1 / 24

Interconnect Working Group

Interconnect Working Group. ITRS 2005 13 December 2005 Seoul,Korea Chris Case BOC Edwards US Sibum Kim MagnaChip Korea Mauro Kobrinsky Intel US Noh Jung Kwak Hynix Korea Hyeon-Deok Lee Samsung Korea Seh Kwang Lee Novellus Korea

truda
Download Presentation

Interconnect Working Group

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. Interconnect Working Group ITRS 2005 13 December 2005 Seoul,Korea Chris Case BOC Edwards US Sibum Kim MagnaChip Korea Mauro Kobrinsky Intel US Noh Jung Kwak Hynix Korea Hyeon-Deok Lee Samsung Korea Seh Kwang Lee Novellus Korea Kazuyoshi Ueno NEC Japan Osamu Yamazaki Sharp Japan

  2. Agenda • Scope • Technology requirements • Difficult challenges • Key changes • Cu resistivity effects • Crosstalk and performance • Low k roadmap • DRAM update • Emerging interconnect • Last word

  3. ITWG Regional Chairs Japan Tomoji Nakamura Hideki Shibata Taiwan Douglas CH Yu US Christopher Case Robert Geffken Europe Hans-Joachim Barth Alexis Farcy Korea Hyeon-Deok Lee Sibum Kim

  4. Robert Geffken Hans-Joachim Barth Alexis Farcy Harold Hosack Paul Feeney Ken Monnig Rick Reidy Hideki Shibata Kazuyoshi Ueno Michele Stucchi Douglas Yu Osamu Yamazaki Lucile Arnaud JD Luttmer Manfred Engelhardt Dirk Gravesteijn NS Nagaraj Mike Mills Gunther Schindler Chung-Liang Chang Tomoji Nakamura Christopher Case Partial List of Contributors

  5. Interconnect scope • Conductors and dielectrics • Metal 1 through global levels • Starts at pre-metal dielectric (PMD) • Associated planarization • Necessary etch and surface preparation • Embedded passives • Reliability and system and performance issues • Ends at the top wiring bond pads • Predominantly “needs” based, with some important exceptions (k and resistivity)

  6. Typical MPU cross section

  7. Technology Requirements • Wiring levels including “optional levels” • Reliability metrics • Minimum wiring/via pitches by level • Performance figure of merit • Planarization requirements • Conductor resistivity with and without scattering • Barrier thickness • Dielectric metrics including effective k • Crosstalk metric • Metal 1 variability due to CD and scattering

  8. Difficult challenges • Introduction of new materials to meet conductivity requirements and reduce the dielectric permittivity • Engineering manufacturable interconnect structures compatible with new materials and processes • Identify solutions which address global wiring scaling issues

  9. Whose linewidth is it anyway? The pitch for M1 • Recent publications by logic device manufacturers suggest that M1 and intermediate wire pitch is scaling rate at a rate faster than the current 2004 ITRS • “Non-contacted” or “staggered contacted” M1 pitch is widely used by most logic manufacturers. To avoid ambiguity - we will use staggered contacted M1 half pitch • Changes: • 90 nm M1 half pitch in 2005 • scaling at x 0.75 / 2 years from 2005 to 2009 • reverting to 3 years cycle in 2010 and beyond • Metal 1 pitches converging between DRAM, logic, flash

  10. Size matters • 2003 – the impending impact of Cu resistivity increases at reduced feature sizes (due to scattering) - noted • 2004 – metrics introduced to highlight the impact of width dependent scattering on the effective resistivity and impact on RC delay • Models have been refined to more accurately predict the resistivity due to changes in aspect ratio, shape and metal thickness • Metrics have been recalculated • Adapt the same methodology for DRAM when Cu is introduced (2007)

  11. Size matters

  12. Aspect Ratio Dependence

  13. Interconnect performances: crosstalk Input signal Crosstalk level • Crosstalk among neighbouring interconnects • Capacitive crosstalk roughly proportional to kc =CIMD /CILD • Mainly fixed by the aspect ratio of lines and vias • Crosstalk level increases at each new generation • Induces delay uncertainty (delay increased by crosstalk up to 3x delay) • Crosstalk is becoming a major issue • Special attention should be paid on these parasitic effects Metal 1

  14. Crosstalk • Introduced a crosstalk ratio as a metric to raise visibility of this issue • Line length where 25% of the switching voltage is induced on a victim global wire • Potential solutions • Introduction of ULK materials • Only a slight impact on crosstalk as both CIMD and CILD decrease • Development of hybrid architectures • Strong reduction of crosstalk level • Ultimate hybrid architecture is air gap • Reduction of the k-value of additional capping layers • Low-k dielectric barriers • Self-aligned barriers

  15. Dielectrics

  16. Integration Schemes

  17. Low k again! Near term MPU

  18. Low k long term MPU

  19. DRAM Small changes in specific via and contact resistivity Contact A/R rises to >20 in 2020 - a red challenge - associated with 16 nm DRAM half pitch Low k in 2003 - Cu delayed to 2007 Plan to distinguish embedded, flash, and traditional DRAM in the future

  20. Emerging Interconnect • Use geometry • 3D • Air gap • Use different signaling methods • Signal design • Signal coding techniques  • Use innovative design and package options • Interconnect - centric design • Package intermediated interconnect  • Chip-package co-design 

  21. Emerging interconnect • Use different physics • Optics (waveguides, emitters, detectors, free space, trans-impedance amps, modulators) • RF/microwaves (transmitters, receivers, free space, waveguides) • Terahertz photonics • Radical solutions • Nanowires/nanotubes • Molecules • Spintronics • Quantum wave functions 

  22. From low k to no k - air gaps Non-conformal deposition Sacrificial material • Introduction of air gap architectures • Creation of air gaps with non-conformal deposition • Removal of sacrificial materials after multi-level interconnects • Values of effective k-value down to 1.7 with low crosstalk levels • Localized air gaps to maintain good thermal and mechanical properties Ultra-low kand Air gap (k<2.0) (CVD & Spin-on)

  23. 2005 last words • Metal 1 design rule concerns • Staggered pitch used for definition • New • 90 nm half pitch for 2005 • High performance MPU pitches scaling at ~0.75/2 years until 2009 • Returning to 0.7/3 years • Working with Design, A&P and Test to identify directions for 3D ICs – may address global wiring problem

  24. Last words • Must manage the power envelope • Develop solutions for emerging devices • Must manage 3DCD • System level solutions must be accelerated to address the global wiring grand challenge • Cu resistivity increase impact appears ~2006 • materials solutions alone cannot deliver performance - end of traditional scaling • integrated approach with design and packaging

More Related