uk sige research programme epsrc final review meeting, thursday november 4th 2004 electrical and...
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UK SiGe Research ProgrammeEPSRC
Final Review Meeting, Thursday November 4th 2004Electrical and Electronic Engineering Dept, Imperial College,
Device Modelling in the New Silicon Era& the future with silicon
John Barker
Nanoelectronics Research CentreDepartment of Elelectronics and Electrical Engineering
University of Glasgow
Human Resources
John Barker
Asen Asenov
Scott Roy
Jeremy Watling
Savas Kaya
Mirela Borici
Richard Wilkins
Lianfeng Yang
Antonio Martinez
Outline
Deliverables: Publications, Conferences, Grants, Collaborations
Context: where we are with Si and SiGe (update)
Theory and Modelling: 3D atomistic Full Band Monte Carlo,
3D Non-equilibrium Green function atomistic simulator 3D NASA codes
High dielectricsDevices: conventional versus strained Si MOSFETsNano-silicon and atomistic MOSFETs
The future with silicon (I come to bury silicon not to praise it!)€
κ
Deliverables in Phase I-II (2001-2004): I
Publications: > 50 (major journals inc IEEE Trans)
Review paper:”The impact of interface roughness scattering and degeneracy in relaxed and strained Si n-channel MOSFETs”Solid State Electronics, 48, 1337-1346 (2004)
Special mention:”I am pleased to tell you that your article, "Si/SiGe heterostructure parameters for device simulations", in Semiconductor Science and Technology, Vol 19, pp1174 (2004), has been downloaded 250 times so far.To put this into context, across all IOP journals 10% of articles were accessed over 250 times this quarter.”
Conferences: IEDM, ESSDERC, Si-VLSI, ICPS26, ICPS27, VLSI02,03,04 CMMP04,SISPAD,NEGF2,MSED03,EDSSC03, EDMO,ULSI04,ICSIT04,IWCE9, SIMD-6,NPMD03, HCIS13, IWCE10,HighKWorshopAustin04,Sematech Symp
Invited papers: 12
Special notice: Paper accepted for IEDM’04.
Deliverables (2001-2004): II
New Grants and Collaborations
1. Statistical 3D simulation of intrinsic parameter fluctuations in decananometer MOSFETS introduced by discreteness of charge and matterA Asenov, J.R. Barker, S Roy, J Watling EPSRC HPC facility EPSRC 01/10/04-30/09/04 £ 153021
2. Modelling the impact of high-k gate stacks on mobility device performance and intrinsic parameter fluctuations J. Watling , A. Asenov ,J.R.Barker, S. Roy; and UCL; International Sematech 09/2004-10/2006 $ 310 000
3. SINANO - Network of Excellence A. Asenov , J.R. Barker,S. Roy IMEC, LETI, INFINEON, ST MICROELECTRONICS European Commission 01/2004-02/2007 € 250 000
4. Sub 100 nm III-V MOSFETs for Digital Applications With 14 others MOTOROLA, University of Surrey EPSRC 09/2003-09/2006 £ 3000 000
5. Meeting the materials challenges of nano-CMOS electronics A Asenov, J.R. Barker and S Roy collaboration with University College London and NASA Ames EPSRC, 01.07.04-30.06.08: £ 354711
6. Atomistic simulation of nanoscale devices A Asenov, J.R. Barker, S Roy EPSRC Platform grant, 06.02-05.07: £ 429564
Other stuff
Intel using SiGe/Si hole band model for compact studies.
Sharing atomistic codes
NASA 2D and 3D NEGF codes to be shared with Glasgow
Our 3D atomistic NEGF codes to be shared with NASA
DFT collaborationsunderway
INDUSTRY: IBM, Intel,ToshibaNASA, Sony, Freescale…
International Technology Roadmap 2001 EditionYear 2001 2004 2007 2010 2013 2016
Technology node (nm) 130 90 65 45 32 22
MPU Gate Length (nm) 65 37 25 18 13 9
Oxide thickness (nm) 1.3-1.6 0.9-1.4 0.6-1.1 0.5-0.8 0.4-0.6 0.4-0.5
Intel May 2002IBM Dec 2002
AMD Dec 2001
ITRS 1999ITRS 2001
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The dramatic acceleration of the ITRS is due to the failure of The dramatic acceleration of the ITRS is due to the failure of conventional MOSFETs to meet the performance requirements.conventional MOSFETs to meet the performance requirements.
Context: where we are with Si and SiGe 2002
Brute force scaling of MOSFETS will not workIntel
Toshiba
Intel
RequiresToo thin oxideToo high doping
Results inHigh leakageGate oxide and band to band tunnelling Low performanceImpurity scattering limited mobilityIntrinsic parameter variationsRandom dopants and interfaces
The conventional MOSFET will need a replacement somewhere The conventional MOSFET will need a replacement somewhere between the 65 nm and the 45 nm technology nodes.between the 65 nm and the 45 nm technology nodes.POST CMOSPOST CMOS
10 nm
Too Hot
The IBM 6 nm silicon transistor (IEDM 2002)
demonstrated
New Post CMOS architecture solves problem
Context: where we are with Si and SiGe 2004
Research pushes MOSFET designs down to 4-5 nm
High K dielectric take-up is high(gate leakage stopped dead)
Some problems in old CMOS yield at 90 nm node IBM. Intel
Parallel track developing: Plan A-aggressive scalingPlan B-multi-core and otherarchitecture developmentsNoC/SoC
SiGe and strained silicon: Huge interest: definitely on board for coming generations
The Post CMOS Si developments have two mainstreams
New materials
SiGe, Ge, Strained Si
Lower effective massIncreased mobilityReduced scatteringHigher carrier velocityBallistic transport
Improves device performance compared to Si
New device architectures
UTB SOI, Multiple gates
Better electrostatic integrityReduced SCEImproved drivabilityRelatively thicker oxideBallistic transport
Allows scaling to nanometer dimensions
Members of the SiGe consortium have carried out pioneering work Members of the SiGe consortium have carried out pioneering work in these two mainstream areas.in these two mainstream areas.
High K: new issues
The Post CMOS devices are immensely complex from physics and technology point of view
10 nm DG MOSFET
Fin-FET Double-gate
SON UTB SOI
Omega-gate
SiGeStrained Si
Pure Ge
High-K
TiN
Metal gate Schottky S/D
Raised S/D
NiSi
Replacement gate
Quantum
Confinement
Tunnelling
Ballistic
Atomistic
Non-equilibrium
Silicon is once again an exciting area for research.Silicon is once again an exciting area for research.Huge challenge for device modellingHuge challenge for device modelling
Mobility in UTB SOI
Scattering from two interfacesSurface phononsTO phonons couplingRemote Coulomb scatteringInterface charge scatteringBody thickness fluctuationsMaterial composition fluctuationsHigh-k composition fluctuations
K. Ushida IEDM 02
Complexity associated with the simulation of thin body SOI MOSFETS
Quantum potential variationAssociated with UTB variation
Device quantum effects at room temperatureDevice quantum effects at room temperature
GateTunnelling
B-to-BTunnelling
S-to-DTunnelling
QuantumConfinement
And this is only one item from the list on the previous slide.And this is only one item from the list on the previous slide.
Quantum transport
Technology nodes 22 nmSOI30nm
0.25 2
Toshiba (2004)6 nm channel
5 nm wire FINFETTaiwan Semiconductor Manufacturing company
High-k
LETI/STM
SiGe(:C)
Motorola Univ. Texas
3D Atomistic Monte Carlo3D Non-equilibrium Green function atomistic simulator
3D NASA codes
MediciQuantum corrected Medici
Theory and Modelling:
Planned: atomic basis sets, DFT,Quantum corrected Monte CarloConvergence with quantum chemistry
Tools: unique to UKHelps understand the presentHelps design the futureUsed to iteratively design and model devices for Cons.
Two recent examples
High-κ dielectrics
• Scaling of MOSFETs beyond the 45nm technology node required by 2010 (ITRS) requires extremely thin SiO2 gate oxides (~0.7nm) resulting in intolerably high gate leakage.
• Maximise gate capacitance:
• The most likely solution is the implementation of high-κ dielectrics such as HfO2 and Al2O3 which are the leading contenders. However, there is a fundamental drawback due to the resulting mobility degradation.
Strained Si• Has already demonstrated significant enhancement for CMOS
applications. It is shown here that it can compensatefor the performance hit due to high k dielectric.
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Cox =εoxtox
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thigh−κ =κ high−κ
κ ox
⎛
⎝ ⎜
⎞
⎠ ⎟tSiO2
1.
Interface roughness (new non-perturbative model in excellent agreement with expt)
Gaussian auto-covariance
Exponential auto-covariance
Parameters: RMS height, 0.5nm and Correlation Length, c=3.0nmM. Boriçi, J. R. Watling, R. Wilkins, L. Yang and J. R. Barker, J. Comp. Electronics, 2 p163-167 (2004)
2.
Ab initio models
Full SC Quantum
Device Structures investigated
Impact of Surface Roughness Scattering
Comparison between n-type Strained Si and control Si MOSFETs:
• 67nm effective channel length• Similar processing and the
same doping conditions
In the strained Si MOSFET:• 10nm tensile strained Si layer• Strained Si on relaxed SiGe
(Ge content: 15%)
K.Rim, et. al., Symposium on VLSI Technology 2001http://www.research.ibm.com/resources/press/strainedsilicon/
Simulation of 67nm IBM Relaxed and Strained Si n-MOSFET
Strained Si n-channel MOSFET Structure
Comparison between the n-type Strained Si and control Si MOSFETs:• 67nm effective channel length• Similar processing and doping conditions• Oxide thickness, tox =2.2nm (SiO2)
For the strained Si MOSFET:• 10nm strained Si layer thickness• Strained Si on relaxed SiGe (Ge content: 15%)
SiGe n-MOSFET >35% drive current enhancement (70% high field mobility enhancement)
Universal Mobility Curve: Monte Carlo v Expt
‘universal’ mobility behaviors of bulk Si and strained Si, a comparison between experiment and Monte Carlo simulation.
A smoother interface
for strained Si?
Si SSi
RMS 0.5nm 0.5nm
CL 1.8nm 3.0nm
Device Calibration – Drift Diffusion
Drift-diffusion (MEDICI™) device simulations
• Concentration dependent, Caughy-Thomas and perpendicular field dependent mobility models
• Corrected Si/SiGe heterostructure parameters: band gap and band offsets, effective mass, DoS and permittivity†
Calibrated ID-VG characteristics of the 67nm n-type bulk Si and strained Si MOSFETs (experimental data from Rim VLSI’01)
† L. Yang, et al, ‘Si/SiGe Heterostructure Parameters for Device Simulations’, Semiconductor Science and Technology (2004)
Device Calibration – Monte Carlo
Calibrated ID-VG characteristics for 67nm conventional Si and strained MOSFETs, comparison with experimental data of Rim.
Larger CLFor SSiSmoother interfacePerformanceEnhancement
Problems associated with high-κ dielectrics
(1) Lower mobility (Soft optical phonon scattering)
(2) Micro crystal growth
(3) Lateral oxidation at gate edge
(4) Interfacial layer formation Fermi level pinning
(5) Fixed charge, Flatband shift
(6) Higher density of interface states
(7) Reliability
Iwai, ESSDERC’03 Atomic level modelling
Strong SO phonon scattering degrades the inversion layer carrier mobility within the MOSFET with high-κ gate stacks.
Adapted from: Hitachi IEDM 2003
Atomic level models needed
Remote (SO) Phonon Scattering
SO phonon scattering rate in the X-valley for phonon mode 1 (absorption) as a function of energy and the distance from interface (HfO2 EOT=2.2nm for bulk Si MOSFET)
The losses due to high k in Si are largely compensatedby switching to high k in strained silicon.
Monte Carlo simulations of Si MOSFET and SSi MOSFET with HfO2 oxide
See IEDM paper
Monte Carlo simulations of Si MOSFET, with Al2O3 oxide
ID-VG characteristics of 67nm n-type Si MOSFET, with and without soft-optical phonon scattering, from the Al2O3 oxide.
Note
SSi
Restores
Performancehit
Summary of high K results
• We have investigated the impact on the performance degradation in sub 100nm n-MOSFETs due to soft-optical phonon scattering in the presence of high-κ dielectrics HfO2 and Al2O3.
• A device current degradation of around 25% and 10% at VG-VT=1.0V and VD=1.2V is observed for conventional and strained Si devices with a 2.2nm EOT HfO2 or Al2O3 dielectric respectively.
• Results indicate that the performance degradation associated with high-κ gate stack MOSFETs can be compensated by the introduction of strained Si channels.
• The infancy of high-κ gate fabrication techniques means that overall performance degradation associated with high-κ gate dielectrics is expected to be worse than the predictions here.
More details in IEDM paper.
Nano-silicon and atomistic MOSFETs
New methodologies for the challenges ahead: planned or in hand.Convergence with Quantum Chemistry
Atomic basis functionsDensity Functional TheoryNon Equilibrium 3D Green Function codesQuantum corrected Monte CarloExtensions to quantum corrected drift diffusionConvergence with Quantum ChemistryBasis for exploring hybrid technologies andUltimately nano-molecular electronics.Huge range of new materials/device configs, withindustry looking for answers soon.
The next generation Post-CMOS devices are immensely complex from physics and technology point of view
10 nm DG MOSFET
Fin-FET Double-gate
SON UTB SOI
Omega-gate
SiGeStrained Si
Pure Ge
High-K
TiN
Metal gate Schottky S/D
Raised S/D
NiSi
Replacement gate
Quantum
Confinement
Tunnelling
Ballistic
Atomistic
Non-equilibrium
Silicon is once again an exciting area for research.Silicon is once again an exciting area for research.Huge challenge for device modellingHuge challenge for device modelling
Quantum simulations and Green Function Codes
Current flow comprises open orbits + localised vortices
Fluctuations indevice performance
Discovered at Glasgow, picked up by IBM, ASU
Exotic science discovered in advanced Si devices
10-25 nm
€
ωτ >1 ω =Nh
m * r2
Exact model and NEGFSimulations in 3D
Existence of vortices in total current at high T
Barker and Martinez 2004Decoherence studies in 3D
EPSRC has given the UK communitythe opportunity to stay in world-class competitionin the technology of the century.
But it will not be enough to continue to competein Europe, let alone the world.
Silicon technology of the type available to develop newapplications and systems is BIG ENGINEERING.
We need to shift away fromthe gentlemanly amateurism of the 1970s and 1980swhich saw us lose our world lead in semiconductors.
CONCLUSIONS: The future with silicon
The future with silicon
The UK cannot afford not to be in siliconIt will remain the platform technology for at least 20 yearsas scaling continues.
It will remain a platform for maybe >20 years beyond, by supporting System on Chip,Network on Chip, Comms on chip, Lab on chip, Smart dust,Nanorobotics, Med.Diagnostic on Chip, Nanotechnology,Hybrid organic/plastic silicon/Some questions and observationsCan you name any replacement technology?Remember: it is not good enough to demonstrate a transistoror even two. Can you demonstrate any path to fabricating1000000000000 transistors, precisely, at low cost in 16 mm2
and repeat this for 16000000000 chips?
The future with silicon
What opposition? Does exotic science gave any solitions?
Single Electronics: no gain, RC time constant limited,very slowSensitive to local fluctuations. Compensating circuitry outweighs SET circuitry at 256 M level.No fabrication strategy.
Nanotubes: Millie Dresselhaus let the cat out of the bag in ICPS27. Every CNT has its own name: they are all different and massively sensitive to contaminants. There is absolutely no interconnection strategy, no fabrication strategy.
Even magnetic bubble logic was better advanced.Don’t believe the hype!
Spintronics: similar issues to single electronics. Also scales.
Wave interference devices: in your dreams!You need 30000 electrons just to resolve a 2 slit experiment.Scale, coherence/de-coherence. The interface between macroMicro system…… Already dismissed in the 1980s.
Molecular electronics: most simple molecules are already thescale of 5 nm MOSFETs. Huge problems of fabrication and Interconnection. Absolutely no assembly method demonstrated,Unless you count DNA replication (error rate 10-5!!). 3D might just be an advantage; likely to be very slow.Nice non-competitive apps: still need to interface to silicon.
Biological devices: surely not neurons or biomachines!!
The future with silicon
The future with silicon
III-V MOSFETs: the window of opportunity is narrowing. At the smallest scales there is no advantage. But could integrate with silicon or germanium.
(IBM, IWCE04)
Silicon and SiGe are already encroaching on III-Vs for RF
Quantum Computing: the idea of several bits on one electron and the mystical advantages of QC fascinates a lot of people. Ask them what real advantages it has over analogue computing? Do you really expect to control coherence/entanglement etc at room temperature?
DNA computers: fascinating demos. Totally ludicrous asengineering. If you want more emergent technologies that will replace Si
Remember the characteristic of Pseudo-Science
The future with silicon
How many more times does the UK have to get it wrong inElectronics? The issue is primarily engineering.
Remember: BabbageMalvern 3D ICs in 1950s 1960s;GaAs, III-Vs, InP, Bubble logic, Gunn logic, Resonant tunneldevices, High Tc and Low Tc superconducting systems,…….
So, you whine….” It is in the Road Map;All the new stuff you disparage is IN THE ROAD MAP.”
“..and the non Silicon Physics community says that silicon is dead!”
The future with silicon
Let me tell you about the reality of the Road Map.
It is supposed to be a wish list of problems to solve in order tocontinue Moores Law. It waswas originally.
Now manufacturers lower the targets, so that they triumphantlybeat the Road Map. Usually each year at IEDM.Remember the HEAT DEATH of NMOS ? We got CMOS.Remember the recent HEAT DEATH scares of CMOS?Lots of solutions: raised S/D, Si on insulator, high k dielectrics, …What about the new emergent technology section?Mostly pie in the sky. This is where the gurus play.It is also cool for investors to know that your favourite companyinvests in the future. But test it: you are scientists: how much are they actually spending? Eg look at Intels CNT investment.
The future with silicon
Most involve new science tightly integrated with new engineering.Of course there are limits. But not to applicable electronics.
We will still want low cost super-functionality from future chips.But they will not just be memories and CPUs. New materials, new devices will be hybridised and developedusing that special economic advantage of silicon:
the cost per function is likely to fall even as the functionality increases and diversifies.
The next decades should be periods of great invention.We will need access to silicon fabrication to explore newinventions. Off the shelf is simply not good enough.
Of course there are problems, but there is a surfeit of routes forward
The industry needs help in the development of the next generations devices
University research is bound to play an important role in the University research is bound to play an important role in the Nano-CMOS era. Nano-CMOS era.
The ex members of the SiGe consortium are particularly well placed The ex members of the SiGe consortium are particularly well placed due to pioneering research in materials, device physics and design, due to pioneering research in materials, device physics and design, semiconductor theory and modelling and Si fabricationsemiconductor theory and modelling and Si fabrication
The technology is so complex that even the large multinationals can not afford to develop it alone (groupings for developing 65 nm node).
During the downturn the multinationals downsized their basic research capabilities and cannot deal with some of the material, device physics and modelling issues.
The companies are therefore ready to forge new relations with universities and to offer not only financial contribution but access to technologies and devices.
Strong alliances has been developed in the European scene in Framework 6 including members of the consortium (SINANO, NanoCMOS).
Not the end…
New beginnings!!