1 / 19

Modeling and Simulation ITWG Jürgen Lorenz - FhG-IISB

Modeling and Simulation ITWG Jürgen Lorenz - FhG-IISB. ITWG/ TWG Members. H. Jaouen, STM * W. Molzer, Infineon * R. Woltjer, Philips * G. Le Carval, LETI J. Lorenz, Fraunhofer IIS-B * W. Schoenmaker, IMEC * supported by EC User Group UPPER+ T. Wada, SELETE S. Sato, Fujitsu

pello
Download Presentation

Modeling and Simulation ITWG Jürgen Lorenz - FhG-IISB

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Modeling and Simulation ITWG Jürgen Lorenz - FhG-IISB ITWG/TWG Members H. Jaouen, STM* W. Molzer, Infineon* R. Woltjer, Philips* G. Le Carval, LETI J. Lorenz, Fraunhofer IIS-B* W. Schoenmaker, IMEC * supported by EC User Group UPPER+ T. Wada, SELETE S. Sato, Fujitsu Japanese TWG 16 industrial members C. Riccobene, AMD M. Giles, INTEL M. Orlowski, Motorola M. Meyyappan, NASA V. Bakshi, SEMATECH J. Wu, TI E. Hall, Arizona State Univ. J.-H. Choi, Hynix K.H. Lee, Samsung

  2. Key Messages (I) • Update of key messages from 2001/2002 ITRS: • Technology modeling and simulation is one of a few enabling methodologies that can accelerate development times and reduce development costs: Assessment up to 35% in 2003 •  important not only in years of difficult economic conditions • Modeling and simulation provides an ‘embodiment of knowledge and understanding’. It is a tool for technology/device optimization and also for training/education • Accurate experimental characterization is essential • Art of modeling: • - Combine different experiments & theory to extract physical mechanisms • & parameters • - Find appropriate trade-off between detailed physical simulation (CPU and • memory costly) and simplified but physically appropriate approaches

  3. Key Messages (II) • Further growing importance of atomistic/hierarchical/multilevel simulation, materials - appropriate treatment of nanostructures • Extension of cross-cut links to the other ITRS sections ongoing process • Specific problem for 2003 • - Delays in guidelines, + travel restrictions at companies • - Need for additional participation esp. from Korea, Taiwan, and partly • also USA

  4. M& S 2003 Sequence of Actions • Requirements: Update 2003 & critically review & simplify 2003 tables • (still valid details into text) - also for readability and preparation for 2004 • • Critically update challenges (timing and content) • Consider transition into Nano Era • Further strengthen interactions with other ITWGs • (esp. around San Francisco meeting) • ITWG composition: Updates in US and Japan on the way/done, • more contributions from Korea and Taiwan needed

  5. Technology Modeling SCOPE & SCALES • Equipment related • Equipment/feature scale • Lithography • Feature scale • Front End, Back End • Device 2001/2 Chapter sub-sections in blue - (slight changes in 2003 in progress) • IC-scale • Circuit elements • Package modeling • Interconnect performance modeling •Materials Modeling •Numerical Methods

  6. Short-Term Challenges: Major Changes • Modeling hierarchy included  “Modeling of shallow junctions” extended • to “Front-End Process Modeling for Nanometer Structures” • • “Ultimate nano-scale CMOS simulation capability” pulled in from long-term, replacing & partly incorporating “Gate-stack models for ultra-thin dielectrics” (phenomenological models) • • Rest of “Gate-stack models for ultra-thin dielectrics”incorporated into new long-term challenge on predictive “Modeling of processing and electrical properties of new materials“ • • 2002 long-term challenge “Thermal-Mechanical-Electrical Modeling for interconnections and packaging“ pulled in to short-term (6th short-term challenge) • More precise phrasing & shift of emphasis / new aspects in other • challenges

  7. Difficult Challenges > 45 nm: Status June 23, 2003

  8. Short-term Difficult Challenges High-Frequency Circuit Modelingfor 5-40 Ghz applications • Needs • Efficient extraction and simulation of full-chip interconnect delay • Accurate and yet efficient 3D interconnect models, esp. for transmission lines and S-parameters • High-frequency circuit models including • non-quasi-static effects • substrate noise • parasitic coupling • Parameter extraction assisted by numerical electrical simulation instead of RF measurement (From Philips)

  9. Short-Term Difficult Challenges Front-End Process Modeling for Nanometer Structures Needs • Diffusion/activation/damage models and parameters incl. low thermal budget processes in Si-based substrate, e.g. Si, SiGe:C, (incl. strain), SOI and ultra-thin body devices • Characterization tools for ultra-shallow geometries and dopant levels • Modeling hierarchy from atomistic to continuum for dopants and defects in bulk and at interfaces Source: A. Claverie, CEMES/CNRS, Toulouse, France

  10. Short-Term Difficult Challenges Modeling of Equipment Influences on Features Generated in Deposition and Etching Processes Needs • Fundamental physical data ( e.g. rate constants, cross sections, surface chemistry); reaction mechanisms and reduced models for complex chemistries • Linked equipment/feature scale models • CMP (full wafer and chip level, pattern dependent effects) • •MOCVD, PECVD and ALD modeling • • Multi-generation equipment/wafer models Simulated across-wafer variation of feature profile for a sputter-deposited barrier.

  11. Short-Term Difficult Challenges Lithography Simulation including NGL Needs • Optical simulation of resolution enhancement techniques including mask optimization (OPC, PSM) • Predictive resist models incl. line-edge roughness, etch resistance and mechanical stability • Multi-generation lithography system models Printing of defect on phase-shift mask: bump defect (top) vs. etch defect (lower)

  12. Short-Term Difficult Challenges Ultimate nanoscale CMOS simulation capability Pulled in from long-term! Needs • Methods and algorithms which contribute to prediction of CMOS limits • Quantum based simulators • Models and analysis to enable design and evaluation of devices and architectures beyond traditional planar CMOS • Phenomenological gate stack models for ultra-thin dielectrics • Models for device impact of statistical fluctuations in structures and dopant distributions

  13. Short-Term Difficult Challenges Thermal-Mechanical-Electrical Modeling for interconnections and packaging Pulled in from long-term! Needs • Model thermal-mechanical and electronic properties of Low-k, High-k and conductors and the impact of processing on these properties • Model reliability of packages and interconnects, e.g. Stress voiding, electromigration, piezoelectric effects; textures, fracture, adhesion

  14. Long-Term Challenges: Major Changes • “Extend beyond continuum tools” shifted to short-term & integrated there • into various challenges, esp. “Front-End Process Simulation” • Instead: “Modeling of processing and electrical properties of new materials” • “Ultimate nanoscale CMOS simulation capability“ shifted to short-term, including parts of old „gate stack modeling“ challenge • “Thermo-Mechanical-Electrical Modeling for Interconnections and Packaging” shifted to short-term • “Software Module Integration” skipped: Rather a requirement than a • challenge • Instead: “Nano-Scale Modeling” (e.g. nanotubes ...) • New challenge “Optoelectronics modeling”

  15. Difficult Challenges < 45 nm

  16. Short-Term Requirement: Major Changes General: - Some items now in “zebra” colour - according to ITRS guidelines: “Limitations of available solutions will not delay the start of production. In some cases, work-arounds will be initially employed. Subsequent improvement is expected to close any gaps for production performance in areas such as process control, yield, and productivity.“ - This means for simulation: It can be used, but with more calibration, larger CPU time/memory, less generality then in the end required ...

  17. Short-Term Requirement: Major Changes Lithography: - In exposure simulation no more emphasis on evaluation of wavelengths, but on capabilities of simulation incl. mask features and CPU efficiency Gate stack: - Short-term focus on high-k - “Alternative” dielectrics / gates tbd with PIDS Back-End Process/Equipment/Topography Modeling - More clear structure, according to kinds of processes to be simulated

  18. Short-Term Requirement: Major Changes Numerical device modeling: - Instead of “bulk CMOS” and “non-bulk” CMOS now “Classical CMOS” and “Non-classical CMOS incl.channel-engineered devices” “Circuit element modeling/ECAD” replaced by “circuit component modeling”& now structured into - Active devices - Interconnects and integrated passives Package modeling now structuring into - Electrical modeling - Thermo-mechanical modeling instead of an item “thermo-mechanical-electrical integrated models”

  19. More details given in tables • Thank you

More Related