Your search keyword '"Process windows"' showing total 20 results

1. Experimental Development of an Injection Molding Process Window.

Author

Myers, Mason, Mulyana, Rachmat, Castro, Jose M., and Hoffman, Ben

Subjects

*MANUFACTURING processes, *INJECTION molding, *PLASTICS, *AMORPHOUS substances

Abstract

Injection molding is one of the most common and effective manufacturing processes used to produce plastic products and impacts industries around the world. However, injection molding is a complex process that requires careful consideration of several key control variables. These variables and how they are utilized greatly affect the resulting polymer parts of any molding operation. The bounds of the acceptable values of each Control Process Variable (CPV) must be analyzed and delimited to ensure manufacturing success and produce injected molded parts efficiently and effectively. One such method by which the key CPVs of an injection molding operation can be delimited is through the development of a process window. Once developed, operating CPVs at values inside the boundaries of the window or region will allow for the consistent production of parts that comply with the desired Performance Measures (PM), promoting a stable manufacturing process. This work proposes a novel approach to experimentally developing process windows and illustrates the methodology with a specific molding operation. A semicrystalline material was selected as it is more sensitive to process conditions than amorphous materials. [ABSTRACT FROM AUTHOR]

Published

2023

2. Experimental Development of an Injection Molding Process Window

Author

Mason Myers, Rachmat Mulyana, Jose M. Castro, and Ben Hoffman

Subjects

injection molding, process windows, simulation, controllable process variables, performance measures, Organic chemistry, QD241-441

Abstract

Injection molding is one of the most common and effective manufacturing processes used to produce plastic products and impacts industries around the world. However, injection molding is a complex process that requires careful consideration of several key control variables. These variables and how they are utilized greatly affect the resulting polymer parts of any molding operation. The bounds of the acceptable values of each Control Process Variable (CPV) must be analyzed and delimited to ensure manufacturing success and produce injected molded parts efficiently and effectively. One such method by which the key CPVs of an injection molding operation can be delimited is through the development of a process window. Once developed, operating CPVs at values inside the boundaries of the window or region will allow for the consistent production of parts that comply with the desired Performance Measures (PM), promoting a stable manufacturing process. This work proposes a novel approach to experimentally developing process windows and illustrates the methodology with a specific molding operation. A semicrystalline material was selected as it is more sensitive to process conditions than amorphous materials.

Published

2023

3. In Situ Investigations of Simultaneous Two‐Layer Slot Die Coating of Component‐Graded Anodes for Improved High‐Energy Li‐Ion Batteries.

Author

Diehm, Ralf, Kumberg, Jana, Dörrer, Christopher, Müller, Marcus, Bauer, Werner, Scharfer, Philip, and Schabel, Wilhelm

Subjects

LITHIUM-ion batteries, ANODES, STORAGE batteries, STYRENE-butadiene rubber, COATING processes, INVESTIGATIONS, ELECTRODES

Abstract

The use of thicker electrodes can contribute to a reduction in cell costs. However, the properties of the electrode must be kept in view to be able to meet the performance requirements. Herein, the possibility of simultaneous multilayer slot die coating is investigated to improve the electrode properties of medium‐ and high‐capacity anodes. The stable coating window of the two‐layer slot die coating process is investigated to produce property‐graded multilayer electrodes. Electrodes with different styrene–butadiene rubber (SBR) gradients are investigated with regard to adhesive force and electrochemical performance. An increase in the adhesive force of up to 43.5% and an increase in the discharge capacity is observed. [ABSTRACT FROM AUTHOR]

Published

2020

4. Back to the Press Shop

Author

Emmens, Wilko C. and Emmens, Wilko C.

Published

2011

5. Simulation-based process windows simultaneously considering two and three conflicting criteria in injection molding.

Author

Rodríguez-Yáñez, Alicia Berenice, Méndez-Vázquez, Yaileen Marie, and Cabrera-Ríos, Mauricio

Subjects

INJECTION molding, PARETO analysis, MULTIPLE criteria decision making, MATHEMATICAL optimization, MANUFACTURING industries

Abstract

Process windows in injection molding are habitually built with only one performance measure in mind. A more realistic picture can be obtained when considering multiple performance measures at a time, especially in the presence of conflict. In this work, the construction of process windows for injection molding is undertaken considering two and three performance measures in conflict simultaneously. The best compromises between the criteria involved are identified through the direct application of the concept of Pareto-dominance in multiple criteria optimization. The aim is to provide a formal and realistic strategy to set processing conditions in IM operations. The resulting optimization approach is easily implementable in MS Excel. The solutions are presented graphically to facilitate their use in manufacturing plants. [ABSTRACT FROM AUTHOR]

Published

2014

6. Impact of source pupil shapes on process windows in EUV lithography.

Author

Kuo, Hung-Fei

Abstract

International Technology Roadmap for Semiconductors (ITRS) report proposes extreme ultraviolet (EUV) lithography to be the key candidate of lithography tools to manufacture devices at the 22nm node and beyond. The image effects on wafer critical dimensions (CDs) in the EUV lithography are different from the effects in the conventional lithography caused by the off-axis illumination and refelective optics design. This research investigates process windows of line/space (L/S) with the target CD 22nm and contact hole (CH) features with the target CD 35nm illuminated by the conventional, annular, dipole, and quasor source shapes. The diffraction amplitudes by the EUV mask are summarized. The research suggests that the dipole is the better illumination source shape to print L/S features and the quasor is the better one for CH features. In addition, the research reports the best dipole illumination setting for the L/S features and the best quasor illumination setting for the CH features. The exposure latitude and depth of focus (DOF) for L/S feature illuminated by the dipole to print the target CD 22nm are 4% and 100nm respectively. The exposure latitude and DOF for CH feature illuminated by the quasor to print the target CD 35nm are 24% and 300nm respectively. Full field analysis of CH CDs displays the minimized CD error through slit due to the quasor illumination in the EUV lithography. [ABSTRACT FROM PUBLISHER]

Published

2013

7. Photo isomerization of cis-cyclooctene to trans-cyclooctene: Integration of a micro-flow reactor and separation by specific adsorption

Author

Elnaz Shahbazali, Timothy Noël, Volker Hessel, Arash Sarhangi Fard, Emilie M. F. Billaud, J Jan Meuldijk, Guy Bormans, Micro Flow Chemistry and Synthetic Meth., and Process and Product Design

Subjects

Technology, Engineering, Chemical, Environmental Engineering, Materials science, flow chemistry, General Chemical Engineering, MASS-TRANSFER, Separator (oil production), Process design, 02 engineering and technology, CLAISEN REARRANGEMENT, microreactor, isomerization, chemistry.chemical_compound, Adsorption, Engineering, 020401 chemical engineering, DESIGN, Cyclooctene, PROCESS WINDOWS, PHOTOISOMERIZATION, Process integration, process integration, 0204 chemical engineering, PACKED-BED REACTORS, Science & Technology, photochemistry, INTENSIFICATION, ORDER, Flow chemistry, 021001 nanoscience & nanotechnology, MODEL, chemistry, Chemical engineering, Microreactor, 0210 nano-technology, Isomerization, Biotechnology

Abstract

Liquid-phase adsorption has hardly been established in micro-flow, although this constitutes an industrially vital method for product separation. A micro-flow UV-photo isomerization process converts cis-cyclooctene partly into trans-cyclooctene, leaving an isomeric mixture. Trans-cyclooctene adsorption and thus separation was achieved in a fixed-bed micro-flow reactor, packed with AgNO3/SiO2 powder, while the cis-isomer stays in the flow. The closed-loop recycling-flow has been presented as systemic approach to enrich the trans-cyclooctene from its cis-isomer. In-flow adsorption in recycling-mode has hardly been reported so that a full theoretical study has been conducted. This insight is used to evaluate three process design options to reach an optimum yield of trans-cyclooctene. These differ firstly in the variation of the individual residence times in the reactor and separator, the additional process option of refreshing the adsorption column under use, and the periodicity of the recycle flow. ispartof: AICHE JOURNAL vol:67 issue:1 ispartof: location:United States status: published

Published

2021

8. Effect of Source Pupil Shape on Process Windows in EUV Lithography.

Author

Kuo, Hung-Fei

Abstract

According to the International Technology Roadmap for Semiconductors report, extreme ultraviolet (EUV) lithography is a key lithography tool for manufacturing devices at the 22-nm node and above. The current findings suggest that the lithographic image affects the critical dimensions (CDs) of wafers used in EUV lithography differently from those used in conventional lithography because of off-axis illumination and reflective optics design. The process windows of line/space (L/S) were explored, using a target CD of 22 nm and illuminating target contact hole (CH) features of a CD of 35 nm by using conventional, annular, dipole, and quasor source shapes. The diffraction amplitudes of the L/S and CH EUV masks and corresponding aerial images were calculated. The results indicate that the dipole is the favorable illumination source shape for printing the L/S features and the quasor is favorable for printing the CH features. In addition, the optimal dipole and quasor illumination settings are reported for the L/S and CH features, respectively. The exposure latitude was 4% and the depth of focus (DOF) was 100 nm to illuminate the L/S feature by using the dipole to print the target at a CD of 22. The exposure latitude was 24% and the DOF was 300 nm to illuminate the CH feature by using the quasor to print the target CD at 35 nm. [ABSTRACT FROM PUBLISHER]

Published

2014

9. Quality-in(Process)Line (QuIProLi) process intensification for a micro-flow UV-photo synthesis enabled by online UHPLC analysis

Author

Maarten Honing, Volker Hessel, Marc Escribà-Gelonch, Elnaz Shahbazali, Imaging Mass Spectrometry (IMS), RS: M4I - Imaging Mass Spectrometry (IMS), and Micro Flow Chemistry and Synthetic Meth.

Subjects

NEAR-INFRARED SPECTROSCOPY, Process automation, Fast-sampling, IN-LINE, Flow chemistry, Abstract process, 010402 general chemistry, CLAISEN REARRANGEMENT, 01 natural sciences, Biochemistry, Robustness (computer science), PROCESS WINDOWS, Drug Discovery, UHPLC, Process engineering, SELF-OPTIMIZATION, Reaction conditions, 010405 organic chemistry, business.industry, Chemistry, Organic Chemistry, REACTOR SYSTEM, ORGANIC-SYNTHESIS, Work in process, Process automation system, Automation, Self-optimization, PARTICLE-SIZE, 0104 chemical sciences, Analytics, INTEGRATED MICROREACTOR SYSTEM, LIQUID-CHROMATOGRAPHY, business, Photo-Claisen rearrangement

Abstract

Process intensification commonly enables reaction acceleration and therefore continuous-flow/PAT is urgently needed. The low volumes typical for micro-flow pose challenges for online sampling operations in analytics. In this paper, a very fast process is combined with a modified ultra-high-performance liquid chromatography (UHPLC) system allowing for very fast sampling and analysis. Low-volume online sampling according to the needs posed by PAT for pharma quality control, is introduced here for UHPLC analysis of the photo-Claisen rearrangement in micro-flow. Chances and challenges are critically reviewed, including the reproducibility and robustness of the sampling. Furthermore, the ability and speed of the chosen set-up in order to capture process changes and adjust the process parameters properly is investigated. With the applied online sampling system, it was possible to perform, almost unattended and spending 12 times less sampling volume, a full factorial analysis of all relevant reaction conditions (243 experiments) in three days. Such quality-in-the-process-line (QuIProLi) online sampling avoided random errors due to automation. (C) 2018 Elsevier Ltd. All rights reserved.

Published

2018

10. A study on the analytical modeling for warm hydro-mechanical deep drawing of lightweight materials

Author

Choi, Ho, Koç, Muammer, and Ni, Jun

Subjects

*FORCING (Model theory), *SHEET metal work, *LIGHTWEIGHT construction, *METALWORK

Abstract

Abstract: The warm hydroforming process has become an emerging technology in recent years to reduce the weight of automotive body structure and minimize the number of process steps. In this study, analytical models were developed to investigate the effects of process conditions such as temperature, hydraulic pressure, blank holder force and forming speed. The analytical model under hydro-mechanical deep drawing (HMD) condition was developed based on experimental results in the literatures. FE models were also developed to validate the analytic models. Then, the analytic model was validated through comparisons with both existing experimental results and FE results. The analytical model provided rapid and reasonably accurate results for the design of warm hydroforming process. Based on this analytic model, several parametric studies were performed regarding to the temperature, hydraulic pressure, blank holder force, and punch speed conditions. It was demonstrated that the process windows for a successful part forming could be rapidly predicted with a reasonable accuracy by the analytic model compared to lengthy and costly thermo-mechanical FEA or experimental trial and error. [Copyright &y& Elsevier]

Published

2007

11. Slot die coating of lithium-ion battery electrodes

Author

Schmitt, Marcel and Schabel, W.

Subjects

Chemical engineering, lithium-ion batteries, ddc:660, Schlitzguss, Slot die, coating, process windows, thin film technology, Beschichtung, Lithium-ionen Batterien, Prozessfenster, Dünnfilmtechnik

Abstract

Li-Ionen-Batterien können helfen, die Energiewende zu beschleunigen. Innerhalb ihrer Prozesskette, ist einer der wichtigsten Schritte die Elektrodenherstellung im Schlitzguss. Erhöhte Geschwindigkeiten und ein geringerer Ausschuss könnten zu niedrigeren Kosten beitragen. Gegenstand dieser Arbeit ist deshalb die wissenschaftliche Ausarbeitung eines fundierten Prozessverständnisses von einlagigen und simultan-mehrlagigen Beschichtungen, minimierten Randeffekten und einem intermittierten Prozess.

Published

2016

12. Heat Management in Single and Multi-injection Microstructured Reactors: Scaling Effects, Stability Analysis, and Role of Mixing

Author

Lioubov Kiwi-Minsker, Julien Haber, M.N. Kashid, and Albert Renken

Subjects

Optimal design, Exothermic reaction, Microchannel Reactors, Materials science, General Chemical Engineering, Nuclear engineering, Mixing (process engineering), Ionic Liquids, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Stability (probability), Industrial and Manufacturing Engineering, Numbering-Up, Phase Fluid-Flow, Magnetic Microstirrer, Of-The-Art, Scaling, Temperature control, Process Windows, Optimal-Design, General Chemistry, Micro-Channels, 021001 nanoscience & nanotechnology, Product distribution, 0104 chemical sciences, Chemical engineering, Heat transfer, Process Intensification, 0210 nano-technology

Abstract

The exothermic reactions with fast intrinsic kinetics when carried out in conventional reactors are often limited by heat transfer. This results in the formation of hot spots, which affects product distribution of complex reactions and may lead to reactor runaway. Microstructured reactors (MSR) have been successfully used for this type of reaction, gaining increased temperature control and enhanced safety. Although different MSR concepts have been applied to various processes, the general design criteria are still poorly discussed in the literature. In this review, temperature management in conventional single injection MSR is described. The important issues, such as reactor safety and stability, along with the role of mixing, are discussed in detail. Subsequently, the multi-injection reactor concept is introduced and a simplified model developed to investigate the temperature profile is presented. Finally, the benefits and critical issues in the design of multi-injection MSR are highlighted.

Published

2012

13. Using the Plunging and Welding Process Windows to Determine a FSW Means of Production

Author

Régis Bigot, Julien Laye, Patrick Martin, Laurent Langlois, Sandra Zimmer, and Jean-Claude Goussain

Subjects

Engineering, business.industry, Friction Stir Welding, Génie des procédés [Sciences de l'ingénieur], General Engineering, Process (computing), Mechanical engineering, Welding, Industrialization, Two stages, Manufacturing engineering, law.invention, Plunging stage, Welding process, law, Torque, Friction stir welding, Process window, Process windows, business, Parametric statistics

Abstract

This paper presents an experimental methodology to determine a Friction Stir Welding (FSW) means of production based on the experimental study of the tool / material mechanical interactions generated during the plunging and welding stages. These two stages have been identified as being characteristic for the qualification of a FSW equipment. This paper presents the experimental results of the parametric study done on the plunging and welding phases. Ranges of forces and torques diagrams were established according to the processing parameters, in order to qualify a means of production and select the process parameters allowing the operation on the available FSW equipment.

Published

2010

14. Experimental investigation of process performance enhancing in extrusion of a magnesium hollow profile

Author

SEGATORI, ANTONIO, DONATI, LORENZO, TOMESANI, LUCA, T. Pinter, Y. Rami, ANTONIO SEGATORI, A. Segatori, T. Pinter, Y.Rami, L. Donati, and L.Tomesani

Subjects

MAGNESIUM, PROCESS WINDOWS, PROCESS MONITORING, EXTRUSION

Abstract

In the present paper a new concept die purposely designed for magnesium extrusion has been investigated. Despite it is often common practice to adopt die design similar to aluminum production for magnesium, a tailored design has been develop with the aim to increase process efficiency and die resistance. The extrudate selected for the trials was a round hollow profile to be used in bike frames actually processed at 0,2mm/sec ram speed (1,4 m/min exit speed) in relation to the previously explained limits. Two magnesium alloys, ZM21 and AZ31, have been tested at various speeds in order to evaluate the process rate limit. Temperature and loads were also monitored during the extrusion trials.

Published

2011

15. Qualification of a robotized Friction Stir Welding System

Author

ZIMMER-CHEVRET, Sandra, LANGLOIS, Laurent, LAYE, Julien, GOUSSAIN, Jean-Claude, MARTIN, Patrick, and BIGOT, Régis

Subjects

Plunging stage, Friction Stir Welding, Génie des procédés [Sciences de l'ingénieur], Process windows, Industrialization

Abstract

This paper presents an experimental methodology to determine a Friction Stir Welding (FSW) means of production based on the experimental study of the tool / material mechanical interactions generated during the welding operation. These two stages have been identified as being characteristic for the qualification of a FSW equipment. This paper presents the experimental results of the parametric study done on the plunging and welding phases. Ranges of forces and torques diagrams were established according to the processing parameters, in order to qualify a means of production and select the process parameters allowing the operation on the available FSW equipment.

Published

2010

16. Determining the ability of a high payload robot to perform FSW applications

Author

ZIMMER-CHEVRET, Sandra, LANGLOIS, Laurent, LAYE, Julien, GOUSSAIN, Jean-Claude, MARTIN, Patrick, and BIGOT, Régis

Subjects

Plunging stage, Friction Stir Welding, Génie des procédés [Sciences de l'ingénieur], Process windows, Industrialization

Abstract

This paper presents an experimental methodology to determine a Friction Stir Welding (FSW) means of production based on the experimental study of the tool / material mechanical interactions generated during the welding operation. These two stages have been identified as being characteristic for the qualification of a FSW equipment. This paper presents the experimental results of the parametric study done on the plunging and welding phases. Ranges of forces and torques diagrams were established according to the processing parameters, in order to qualify a means of production and to select the processing parameters allowing the operation on the available FSW equipment.

Published

2010

17. Contribution a l'industrialisation du soudage par friction malaxage

Author

Zimmer, Sandra, Laboratoire de Conception Fabrication Commande (LCFC), Arts et Métiers Sciences et Technologies, HESAM Université (HESAM)-HESAM Université (HESAM)-Université de Lorraine (UL), Arts et Métiers ParisTech, Régis Bigot, Laurent Langlois, and HESAM Université (HESAM)-HESAM Université (HESAM)

Subjects

[SPI]Engineering Sciences [physics], Domaine de soudabilité opératoire, soudage par friction malaxage (FSW), FSW Equipment, Friction Stir Welding, Process windows, Industrialization, machine de soudage FSW, Industrialisation

Abstract

The Friction Stir Welding (FSW) is a solid state welding process which avoids some problems encountered by fusion welding, like hot cracking or solidification defects. The welding is performed by a rotating tool, inserted into the interface of two rigidly clamped workpieces. The required heat energy is provided by the friction between this tool and the workpieces. The combined tool rotation and translation create the material stirring, joining the workpieces together. The resulting efforts at the interface must be support by the machine and the part-holding device. They are thus a major issue for the choice of the welding equipments. This thesis work consists in implementing a method to qualify means of production for FSW process, by identifying the suitable part of the process windows. This method is threefold. The first point is the identification of the characteristic parameters of FSW process. These one are taken into account in specifications for the choice or the design of a means of production for FSW. The second point of the method is the experimental characterization of the process windows. The mechanical actions on the tool were associated with each combination of the operating parameters of the process windows. This experimental study highlighted the effect of driving parameters on the efforts at the tool/product interface. Lastly, the last point of the method is the validation of the selected means of production for FSW, thanks to the collected experimental data sets. These mean of production is modelled in order to check the capacities of the device, the pin and the parts holder used to carry out the operation of welding. The method of qualification was implemented in the case of multi-axis robot (6 axis). This; Le soudage par friction malaxage, ou FSW, est un procédé de soudage à l'« état solide » permettant d'éviter certains problèmes rencontrés en soudage par fusion comme la fissuration à chaud ou la création de soufflures. La soudure est réalisée par l'action d'un outil à l'interface de deux pièces à souder. Celui-ci a pour rôle de malaxer et d'échauffer par frottement la matière. Le cordon est réalisé de proche en proche. Les efforts générés à l'interface outil/matière doivent être repris par la machine et le montage de soudage. Ils sont donc un facteur important pour le choix des moyens de soudage. Ce travail de thèse consiste à mettre en place une démarche pour qualifier les moyens de production FSW, en identifiant la partie du domaine de soudabilité opératoire accessible par le moyen envisagé. Ce travail comporte trois phases. La première est l'identification des paramètres caractéristiques du procédé FSW. Cela aboutit à l'écriture de spécifications du cahier des charges pour le choix ou la conception d'un moyen de production. Une fois ces paramètres identifiés, la deuxième étape de la démarche est la caractérisation expérimentale des domaines de soudabilités opératoires (DSO). Les actions mécaniques appliquées sur l'outil ont été associées à chaque combinaison des paramètres opératoires de ces domaines. Cette étude expérimentale a mis en évidence l'influence des paramètres de conduite sur le torseur des efforts outil/matière. Ces derniers peuvent être réduits en agissant sur ces mêmes paramètres opératoires. Enfin, la dernière phase de la démarche est la validation du moyen de production FSW choisi, grâce à l'ensemble des données expérimentales recueillies. Ce moyen de production est modélisé dans le but de tester les capacités de la machine, de la broche et du porte-pièces pour réaliser l'opération de soudage. La démarche de qualification a été mise en œuvre à la réalisation de soudures FSW par un robot polyarticulé (6 axes). Cette structure « peu rigide » et de « faible » capacité en effort est très sensible aux actions mécaniques générées par le FSW. Le choix des paramètres opératoires de soudage s'appuie sur les DSO déterminés expérimentalement pour les phases de plongée et de soudage, bornées par les limites de la machine. Il est nécessaire, pour ce type de structure, de qualifier son aptitude à réaliser l'opération de soudage FSW, car ses capacités dépendent fortement de la position de l'outil dans l'espace de travail.

Published

2009

18. Studies on hot-rolled galvanized steel sheets: Segregation of alloying elements at the surface

Author

Arunansu Haldar, V. Subramanya Sarma, Debashish Bhattacharjee, B.S. Murty, and Amares Chattopadhyay

Subjects

Materials science, Mechanical Engineering, Metallurgy, technology, industry, and agriculture, Metals and Alloys, chemistry.chemical_element, Condensed Matter Physics, Galvanization, Hot rolled, symbols.namesake, Cooling rate, chemistry, Mechanics of Materials, symbols, General Materials Science, Process window, Annealing atmosphere, Carbon, Alloying, Alloying elements, Annealing, Cooling, Galvanized metal, Galvanizing, Hot rolling, Hot rolling mills, Hot working, Iron, Metal working, Segregation (metallography), Steel, Steel sheet, Surfaces, Zinc, (1 1 0) surface, Annealing atmospheres, Cooling rate (CR), Galvanized steel sheet (GI), Hot rolled steel (HRS), Hot-rolled, Process windows, Segregation (beneficiation), surface regions, Surface segregation

Abstract

The Zn coatability of hot-rolled steel sheets is dependent on the extent of the segregation of carbon and other alloying elements in the surface region. The mechanism of segregation has been established and it is found that the extent of segregation is dependent on the cooling rate after the hot rolling and on the annealing atmosphere. This segregation study will determine the proper process window for galvanizing this type of steel through a continuous galvanizing route. � 2008 Acta Materialia Inc.

Published

2008

19. Evaluation of double focal plane exposure technique for 248-nm and 193-nm lithography for semidense trenches and contacts

Author

Govanni Bianucci, Francesco Enrichi, Gianfranco Capetti, Francois Weisbuch, and Gina Cotti

Subjects

Multiple exposure, aerial image, defocus, Materials science, business.industry, multiple exposure, process windows, Exposure technique, simulation, Flex, Wavelength, CD uniformity, Cardinal point, Optics, Bossung, business, Lithography, Aerial image, Coherence (physics)

Abstract

Double focal plane exposure technique has the property to increase greatly the depth of focus of a lithographic process and appears to be a solution to fulfil the requirements of the most aggressive lithographic targets. The purpose of this work is to investigate the performances of this technique and to understand its mechanisms, to be able to find the best conditions of use for a given process. A simple model based on aerial images considerations has been developed to determine the behaviors of the main lithographic parameters (DoFmax, Elmax, central dose, shape of the Bossung curves) for various values of the distance between the two focal planes. Comparisons with four experiments have been realized with different conditions (type of pattern, dimensions, wavelength, N.A. and coherence (sigma) ). The possibility to predict the best experimental conditions (trade-off between DoF, El, resolution and LER) has been verified.

Published

2002

20. Investigation of electron beam nanolithography processes, mechanisms, and applications

Author

Mohammad, Mohammad A.

Subjects

Anchor Modeling, SML Resist, HSQ Resist, Process Windows, Polymer Physics, PMMA Resist, Electron Beam Lithography, Nanofabrication, Molecular Dynamics Simulations, Nanomechanical Cantilevers, ZEP Resist, Silicon Carbon Nitride (SiCN), Polymer Solutions, Resonant Nanostrings, Sub-10 nm Nanofabrication, Dense Gratings, Flory-Huggins Theory, Diffusivity

Abstract

Abstract: Electron beam lithography (EBL) is the leading technology for versatile two dimensional patterning at the deep (10-100 nm) nanoscale. In addition to its reputation as an enabling technology for next generation advances in industry, its ease of use, accuracy, and cost has made it the technology of choice for rapid sub-micron prototyping in academia and research institutes worldwide. Advances in EBL processing have enabled sub-10 nm fabrication using a variety of materials under limited conditions. Repeatable processing at the deep nanoscale, particularly for dense nanostructure fabrication, requires a systematic quantitative study of all processing steps and their intricate interdependencies. In addition, developing future nanofabrication strategies with features approaching molecular length scales, requires a thorough examination of the molecular interactions taking place in EBL processing. This research project investigates EBL processing using PMMA and ZEP resists through an in-depth quantitative study and analysis of process windows for dense grating fabrication. The effect of processing parameters from each EBL stage on process windows is thoroughly investigated. Through the study of process windows and contrast curves, EBL processing strategies are developed and high resolution processing limits in PMMA and ZEP resists are explored. Furthermore, the EBL development stage involving resist-solvent interactions is studied using molecular dynamics simulations in Accelrys Materials Studio software package, and analyzed using the Flory-Huggins polymer physics theory. Finally, optimized processing strategies for dense grating fabrication are demonstrated and techniques are employed for the fabrication of record ultra-narrow (8 nm) suspended SiCN cantilever structures and high aspect ratio polymer fabrication using novel SML resist.

Published

2013