Beyond-CMOS Device Concepts Enabled by 2D...
Transcript of Beyond-CMOS Device Concepts Enabled by 2D...
Beyond-CMOS Device Concepts Enabled by 2D Materials
April 23, 2015 Thomas N Theis
Executive Director
SRC Nanoelectronics Research Initiative
Working Dinner Remarks at NSF US – EU Workshop on 2D Materials
Topics
Why semiconductor manufacturers are investing in “beyond-CMOS” device research
NRI and STARnet – private-public partnerships funding university research
Some new device concepts enabled by 2D materials.
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Computer clock frequencies have been stagnant since 2003.
3 http://www.gotw.ca/publications/concurrency-ddj.htm
Clock Frequency (flat since 2003)
Transistor Count (still growing)
Architectural Innovation (ILP)
(also flagging!)
Power (flat since 2003)
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For charge transport controlled by thermal emission over a barrier, the leakage
current is an exponential function of the voltage swing; I ~ exp[-ys(e/kT)]
This determines the maximum nonlinearity of the switch, which determines the minimum allowable voltage swing, which determines the minimum power dissipation. (Active power ~ V2.)
Log Current
Voltage
Sub-threshold Slope
Ion
Ioff
Vdd 0
En
erg
y
distance
With voltage swing already reduced to ~ 1V, The FET is close to its
fundamental voltage limit for operation at ambient temperatures.
The FET has reached its voltage scaling limit.
Briefly summarizing the last 10 years…
To keep areal power density and total power within economically acceptable limits, industry froze clock speed and slowed the deployment of multiple cores.
To escape this new status quo, we’ve begun to explore devices with switching mechanisms that are fundamentally different from that of the conventional FET, and architectures than are fundamentally different from the von Neumann architecture.
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University research funded by industry and government in recent years has given us a
broader picture of what is possible.
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The Nanoelectronics Research Initiative
Founded in 2005, NRI is a consortium of leading semiconductor companies (IBM, Intel, Micron, and Texas Instruments) working with the National Science Foundation (NSF) and the National Institute of Standards and Technology (NIST) to collaboratively fund university research.
Three multidisciplinary, multi-university research centers
Twelve Nanoelectronics for Beyond 2020 (NEB2020) projects
NRI’s Mission: Demonstrate non-conventional, low-energy technologies for computation which can outperform CMOS on critical applications in ten years and beyond.
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NRI Research Centers In Partnership with NIST
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INDEX Michael Liehr, Executive Director The mission of INDEX is to discover and demonstrate nanoscale computing devices to extend Moore’s law beyond CMOS limits, organized around spin and graphene p-n junction logic devices and implemented in an advanced semiconducting fabrication facility.
8 Universities
SWAN Sanjay Banerjee, Director The South West Academy for Nanoelectronics seeks to develop ultra-low power transistors based on novel single particle and collective tunneling effects in 2D materials such as graphene and transition metal dichalcogenides, as well as magnetoelectric switching on topological insulators.
7 Universities
SRC Executive Director: Thomas N. Theis
CNFD Evgeny Tsymbal, Director The mission of CNFD is to develop low-energy memory and logic devices based on materials, structures, and phenomena non-traditional for existing technologies, such as magnetoelectricity, ferroelectricity, and spin dynamics, to advance the information technology beyond current limits.
6 Universities
NEB2020 Projects Co-funding 12 Projects at 12 NSF Centers
Pittsburgh Scalable Sensing, Storage and Computation with a Rewritable Oxide Nanoelectronics
Platform
MIT Integrated Biological and Electronic Computation at the Nanoscale
UC-Riverside Developing a Graphene Spin Computer: Materials, Nano-Devices, Modeling, and Circuits
Drexel Meta-Capacitance and Spatially Periodic Electronic Excitation Devices (MC-SPEEDs)
Virginia Commonwealth Hybrid Spintronics and Straintronics: Technology for Ultra-Low Energy Computing and Signal
Processing Beyond 2020
UC-Riverside Charge-Density-Wave Computational Fabric: New State Variables and Alternative Material
Implementation
Cornell Ultimate Electronic Device Scaling Using Structurally Precise Graphene Nanoribbons
Notre Dame Nanoelectronics with Mixed-valence Molecular QCA
Minnesota Scalable Perpendicular All-Spin Non-Volatile Logic Devices and Circuits with Hybrid
Interconnection
Notre Dame Physics-Inspired Non-Boolean Computation based on Spatial- Temporal Wave Excitations
Columbia Novel Quantum Switches Using Heterogeneous Atomically Layered Nanostructures
UC-Santa Barbara Superlattice-FETs, Gamma-L-FETs, and Tunnel-FETs: Materials, Devices and Circuits for
Fast Ultra-Lower-Power ICs
A Fruitful Partnership with NSF
2006-2010: Annual partnership for joint funding of projects at NSF Nanoscience Centers (NSECs/MRSECs/NCN)
2011: Launched 12 NRI-NSF NEB2020 projects.
NRI-NSF exploratory programs are feeding the more-focused center programs in NRI and STARnet.
Prof. Evgeny Tsymbal, funded through former MRSEC grant, now Director, NRI CNFD center.
Prof. Jian-Ping Wang, funded through NEB2020 since 2012, now Director, STARnet C-SPIN center.
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Growing Research Investment
Since 2013, NRI has been joined in the focused exploration of beyond-CMOS devices, by the former Focus Center Research Program, completely refreshed as STARnet.
Jointly funded by Globalfoundries, IBM, Intel, Micron, Raytheon, TI, United Technologies, and DARPA.
Funding six multidisciplinary, multi-university centers
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STARnet Research Centers In Partnership with DARPA
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Applied Materials
Novellus
FAME Jane Pei-Chen Chang, Director The mission of FAME is to create and investigate new nonconventional atomic scale engineered materials and structures of multi-function oxides, metals and semiconductors to accelerate innovations in analog, logic and memory devices for revolutionary impact on the semiconductor and defense industries.
TerraSwarm Edward A. Lee, Director
The TerraSwarm Research Center aims to enable the simple, reliable, and secure deployment of a multiplicity of advanced distributed sense control-actuate applications on shared, massively distributed, heterogeneous, and mostly uncoordinated swarm platforms through an open and universal systems architecture.
C-SPIN Jian-Ping Wang, Director The Center for Spintronic Materials, Interfaces and Novel Architectures (C-SPIN) seeks to overcome barriers to realizing practical spin-based memory and logic technology by assembling experts in magnetic materials, spin transport, novel spin-transport materials, spintronic devices, circuits, and novel architectures.
SONIC Naresh Shanbhag, Director SONIC will be guided by the following mission: To enable equivalent scaling in beyond-CMOS nanoscale fabrics by embracing their statistical attributes within statistical-inference-based applications, architectures, and circuits, to achieve unprecedented levels of robustness and energy efficiency.
LEAST Alan Seabaugh, Director
The Center for Low Energy Systems Technology (LEAST) explores the physics of new materials and devices to enable more energy-efficient integrated circuits and systems.
C-FAR Todd Austin, Director
The center's research agenda is guided by three initial technical vectors, whose intersections will help realize non-conventional architectures that address these pressing challenges: data-centric architectures, novel architectures based on emerging technologies, and beyond homogenous parallelism.
16 Universities 10 Universities
15 Universities
8 Universities 14 Universities
10 Universities
SRC Executive Director: Gilroy Vandentop
Beyond-CMOS Devices
New Architectures
What are the prospects for these devices?
How can we compare them to each other and to CMOS?
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NRI Device Performance Benchmarking
Goals:
Enable concise communication of research outcomes.
Focus researcher’s attention on key technical challenges.
Spark invention.
Practices and methodology developed across four NRI centers by university PIs led by K. Bernstein
K. Bernstein et al., Proc. IEEE 98, 2169 (2010).
Comprehensive assessments with uniform engineering assumptions applied to all devices, led by I. Young and D. Nikonov
D.E. Nikonov and I.A. Young, IEEE IEDM, pp. 573-576, Dec. 2012; Proc. IEEE, vol. 101, no. 12, pp. 2498-2533, Dec. 2013; IEEE J. Exploratory Sold-State Computational Devices and Circuits, DOI 10.1109/JXCDC.2015.2418033, to be published.
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Delay, ps
D. Nikonov and I. Young, IEEE J. Exploratory Solid-State Computational Devices and Circuits, DOI 10.1109/JXCDC.2015.2418033,
to be published.
Benchmarking Example: Energy vs. Delay for 32 Bit Adder
CMOS ref
Electronic
Spintronic
Ferroelectric
Orbitronic
Straintronic
D. Nikonov and I.Young, IEEE J. Exp. Solid-State Computational Devices and Circuits, to be published
D. Nikonov and I.Young, Proc. IEDM, Dec. 2012
Electronic
STTtriad
GpnJ
SpinFET CMOS HP
HJTFET
IIIvTFET
gnrTFET
CMOS LP
ASLD
STMG
SWD
Spin torque
Magnetoelectric
NML
Delay, ps
D. Nikonov and I. Young, IEEE J. Exploratory Solid-State Computational Devices and Circuits, DOI 10.1109/JXCDC.2015.2418033,
to be published.
Benchmarking Example: Energy vs. Delay for 32 Bit Adder (2012 results)
CMOS ref
Electronic
Spintronic
Ferroelectric
Orbitronic
Straintronic
D. Nikonov and I.Young, IEEE J. Exp. Solid-State Computational Devices and Circuits, to be published
D. Nikonov and I.Young, Proc. IEDM, Dec. 2012
Electronic
STTtriad
GpnJ
SpinFET CMOS HP
HJTFET
IIIvTFET
gnrTFET
CMOS LP
ASLD
STMG
SWD
Spin torque
Magnetoelectric
NML
Delay, ps
D. Nikonov and I. Young, IEEE J. Exploratory Solid-State Computational Devices and Circuits, DOI 10.1109/JXCDC.2015.2418033,
to be published.
Benchmarking Example: Energy vs. Delay for 32 Bit Adder (2014 results)
CMOS ref
Electronic
Spintronic
Ferroelectric
Orbitronic
Straintronic
Takeaways from 2012 – 2014 Comparison
As device models improve, estimates of device attributes tend to become more conservative (and more accurate).
While no clear winner has emerged, the number of device concepts benchmarked as competitive with CMOS has increased.
New device concepts continue to emerge, suggesting that more (perhaps many more) are yet to be invented.
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The Band-to-Band Tunnel-FET
Operating principle of a tunnel field-effect transistor, after Appenzeller:
Bands are crossed in the ‘on’ state and uncrossed by the gate voltage in the
‘off’ state.
TFET Performance Prediction (100x performance advantage at low voltage)
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Heterojunction TFET Scaling and Resonant-TFET for Steep Subthreshold Slope at sub-9nm Gate-Length, IEDM 2013, U. Avci and I. Young (Intel Corp.)
I-V curves for nanowire resonant TFET, heterojunction TFET, and MOSFET; all at Lg = 9 nm, VDD = 0.27 V
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Schematic representation of various topologies of TFETs, from
Debdeep Jena, Proceedings of the IEEE, Vol. 101, No. 7, p. 1586 July 2013
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The TFET concept is still rapidly evolving. 2D materials and device structures
Can a low-voltage device be fast?
100x faster than CMOS at 0.27V is still slow!
Newer low-voltage device concepts, now being explored, may enable faster devices, perhaps ultimately exceeding what is possible with the silicon FET.
TFETS based on two-dimensional (2D) materials
Graphene p-n Junction Device (NRI INDEX center) R. Sajjad and A. Ghosh, arXiv:1305.7171 (2013)
Piezoelectronic Transistor (DARPA Mesodynamics) D.M. Newns, et al., J. Appl. Phys. 111, 084509 (2012)
… and more …
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Graphene p-n Junction (GPNJ) Device A new steep slope device
Redwan Sajjad and Avik Ghosh, ACS Nano, Vol. 7, No. 11, pp. 9808–9813, 2013
1. Mobility unaffected
2. High ON current
3. High ON-OFF ratio with steep change in current
Gate engineering to orthogonalize transmissions and turn OFF graphene
Another Example: IBM’s Piezotronic Transistor (PET)
Operating Principle:
A voltage, Vg placed across a piezoelectric (PE) expands the film.
In a mechanically clamped structure, the resulting pressure drives an
insulator metal transition in a piezoresistive (PR) film, allowing a
current to flow.
The area ratio aPR/APE << 1 steps up the pressure in the PR.
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Mechanical
Clamp
(High-Yield-
Strength
Material)
D.M. Newns et al., J. Appl. Phys. 111, 084509 (2012)
How will 2D materials impact nanoelectronics?
Ultra-thin channels for otherwise conventional FETs?
Probably not for high performance devices.
Computational modeling by various groups suggests at best a limited benefit.
Minimum channel length will be limited more by insulator thickness than by channel thickness.
Application in flexible electronics, sensors, etc. seems more likely.
Enabling new device concepts?
Perhaps. A steep slope device with FET-like drive current at ~0.1 V
supply would be truly revolutionary!
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Conclusion
Please continue to explore the fundamental materials science, and the many new device structures and concepts made possible by 2D materials.
But for real impact, we’ll need …
scalable, self-limiting, and selective processes for growth of single crystals and aligned heterostructures.
patterning processes for nm-scale lateral features
vastly improved control of point defects
and more …
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Thanks for your attention!