the fact that the usable depth of focus at 45nm node for critical layer is 200nm or less. Traditional Optical Proximity Correction (OPC) only computes the optimal pattern layout to optimize its patterning at nominal process condition (nominal defocus and nominal exposure dose) according to an OPC model calibrated at this nominal condition, and this may put the post-OPC layout at nonnegligible patterning risk due to the inevitable process variation (defocus and dose variations). With a little sacrifice at the nominal condition, process variation aware OPC can greatly enhance the robustness of post-OPC layout patterning in the presence of defocus and dose variation. There is also an increasing demand for through process window lithography verification for post-OPC circuit layout. The corner stone for successful process variation aware OPC and lithography verification is an accurately calibrated continuous process window model which is a continuous function of defocus and dose. This calibrated model needs to be able to interpolate and extrapolate in the usable process window. Based on Synopsys' OPC modeling software package ProGen, we developed and implemented a novel methodology for continuous process window (PW) model, which has two continuous adjustable process parameters: defocus and dose. The calibration of this continuous PW model was performed in a single calibration process using silicon measurement at nominal condition and off-focus-off-dose conditions which are sparsely sampled within the measured entire focus exposure matrix (FEM). The silicon data at the off-focus-off-dose conditions not used for model calibration was utilized to validate the accuracy and stability of PW model during model interpolation and extrapolation. We demonstrated this novel continuous PW modeling approach can achieve very good performance both at nominal condition and at interpolated or extrapolated off-focus-off-dose conditions.

Proceedings Article | 19 March 2008 Paper

Decomposition difficulty analysis for double patterning and the impact on photomask manufacturability

Yuichi Inazuki, Nobuhito Toyama, Takaharu Nagai, Takanori Sutou, Yasutaka Morikawa, Hiroshi Mohri, Naoya Hayashi, Martin Drapeau, Kevin Lucas, Chris Cork

Proceedings Volume 6925, 69251O (2008) https://doi.org/10.1117/12.773291

KEYWORDS: Inspection, Photomasks, Double patterning technology, Optical proximity correction, Lithography, Printing, Lithographic illumination, Binary data, Critical dimension metrology, Logic

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Proceedings Article | 12 March 2008 Paper

Checking design conformance and optimizing manufacturability using automated double patterning decomposition

Chris Cork, Brian Ward, Levi Barnes, Ben Painter, Kevin Lucas, Gerry Luk-Pat, Vincent Wiaux, Staf Verhaegen, Mireille Maenhoudt

Proceedings Volume 6925, 69251Q (2008) https://doi.org/10.1117/12.774647

KEYWORDS: Double patterning technology, Manufacturing, Optical lithography, Photomasks, Logic, Optical proximity correction, Ultraviolet radiation, Lithography, Semiconducting wafers, Phase shifts

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Delays in equipment availability for both Extreme UV and High index immersion have led to a growing interest in double patterning as a suitable solution for the 22nm logic node. Double patterning involves decomposing a layout into two masking layers that are printed and etched separately so as to provide the intrinsic manufacturability of a previous lithography node with the pitch reduction of a more aggressive node. Most 2D designs cannot be blindly shrunk to run automatically on a double patterning process and so a set of guidelines for how to layout for this type of flow is needed by designers. While certain classes of layout can be clearly identified and avoided based on short range interactions, compliance issues can also extend over large areas of the design and are hard to recognize. This means certain design practices should be implemented to provide suitable breaks or performed with layout tools that are double patterning compliance aware. The most striking set of compliance errors result in layout on one of the masks that is at the minimum design space rather than the relaxed space intended. Another equally important class of compliance errors is that related to marginal printability, be it poor wafer overlap and/or poor process window (depth of focus, dose latitude, MEEF, overlay). When decomposing a layout the tool is often presented with multiple options for where to cut the design thereby defining an area of overlap between the different printed layers. While these overlap areas can have markedly different topologies (for instance the overlap may occur on a straight edge or at a right angled corner), quantifying the quality of a given overlap ensures that more robust decomposition solutions can be chosen over less robust solutions. Layouts which cannot be decomposed or which can only be decomposed with poor manufacturability need to be highlighted to the designer, ideally with indications on how best to resolve this issue. This paper uses an internally developed automated double pattern decomposition tool to investigate design compliance and describes a number of classes of non-conforming layout. Tool results then provide help to the designer to achieve robust design compliant layout.

Proceedings Article | 7 March 2008 Paper

Modeling of focus blur in the context of optical proximity correction

Qiaolin Zhang, Hua Song, Kevin Lucas, James Shiely

Proceedings Volume 6924, 69243K (2008) https://doi.org/10.1117/12.773091

KEYWORDS: Chromatic aberrations, Optical proximity correction, Calibration, Lithography, Optical lithography, Scanners, Laser scanners, 3D scanning, Semiconducting wafers, Laser development

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Proceedings Article | 4 March 2008 Paper

Application of layout DOE in RET flow

Yunqiang Zhang, Paul van Adrichem, Ji Li, Amy Yang, Kevin Lucas

Proceedings Volume 6925, 69251H (2008) https://doi.org/10.1117/12.773059

KEYWORDS: Optical proximity correction, Diffractive optical elements, Atrial fibrillation, Critical dimension metrology, Resolution enhancement technologies, Lithography, Error analysis, Head, Bridges, Process modeling

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At low k1 lithography and strong off-axis illumination, it is very hard to achieve edge-placement tolerances and 2-D image fidelity requirements for some layout configurations. Quite often these layouts are within simple design rules constraint for a given technology node. Evidently it is important to have these layouts included during early RET flow development. Simple shrinkage from previous technology node is quite common, although often not enough. For logic designs, it is hard to control design styles. Moreover for engineers in fabless design groups, it is difficult to assess the manufacturability of their layouts because of the lack of understanding of the litho process. Assist features (AF) are frequently placed according to pre-determined rules to improve lithography process window. These rules are usually derived from lithographic models. Direct validation of AF rules is required at development phase.To ensure good printability through process window, process aware optical proximity correction (OPC) recipes were developed. Generally rules based correction is performed before model based correction. Furthermore, there are also lots of other options and parameters in OPC recipes for an advanced technology, thus making it difficult to holistically optimize performance of recipe bearing all these variables in mind. In this paper we demonstrate the application of layout DOE in RET flow development. Layout pattern libraries are generated using the Synopsys Test Pattern Generator (STPG), which is embedded in a layout tool (ICWB). Assessment gauges are generated together with patterns for quick correction accuracy assessment. OPC verification through full process is also deployed. Several groups of test pattern libraries for different applications are developed, ranging from simple 1D pattern for process capability study and settings of process aware parameters to a full set of patterns for the assessment of rules based correction, line end and corner interaction, active and poly interaction, and critical patterns for contact coverage, etc. Restrictive design rules (RDR) are commonly deployed to eliminate problematic layouts. We demonstrate RDR evaluation and validation using our layout design of experiments (DOE) approach. This technique of layout DOE also offers a simple and yet effective way to verify AF placement rules. For a given nominal layout features all possible assist features are generated within the mask rules constraint using STPG. Then we run OPC correction and assess main feature critical dimension (CD) at best and worst process condition in ICWB. Best assist feature placement rules are derived based on minimum CD difference. The rules derived from this approach are not the same as those derived from the commonly used method of least intensity variation.

Proceedings Article | 16 November 2007 Paper

Polarization aberration modeling via Jones matrix in the context of OPC

Qiaolin Zhang, Hua Song, Kevin Lucas

Proceedings Volume 6730, 67301Q (2007) https://doi.org/10.1117/12.746710

KEYWORDS: Polarization, Optical proximity correction, Scanners, Mathematical modeling, Lithography, Fiber optic illuminators, Thin films, Geometrical optics, Imaging systems, Apodization

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The increasingly stringent demand for shrinkage of IC device dimensions has been pushing the development of new resolution enhancement technologies in micro-lithography. High NA and Ultra-High NA (NA>1.0) applications for low k₁ imaging strongly demand the adoption of polarized illumination as a resolution enhancement technology since proper illumination polarization configuration can greatly improve the image contrast hence pattern printing fidelity. For polarized illumination to be fully effective, ideally all the components in the optical system should not alter the polarization state during propagation from illuminator to wafer surface. In current OPC modeling tools, it is typically assumed that the amplitude and polarization state of the electric field do not change as it passes through the projection lens pupil. However, in reality, the projection lens pupil of the scanner does change the amplitude and the polarization state to some extent, and ignorance of projection pupil induced polarization state and amplitude changes may cause CD errors which are un-tolerable at the 45nm device generation and beyond. We developed an OPC-deployable modeling approach to model polarization aberration imposed by the projection lens pupil via Jones matrix format. This polarization aberration modeling capability has been integrated into the Synopsys OPC modeling tool, ProGen, and its accuracy and efficiency have been validated by comparing with an industry standard lithography simulator SolidE. Our OPC simulations show that the impact of projection lens pupil polarization aberrations on optical proximity effect (OPE) could be as large as several nanometers, which is not negligible given the extremely stringent CD error budget at 45nm node and beyond. This modeling approach is applicable to arbitrary polarization aberrations imposed by any components in the lithography system that can be characterized in Jones matrix format. Based on an experimentally measured Jones matrix pupil which intrinsically provides a much better approximation to the physical scanner pupil, we propose a more physics-centric methodology to evaluate the optical model accuracy of OPC simulator.

Proceedings Article | 1 November 2007 Paper

Modeling scanner signatures in the context of OPC

Qiaolin Zhang, Jacek Tyminski, Kevin Lucas

Proceedings Volume 6730, 673056 (2007) https://doi.org/10.1117/12.746724

KEYWORDS: Scanners, Optical proximity correction, Fiber optic illuminators, Lithography, Apodization, Lithographic illumination, Process modeling, Optical imaging, Data modeling, Computer simulations

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SPIE Journal Paper | 1 July 2007

Novel apodization and pellicle optical models for accurate optical proximity correction modeling at 45 and 32 nm

Qiaolin Zhang, Kevin Lucas, Paul Van Adrichem, Jacek Tyminski, Joseph Gordon

JM3, Vol. 6, Issue 03, 031003, (July 2007) https://doi.org/10.1117/12.10.1117/1.2783418

KEYWORDS: Apodization, Optical proximity correction, Pellicles, Data modeling, Lithography, Signal attenuation, Critical dimension metrology, Gaussian filters, Calibration, Optical filters

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Proceedings Article | 15 May 2007 Paper

Efficient post-OPC lithography hotspot detection using a novel OPC correction and verification flow

Qiaolin Zhang, Paul VanAdrichem, Kevin Lucas

Proceedings Volume 6607, 66072X (2007) https://doi.org/10.1117/12.729016

KEYWORDS: Optical proximity correction, Process modeling, Statistical modeling, Lithography, Critical dimension metrology, Performance modeling, Error analysis, Model-based design, Scanners, Photomasks

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Proceedings Article | 15 May 2007 Paper

Functionality and performance improvements with field-based OPC

Ben Painter, Kunal Taravade, Levi Barnes, Robert Lugg, Jeff Mayhew, Glenn Newell, Kevin Lucas

Proceedings Volume 6607, 66072T (2007) https://doi.org/10.1117/12.729012

KEYWORDS: Optical proximity correction, Model-based design, Resolution enhancement technologies, Atrial fibrillation, Image segmentation, Semiconducting wafers, Lithography, Tolerancing, Performance modeling, Computer simulations

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Proceedings Article | 15 May 2007 Paper

The impact of scanner model vectorization on optical proximity correction

Jacek Tyminski, Tashiharu Nakashima, Qiaolin Zhang, Tomoyuki Matsuyama, Kevin Lucas

Proceedings Volume 6607, 66071L (2007) https://doi.org/10.1117/12.728968

KEYWORDS: Optical proximity correction, Scanners, Fiber optic illuminators, Error analysis, Critical dimension metrology, Photomasks, Polarization, Electronic design automation, Optical lithography, Image acquisition

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Low pass filtering taking place in the projection tools used by IC industry leads to a range of optical proximity effects resulting in undesired IC characteristics. To correct these predicable OPEs, EDA industry developed various, model-based correction methodologies. Of course, the success of this mission is strongly dependent on how complete the imaging models are. To represent the image formation and to capture the OPEs, the EDA community adopted various models based on simplified representations of the projection tools. Resulting optical proximity correction models are capable of correcting OPEs driven by the fundamental imaging conditions such as wavelength, illuminator layout, reticle technology, and lens numerical aperture, to name a few. It is well known in the photolithography community that OPEs are dependent on the scanner characteristics. Therefore, to reach the level of accuracy required by the leading edge IC designs, photolithography simulation has to include systematic scanner fingerprint data. These tool fingerprints capture excursions of the imaging tools from the ideal imaging setup conditions. They quantify the performance of key projection tool components such as illuminator and lens signatures. To address the imaging accuracy requirements, the scanner engineering and the EDA communities developed OPC models capable of correcting for imaging tools engineering attributes captured by the imaging tools fingerprints. Deployment of immersion imaging systems has presented the photolithography community with new opportunities and challenges. These advanced scanners, designed to image in deep sub-wavelength regime, incorporate features invoking the optical phenomena previously unexplored in commercial scanners. Most notably, the state of the art scanners incorporate illuminators with high degree of polarization control and projection lenses with hyper-NAs. The image formation in these advanced projectors exploits a wide range of vectorial interactions originating at the illuminator, on the pattern mask, in the projection lens and at the wafer. The presence of these, previously subdued phenomena requires that the imaging simulation methodologies be refined, increasing the complexity of the OPE models and optical proximity correction methodologies.

Proceedings Article | 4 April 2007 Paper

Comparing traditional OPC to field-based OPC for 45-nm node production

Rick Farnbach, Josh Tuttle, Matt St. John, Randy Brown, Dave Gerold, Kevin Lucas, Robert Lugg, James Shiely, Mike Rieger

Proceedings Volume 6520, 65204F (2007) https://doi.org/10.1117/12.721593

KEYWORDS: Optical proximity correction, Computer simulations, Image segmentation, Semiconducting wafers, Control systems, Photomasks, Mathematical modeling, Manufacturing, Convolution, Image analysis

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Proceedings Article | 27 March 2007 Paper

Patterning control budgets for the 32-nm generation incorporating lithography, design, and RET variations

Kevin Lucas, Chris Cork, Jonathan Cobb, Brian Ward, Martin Drapeau, Charlie Zhang, John Allgair, Mike Kling, Mike Rieger

Proceedings Volume 6520, 65200N (2007) https://doi.org/10.1117/12.715166

KEYWORDS: Optical lithography, Optical proximity correction, Error analysis, Resolution enhancement technologies, SRAF, Lithography, OLE for process control, Photomasks, Manufacturing, Metrology

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An important outcome of the 90nm and 65nm device generations was the realization that new methods for predicting and controlling patterning were required to ensure successful transfer for all design rule compliant features through the required process window. This realization led to a strong increase in the use of CD-based and process window aware post-optical proximity correction (OPC) verification in production mask tapeouts. Accurate post-OPC verification is a necessity but many patterning issues could have been detected and removed earlier in the product development lifecycle. Of course, the 45nm and 32nm device generations are only expected to further strain the ability of device manufacturers to predict process control requirements, robust patterning design rules and first-time right reticle enhancement technology (RET) recipes. Therefore, improvements to the traditional process, OPC and design rule prediction/evaluation steps are needed. In this paper we propose a patterning and CD control prediction methodology which incorporates not only the traditional dose, defocus and mask variation parameters but also implements RET parameter variations such as layout edge discretization, model inaccuracy, metrology error and assist feature placement. This methodology allows a more accurate prediction of process control requirements, worst case CD control layout geometries and RET subsystem accuracy/control requirements. Lithography engineers have long operated with specific (if not always fully understood) dose and focus control success requirements. To efficiently determine real worst design situations, we utilize a new methodology for quickly verifying the RET-ability of a lithography process + design rule set + OPC correction recipe based on coupling iterative layout generation with OPC testing. Our aim in this paper is to provide additional engineering rigor to the traditional experience-based OPC success requirements by looking at the total Litho + RET + metrology patterning problem and analyzing the individual component control needs.

Proceedings Article | 26 March 2007 Paper

A discussion of the regression of physical parameters for photolithographic process models

Lawrence Melvin, Kevin Lucas

Proceedings Volume 6520, 65201V (2007) https://doi.org/10.1117/12.712646

KEYWORDS: Process modeling, Data modeling, Scanners, Mathematical modeling, Critical dimension metrology, Optical proximity correction, Manufacturing, Optics manufacturing, Fiber optic illuminators, Instrument modeling

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All models currently used for Optical Proximity Correction and related Resolution Enhancement techniques are comprised of an analytical description of the modeled system with coefficients determined by data collected from the physical process. The analytical model is normally based on the Hopkin's approximation of the system because this approximation allows the reticle to be a variable in the exposure system. The analytical component of the model contains terms such as numerical aperture, partial coherence, and wavelength, all of which are physical parameters that can be directly read from the equipment used to generate the empirical process data. Therefore, these physical parameters can be directly used in the process model and do not need to be modified. One case example of a physical parameter is the illuminator shape. In an annular exposure system, the center of the exposure system is blocked to allow illumination by high order illumination components. The annular shape can be achieved in different manners. The scanner manufacturer can use a shape cut in a metal form to achieve an annular illumination condition or the scanner manufacturer can use a lens system to achieve the same illumination condition. Both of these systems have the same inner and outer diameters, resulting in the same annulus and therefore the same illumination technique. However, experimental data show that for the exact same setting values, the annular illumination shape is detectably different. This is a first order system difference that is the result of different implementation methods. Further differences can be found due to scanner to scanner variations in either lens shape or aperture shape. These differences create a need for physical parameters to be regressed during fitting of empirical data to the analytical model. This paper will discuss the need to regress what initially appear to be constant physical parameters during the model fitting process. The study will use equipment variability information to demonstrate the range of physical constant impact upon the accuracy of a process model.

Proceedings Article | 21 March 2007 Paper

Scanner-characteristics-aware OPC modeling and correction

Jacek Tyminski, Qiaolin Zhang, Kevin Lucas, Laurent Depre, Paul VanAdrichem

Proceedings Volume 6521, 65210Z (2007) https://doi.org/10.1117/12.711624

KEYWORDS: Optical proximity correction, Scanners, Critical dimension metrology, Fiber optic illuminators, Error analysis, Performance modeling, Reticles, Coastal modeling, Model-based design, Optical lithography

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Proceedings Article | 20 October 2006 Paper

Sensitivity of a variable threshold model toward process and modeling parameters

Mazen Saied, Franck Foussadier, Yorick Trouiller, Jérôme Belledent, Kevin Lucas, Isabelle Schanen, Amandine Borjon, Christophe Couderc, Christian Gardin, Laurent LeCam, Yves Rody, Frank Sundermann, Jean-Christophe Urbani, Emek Yesilada

Proceedings Volume 6349, 634919 (2006) https://doi.org/10.1117/12.686666

KEYWORDS: Calibration, Process modeling, Data modeling, Optical proximity correction, Mathematical modeling, Photoresist processing, Model-based design, Photomasks, Image processing, Image quality

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Proceedings Article | 20 October 2006 Paper

Optical issues of thin organic pellicles in 45-nm and 32-nm immersion lithography

Kevin Lucas, Joseph Gordon, Will Conley, Mazen Saied, Scott Warrick, Mike Pochkowski, Mark Smith, Craig West, Franklin Kalk, Jan Pieter Kuijten

Proceedings Volume 6349, 63490K (2006) https://doi.org/10.1117/12.686741

KEYWORDS: Pellicles, Optical proximity correction, Apodization, Polarization, Critical dimension metrology, Lithography, Photomasks, Semiconducting wafers, Reticles, Spatial frequencies

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Proceedings Article | 21 March 2006 Paper

High transmission mask technology for 45nm node imaging

Will Conley, Nicoló Morgana, Bryan Kasprowicz, Mike Cangemi, Matt Lassiter, Lloyd Litt, Marc Cangemi, Rand Cottle, Wei Wu, Jonathan Cobb, Young-Mog Ham, Kevin Lucas, Bernie Roman, Chris Progler

Proceedings Volume 6154, 615411 (2006) https://doi.org/10.1117/12.659353

KEYWORDS: Photomasks, Polarization, Etching, Plasma etching, Manufacturing, Plasma, Semiconducting wafers, Chromium, Lithography, Chlorine

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Proceedings Article | 21 March 2006 Paper

Process window OPC verification: dry versus immersion lithography for the 65nm node

Amandine Borjon, Jerome Belledent, Yorick Trouiller, Kevin Lucas, Christophe Couderc, Frank Sundermann, Jean-Christophe Urbani, Yves Rody, Christian Gardin, Frank Foussadier, Patrick Schiavone

Proceedings Volume 6154, 61544D (2006) https://doi.org/10.1117/12.657056

KEYWORDS: Immersion lithography, Lithography, Calibration, Optical proximity correction, Printing, Optical transfer functions, Data modeling, Process modeling, Convolution, Optical lithography

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Proceedings Article | 15 March 2006 Paper

Immersion lithography robustness for the C065 node

Scott Warrick, Rob Morton, Andrea Mauri, Jean-Damien Chapon, Jerome Belledent, Will Conley, Alex Barr, Kevin Lucas, Cedric Monget, Valerie Plantier, David Cruau, Juan-Manuel Gomez, Emmanuel Sicurani, Jan-Willem Gemmink

Proceedings Volume 6154, 615407 (2006) https://doi.org/10.1117/12.657158

KEYWORDS: Optical proximity correction, Immersion lithography, Semiconducting wafers, Scanners, Etching, Line width roughness, Manufacturing, Optical lithography, Lithography, Metals

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Semiconductor manufacturers are in the midst of the next technology node C045 (65nm half-pitch) development. The difference this time is that the heavy lifting is being done while swimming. Generally, for the C065 node (hp90), critical layers will be processed using 193-nm scanners with numerical apertures up to 0.85. It is also clear that the capabilities and potential benefits of immersion lithography (at this wavelength and NA) should to be examined, in addition to the development of immersion lithography for the C045 and C032 technology generations. The potential benefits of immersion lithography; increased DOF in the near term and hyper-NA imaging in the next phase, have been widely reported. A strategy of replacing conventional "dry" lithographic process steps with immersion lithographic process steps would allow the benefits of immersion to be realized much earlier. To fully realize this advantage a direct comparison of immersion lithography's benefits and therefore speed learning is needed. However, such an insertion should be "transparent": i.e. the "immersion process" should run with the same reticles (OPC) and resists, as the conventional process. In an effort to gain this knowledge about the immersion processes, we have chosen a path of optimizing and ramping-up the lithographic process for the C065 technology node. In this paper, we report on the compatibility of inserting immersion lithography processes into an established C065 process running in a pilot manufacturing line. We will present an initial assessment of some critical parameters for the implementation of immersion lithography. This assessment includes: OPC compatibility, imaging, process integration, and defectivity all compared to the dry process of record. Finally, conclusions will be made as to the overall readiness of immersion to support C065 node processing in direct transfer from dry and its extendibility to C045. In this work, the C045 technology node (hp65) is the main target vehicle. However, a successful introduction of immersion technology may allow a strategy change complementary with the previous (C065) technology node (i.e. run C065 immersion in production and benefit from larger process windows).

Proceedings Article | 15 March 2006 Paper

High transmission mask technology for 45nm node imaging

Will Conley, Nicoló Morgana, Bryan Kasprowicz, Mike Cangemi, Matt Lassiter, Lloyd Litt, Marc Cangemi, Rand Cottle, Wei Wu, Jonathan Cobb, Young-Mog Ham, Kevin Lucas, Bernie Roman, Chris Progler

Proceedings Volume 6154, 61541D (2006) https://doi.org/10.1117/12.659390

KEYWORDS: Photomasks, Polarization, Etching, Plasma etching, Manufacturing, Plasma, Semiconducting wafers, Chromium, Lithography, Chlorine

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Proceedings Article | 14 March 2006 Paper

Reticle enhancement verification for the 65nm and 45nm nodes

Kevin Lucas, Kyle Patterson, Robert Boone, Corinne Miramond, Amandine Borjon, Jerome Belledent, Olivier Toublan, Jorge Entradas, Yorick Trouiller

Proceedings Volume 6156, 61560R (2006) https://doi.org/10.1117/12.658823

KEYWORDS: Resolution enhancement technologies, Optical proximity correction, Process modeling, Error analysis, Image processing, Semiconducting wafers, Reticles, Optical lithography, Photomasks, Model-based design

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Proceedings Article | 5 November 2005 Paper

Through-process window resist modelling strategies for the 65 nm node

Amandine Borjon, Jerôme Belledent, Yorick Trouiller, Kyle Patterson, Kevin Lucas, Christophe Couderc, Frank Sundermann, Jean-Christophe Urbani, Stanislas Baron, Yves Rody, Christian Gardin, Franck Foussadier, Patrick Schiavone

Proceedings Volume 5992, 599219 (2005) https://doi.org/10.1117/12.632096

KEYWORDS: Data modeling, Calibration, Statistical modeling, Printing, Critical dimension metrology, Electroluminescence, Convolution, Modeling, Mathematical modeling, Computer simulations

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Proceedings Article | 5 November 2005 Paper

Evaluation of transparent etch stop layer phase shift mask patterning and comparison with the single trench undercut approach

Y. Rody, P. Martin, C. Couderc, P. Sixt, C. Gardin, K. Lucas, K. Patterson, C. Miramond-Collet, J. Belledent, R. Boone, A. Borjon, Y. Trouiller

Proceedings Volume 5992, 59920R (2005) https://doi.org/10.1117/12.632561

KEYWORDS: Etching, Optical lithography, Photomasks, Quartz, Phase shifts, Printing, Electroluminescence, Manufacturing, Chromium, Optical proximity correction

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Despite the complexity of AAPSM patterning using the complementary PSM approach with respect to OPC correction, mask making, fab logistics etc, the technique still remains a valuable solution for special products where a low CD dispersion printing process is required. For current and next generation process technologies (90-65nm ground rules), the most common alternating mask solution of single trench etch with or without undercut becomes more difficult to manufacture. Especially challenging is the aspect ratio control of quartz etched trenches as a function of density in order to assure the correct phase angle and sidewall for dense and isolated structures over all phase shifted geometries. In order to solve this problem, a modified mask architecture is proposed, called the Transparent Etch Stop Layer (TESL) phase shift mask. In TESL, a transparent (etch stop) layer is deposited on the quartz substrate, followed by the deposition of a quartz layer having a thickness corresponding to the required phase angle for the used wavelength. On top a Chromium layer will be deposited. The patterning of this mask will be quite similar to the single trench variant. The difference is, that now an overetch can be applied for the phase definition resulting from the high etch selectivity of quartz to the etch stop material. The result of this approach should be that we can better control the phase depth and sidewall angle for dense and isolated structures. In this paper we will discuss the results of the printing tests performed using TESL masks especially with respect to litho process window, and we will compare these with the single trench undercut approach. Simulation results are presented with respect to shifter sidewall profile and TESL thickness in order to optimize image imbalance. Throughout the study we will correlate simulations and measurements to the after-MBOPC CD values for the shifter structures. These results will allow us to determine if the TESL AAPSM approach can be a more effective alternative to the single trench undercut approach.

Proceedings Article | 28 June 2005 Paper

Correction of long-range effects applied to the 65-nm node

Jerome Belledent, James Word, Yorick Trouiller, Christophe Couderc, Corinne Miramond, Olivier Toublan, Jean-Damien Chapon, Stanislas Baron, Amandine Borjon, Franck Foussadier, Christian Gardin, Kevin Lucas, Kyle Patterson, Yves Rody, Frank Sundermann, Jean-Christophe Urbani

Proceedings Volume 5853, (2005) https://doi.org/10.1117/12.617433

KEYWORDS: Critical dimension metrology, Etching, Photomasks, Convolution, Optical proximity correction, Electrons, Point spread functions, Optical lithography, Scattering, Light scattering

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Proceedings Article | 28 June 2005 Paper

Dual layer patterning failures in complex RET processes using ORC tools and pre- or post-optical proximity correction strategy

Christophe Couderc, Jerome Belledent, Amandine Borjon, Yorick Trouiller, Frank Sundermann, Kevin Lucas, Jean-Christophe Urbani, Franck Foussadier, Yves Rody, Kyle Patterson, Stanislas Baron

Proceedings Volume 5853, (2005) https://doi.org/10.1117/12.617412

KEYWORDS: Optical proximity correction, Resolution enhancement technologies, Multilayers, Optical lithography, Photomasks, Optics manufacturing, Semiconducting wafers, Metals, Manufacturing, Lithography

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Proceedings Article | 12 May 2005 Paper

High accuracy 65nm OPC verification: full process window model vs. critical failure ORC

Amandine Borjon, Jerome Belledent, Shumay Shang, Olivier Toublan, Corinne Miramond, Kyle Patterson, Kevin Lucas, Christophe Couderc, Yves Rody, Frank Sundermann, Jean-Christophe Urbani, Stanislas Baron, Yorick Trouiller, Patrick Schiavone

Proceedings Volume 5754, (2005) https://doi.org/10.1117/12.600471

KEYWORDS: Data modeling, Optical proximity correction, Calibration, Printing, Optical lithography, Scanning electron microscopy, Process modeling, 3D modeling, Lithography, Photomasks

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It is becoming more and more difficult to ensure robust patterning after OPC due to the continuous reduction of layout dimensions and diminishing process windows associated with each successive lithographic generation. Lithographers must guarantee high imaging fidelity throughout the entire range of normal process variations. The techniques of Mask Rule Checking (MRC) and Optical Rule Checking (ORC) have become mandatory tools for ensuring that OPC delivers robust patterning. However the first method relies on geometrical checks and the second one is based on a model built at best process conditions. Thus those techniques do not have the ability to address all potential printing errors throughout the process window (PW). To address this issue, a technique known as Critical Failure ORC (CFORC) was introduced that uses optical parameters from aerial image simulations. In CFORC, a numerical model is used to correlate these optical parameters with experimental data taken throughout the process window to predict printing errors. This method has proven its efficiency for detecting potential printing issues through the entire process window [1]. However this analytical method is based on optical parameters extracted via an optical model built at single process conditions. It is reasonable to expect that a verification method involving optical models built from several points throughout PW would provide more accurate predictions of printing errors for complex features. To verify this approach, compact optical models similar to those used for standard OPC were built and calibrated with experimental data measured at the PW limits. This model is then applied to various test patterns to predict potential printing errors. In this paper, a comparison between these two approaches is presented for the poly layer at 65 nm node patterning. Examples of specific failure predictions obtained separately with the two techniques are compared with experimental results. The details of implementing these two techniques on full product layouts are also included in this study.

Proceedings Article | 12 May 2005 Paper

The impact of illumination on feature fidelity for CPL mask technology

Jan Kuijten, Arjan Verhappen, Will Conley, Stephan van de Goor, Lloyd Litt, Wei Wu, Kevin Lucas, Bernie Roman, Bryan Kasprowicz, Chris Progler, Robert Socha, Doug van den Broeke, Kurt Wampler, Tom Laidig, Stephen Hsu

Proceedings Volume 5754, (2005) https://doi.org/10.1117/12.605481

KEYWORDS: Chromium, Photomasks, Nanoimprint lithography, Phase shifts, Resolution enhancement technologies, Optical proximity correction, Mask making, Semiconductors, Photoresist materials, Manufacturing

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Proceedings Article | 12 May 2005 Paper

Strategies of optical proximity correction dedicated to chromeless phase lithography for 65 and 45 nm node

Emilien Robert, Philippe Thony, Kevin Lucas, Daniel Henry, Bryan Kasprowicz, Sergei Postnikov, Will Conley, Wei Wu, Lloyd Litt

Proceedings Volume 5754, (2005) https://doi.org/10.1117/12.601743

KEYWORDS: Chromium, Photomasks, Scattering, Semiconducting wafers, Optical proximity correction, Lithography, Phase shifts, Scanners, Diffraction, Etching

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Proceedings Article | 12 May 2005 Paper

High transmission mask technology for 45nm node imaging

Will Conley, Mike Cangemi, Bryan Kasprowicz, Matt Lassiter, Lloyd Litt, Marc Cangemi, Rand Cottle, Mark Smith, Wei Wu, Jonathan Cobb, Rusty Carter, Young-mog Ham, Kevin Lucas, Bernie Roman, Chris Progler

Proceedings Volume 5754, (2005) https://doi.org/10.1117/12.601584

KEYWORDS: Photomasks, Image processing, Manufacturing, Image transmission, Lithography, Photoresist materials, Nanoimprint lithography, Image resolution, Semiconductors, 193nm lithography

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Proceedings Article | 5 May 2005 Paper

Investigation of model-based physical design restrictions

Kevin Lucas, Stanislas Baron, Jerome Belledent, Robert Boone, Amandine Borjon, Christophe Couderc, Kyle Patterson, Lionel Riviere-Cazaux, Yves Rody, Frank Sundermann, Olivier Toublan, Yorick Trouiller, Jean-Christophe Urbani, Karl Wimmer

Proceedings Volume 5756, (2005) https://doi.org/10.1117/12.601105

KEYWORDS: Model-based design, Optical proximity correction, Optical lithography, Data modeling, Lithography, Systems modeling, Semiconductors, Resolution enhancement technologies, Reticles, Semiconducting wafers

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Proceedings Article | 5 May 2005 Paper

Improving model-based OPC performance for the 65-nm node through calibration set optimization

Kyle Patterson, Yorick Trouiller, Kevin Lucas, Jerome Belledent, Amandine Borjon, Yves Rody, Christophe Couderc, Frank Sundermann, Jean-Christophe Urbani, Stanislas Baron

Proceedings Volume 5756, (2005) https://doi.org/10.1117/12.601166

KEYWORDS: Calibration, Data modeling, Optical proximity correction, Statistical modeling, Performance modeling, Model-based design, Photoresist materials, Printing, Coastal modeling, Optimization (mathematics)

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Proceedings Article | 5 May 2005 Paper

65nm OPC and design optimization by using simple electrical transistor simulation

Yorick Trouiller, Thierry Devoivre, Jerome Belledent, Franck Foussadier, Amandine Borjon, Kyle Patterson, Kevin Lucas, Christophe Couderc, Frank Sundermann, Jean-Christophe Urbani, Stanislas Baron, Yves Rody, Jean-Damien Chapon, Franck Arnaud, Jorge Entradas

Proceedings Volume 5756, (2005) https://doi.org/10.1117/12.600887

KEYWORDS: Transistors, Ions, Optical proximity correction, Lithography, Optical lithography, Lithium, Logic, Photomasks, Lithographic illumination, Manufacturing

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Proceedings Article | 6 December 2004 Paper

Closing the defect printability loop: optimizing defect specifications for an established lithographic process

Kyle Patterson, Clare Wakefield, Pierre Sixt, Frank Sundermann, Yorick Trouiller, Jerome Belledent, Christophe Couderc, Yves Rody, Kevin Lucas

Proceedings Volume 5567, (2004) https://doi.org/10.1117/12.569257

KEYWORDS: Semiconducting wafers, Metrology, Reticles, Lithography, Feature extraction, Optical proximity correction, Photomasks, Photoresist processing, Calibration, Array processing

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Proceedings Article | 20 August 2004 Paper

CPL reticle technology for advanced device applications

Willard Conley, Douglas Van Den Broeke, Robert Socha, Wei Wu, Lloyd Litt, Kevin Lucas, Bernard Roman, Richard Peters, Colita Parker, J. Fung Chen, Kurt Wampler, Thomas Laidig, Erika Schaefer, Jan-Pieter Kuijten, Arjan Verhappen, Stephan van de Goor, Martin Chaplin, Bryan Kasprowicz, Christopher Progler, Emilien Robert, Philippe Thony, Michael Hathorn

Proceedings Volume 5446, (2004) https://doi.org/10.1117/12.557802

KEYWORDS: Photomasks, Optical proximity correction, Image processing, Reticles, Resolution enhancement technologies, Phase shifts, Mask making, Scanning electron microscopy, Quartz, Binary data

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Proceedings Article | 20 August 2004 Paper

CPL mask technology for sub-100-nm contact hole imaging

Bryan Kasprowicz, Willard Conley, Lloyd Litt, Douglas Van Den Broeke, Patrick Montgomery, Robert Socha, Wei Wu, Kevin Lucas, Bernard Roman, J. Fung Chen, Kurt Wampler, Thomas Laidig, Christopher Progler, Michael Hathorn

Proceedings Volume 5446, (2004) https://doi.org/10.1117/12.557755

KEYWORDS: Photomasks, Reticles, Manufacturing, Inspection, Lithography, Image processing, Semiconducting wafers, Quartz, Metrology, Optical lithography

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Proceedings Article | 28 May 2004 Paper

The application of CPL reticle technology for the 0.045-mm node

Will Conley, Douglas Van Den Broeke, Robert Socha, Wei Wu, Lloyd Litt, Kevin Lucas, Bernard Roman, Richard Peters, Colita Parker, Fung Chen, Kurt Wampler, Thomas Laidig, Erika Schaefer, Jan-Pieter Kuijten, Arjan Verhappen, Stephan van de Goor, Martin Chaplin, Bryan Kasprowicz, Christopher Progler, Emilien Robert, Philippe Thony

Proceedings Volume 5377, (2004) https://doi.org/10.1117/12.537613

KEYWORDS: Photomasks, Optical proximity correction, Reticles, Image processing, Resolution enhancement technologies, Phase shifts, Mask making, Scanning electron microscopy, Manufacturing, Quartz

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Proceedings Article | 28 May 2004 Paper

MEV as a new constraint for lithographers in the sub-100-nm regime

Yorick Trouiller, Sergei Postnikov, Kevin Lucas, Frank Sundermann, Kyle Patterson, Jerome Belledent, Christophe Couderc, Yves Rody

Proceedings Volume 5377, (2004) https://doi.org/10.1117/12.556617

KEYWORDS: Electroluminescence, Critical dimension metrology, Photomasks, Semiconducting wafers, Lithography, Cadmium, Logic devices, Process control, Sodium, SRAF

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Proceedings Article | 28 May 2004 Paper

Cost of ownership reduction for OPC development and production

Chi-Min Yuan, Bob Jarvis, Kevin Lucas, Robert Boone, Ruiqi Tian, Alfred Reich

Proceedings Volume 5377, (2004) https://doi.org/10.1117/12.535279

KEYWORDS: Optical proximity correction, Optical lithography, Lithography

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Proceedings Article | 28 May 2004 Paper

The impact of MEEF through pitch for 120-nm contact holes

Lloyd Litt, Wei Wu, Will Conley, Kevin Lucas, Bernard Roman, Patrick Montgomery, Bryan Kasprowicz, Christopher Progler, Robert Socha, Arjan Verhappen, Kurt Wampler, Erika Schaefer, Pat Cook, Jan-Pieter Kuijten, Wil Pijnenburg

Proceedings Volume 5377, (2004) https://doi.org/10.1117/12.537437

KEYWORDS: Fiber optic illuminators, Atrial fibrillation, Critical dimension metrology, Resolution enhancement technologies, Photomasks, Semiconducting wafers, Manufacturing, Reticles, Nanoimprint lithography, Binary data

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Proceedings Article | 3 May 2004 Paper

Combining OPC and design for printability into 65-nm logic designs

Kevin Lucas, Chi-Min Yuan, Robert Boone, Kirk Strozewski, Jason Porter, Ruiqi Tian, Karl Wimmer, Jonathan Cobb, Bill Wilkinson, Olivier Toublan

Proceedings Volume 5379, (2004) https://doi.org/10.1117/12.537655

KEYWORDS: Reticles, Optical proximity correction, Design for manufacturing, Lithography, Logic, Model-based design, Metals, Manufacturing, Optical lithography, Yield improvement

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SPIE Journal Paper | 1 April 2004

Comparisons of 9% versus 6% transmission attenuated phase shift mask for the 65 nm device node

Patrick Montgomery, Lloyd Litt, Willard Conley, Kevin Lucas, Johannes van Wingerden, Geert Vandenberghe, Vincent Wiaux

JM3, Vol. 3, Issue 02, (April 2004) https://doi.org/10.1117/12.10.1117/1.1669524

KEYWORDS: Photomasks, Printing, Critical dimension metrology, Lithography, Phase shifts, Optical lithography, Metals, Nanoimprint lithography, Semiconducting wafers, Image transmission

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Proceedings Article | 17 December 2003 Paper

Comparisons of 9% versus 6% transmission attenuated phase-shift mask for the 65-nm device mode

Patrick Montgomery, Kevin Lucas, Lloyd Litt, Will Conley, Eric Fanucchi, Johannes Van Wingerden, Geert Vandenberghe, Vincent Wiaux, Darren Taylor, Michael Cangemi, Bryan Kasprowicz

Proceedings Volume 5256, (2003) https://doi.org/10.1117/12.518022

KEYWORDS: Photomasks, Inspection, Printing, Reticles, Critical dimension metrology, Optical lithography, Manufacturing, Metals, 193nm lithography, Nanoimprint lithography

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Proceedings Article | 17 December 2003 Paper

METROPOLE-3D: a three-dimensional electromagnetic field simulator for EUV masks under oblique illumination

Zhengrong Zhu, Kevin Lucas, Jonathan Cobb, Scott Hector, Andrzej Strojwas

Proceedings Volume 5256, (2003) https://doi.org/10.1117/12.518544

KEYWORDS: Extreme ultraviolet, Photomasks, Waveguides, Light scattering, Electromagnetism, Scattering, Reflectivity, Diffraction, Lithographic illumination, Electromagnetic scattering

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Proceedings Article | 10 July 2003 Paper

Investigation of product design weaknesses using model-based OPC sensitivity analysis

Sergei Postnikov, Kevin Lucas, Cesar Garza, Karl Wimmer, Patrick LaCour, James Word

Proceedings Volume 5042, (2003) https://doi.org/10.1117/12.485263

KEYWORDS: Optical proximity correction, Reticles, Error analysis, Semiconducting wafers, Model-based design, Optical lithography, Product engineering, Data modeling, Atrial fibrillation, Lithography

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Proceedings Article | 2 July 2003 Paper

Practical quality metrics for resolution enhancement software

Robert Boone, Kevin Lucas, Raphael Wynd, Mike Boatright, Matthew Thompson, Alfred Reich

Proceedings Volume 5043, (2003) https://doi.org/10.1117/12.485281

KEYWORDS: Resolution enhancement technologies, Software development, Lithography, Software engineering, Optical proximity correction, Photomasks, Semiconducting wafers, Computer architecture, Phase shifts, Reticles

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The past few years have seen an explosion in the application of software techniques to improve lithographic printing. Techniques such as optical proximity correction (OPC) and phase shift masks (PSM) increase resolution and CD control by distorting the mask pattern data from the original designed pattern. These software techniques are becoming increasingly complicated and non-intuitive; and the rate of complexity increase appears to be accelerating [1]. The benefits of these techniques to improve CD control and lower cost of ownership (COO) is balanced against the effort required to implement them and the additional problems they create. One severe problem for users of immature and complex software tools and methodologies is quality control, [2] as it ultimately becomes a COO problem. Software quality can be defined very simply as the ability of an application to meet detailed customer requirements. Software quality practice can be defined as the adherence to proven methods for planning, developing, testing and maintaining software. Although software quality for lithographic resolution enhancement is extremely important, the understanding and recognition of good software development practices among lithographers is generally poor. We therefore start by reviewing the essential terms and concepts of software quality that impact lithography and COO. We then propose methods by which semiconductor process and design engineers can estimate and compare the quality of the software tools and vendors they are evaluating or using. We include examples from advanced process technology resolution enhancement work that highlight the need for high-quality software practices, and show how to avoid many problems. Note that, although several authors have worked in software application development, our analysis here is somewhat of a black box analysis. The black box is the software development organization of an RET software supplier. Our access to actual developers within these organizations is very limited. In so far as our comments with respect to the internal workings of these development organizations go, we rely on the interactions we have had with applications engineers and other technical specialists who provide our interface to the development organizations.