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Carbon Nanotube Technology An Alternative in Future SRAM memories UPC CASTNESS’11 WORKSHOP ON TERACOMP FET Projects, Rome , January 17 th -18 th 2011
Carbon Nanotube Technology An Alternative in Future SRAM memories
UPC
CASTNESS’11 WORKSHOP ON TERACOMP FET Projects, Rome , January 17 th-18th 2011
Introduction
CASTNESS’11 WORKSHOP ON TERACOMP FET Projects, Rome , January 17 th-18th 2011
• OBJECTIVE: to evaluate the variability in Carbon nanotube Field Effect Transistor (CNFET) as well as its real capability to be a promising alternative to Si-CMOS technology.
1. Impact of carbon nanotube (CNT) diameter variations and the presence of metallic CNTs in the transistor (device level).
2. Comparison between Si-CMOS and CNFET 6T SRAM cells (circuit level).
• In Si-bulk CMOS technology the variability of the device parameters is a key drawback and it may be a limiting factor for further miniaturizing nodes.
CASTNESS’11 WORKSHOP ON TERACOMP FET Projects, Rome , January 17 th-18th 2011
Carbon Nanotubes (CNTs)
Graphene
Carbon nanotube
Metallic
Semiconducting
Diameter Behaviour
Rest of
Rest of
Chiral vector
angle of the atom arrangement along the tube
Device level
CASTNESS’11 WORKSHOP ON TERACOMP FET Projects, Rome , January 17 th-18th 2011
Carbon Nanotube Field Effect Transistors (CNFETs)An “Ideal” MOSFET-like CNFET is formed by 1 or more semiconducting
CNTs perfectly aligned and well-positioned whose section under the gate is intrinsic and the s/d extension regions are n/p doped.
Promising candidates to replace silicon CMOS due to its high performance
There are some imperfections inherent to CNT synthesis and CNFET manufacturing process that
may eclipse the expectations
Device level
SOURCES OF VARIATION
CNT growth process CNFET manufacturing process
• Percentage of m-CNTs• Diameter variations
• S/D doping variations• Mispositioned and misaligned CNTs
NO control of chirality
CASTNESS’11 WORKSHOP ON TERACOMP FET Projects, Rome , January 17 th-18th 2011
Metallic CNTs
Semiconducting CNTs
Device level
CASTNESS’11 WORKSHOP ON TERACOMP FET Projects, Rome , January 17 th-18th 2011
CNFET device model [1]
[1] J. Deng and H.-S. Wong, “A compact spice model for carbon-nanotube field-effect transistors including nonidealities and its application part II: Full device model and circuit performance benchmarking,” Electron Devices, IEEE Transactions on, vol. 54, no. 12, pp. 3195–3205, 2007.
Device level
CASTNESS’11 WORKSHOP ON TERACOMP FET Projects, Rome , January 17 th-18th 2011
Monte Carlo experiment
Example of IDS − VDS distribution for 50 CNFET samples.
Device level
CASTNESS’11 WORKSHOP ON TERACOMP FET Projects, Rome , January 17 th-18th 2011
STD (σ) of VTH and K
Percentage of variation (100x3σ/μ)
Device level
CASTNESS’11 WORKSHOP ON TERACOMP FET Projects, Rome , January 17 th-18th 2011
Variability analysis and performance in CMOS and CNFET SRAM 6T cells
Circuit level
CASTNESS’11 WORKSHOP ON TERACOMP FET Projects, Rome , January 17 th-18th 2011
Circuit level
CNFET SRAM cell versus Si-MOSFET SRAM cell (nominal comparison)
CASTNESS’11 WORKSHOP ON TERACOMP FET Projects, Rome , January 17 th-18th 2011
Circuit level
CNFET SRAM cell versus Si-MOSFET SRAM cell (variability comparison)
CASTNESS’11 WORKSHOP ON TERACOMP FET Projects, Rome , January 17 th-18th 2011
Circuit level
CNFET SRAM cell versus Si-MOSFET SRAM cell (variability comparison)
CASTNESS’11 WORKSHOP ON TERACOMP FET Projects, Rome , January 17 th-18th 2011
Circuit level
CNFET SRAM cell versus Si-MOSFET SRAM cell (variability comparison)
CASTNESS’11 WORKSHOP ON TERACOMP FET Projects, Rome , January 17 th-18th 2011
Device level
Conclusions
• CNFETs are promising candidates to replace Si-MOSFETs due to their high current driving capability, tolerance to temperature and low leakage currents.
• Manufacturing variability, that is one of the key limiting factors in silicon-MOS technology, has been investigated for such CNFET devices.
• Considering a range of metallic tubes from 33% (current growth methods) to 0% (perfection) and a realistic distribution of diameters, it has been shown that the variability of both K factor and VTH is lower than CMOS for transistors with just 8 nanotubes, and much better for 12 tubes.
• In a future scenario with a narrower distribution of CNT diameters, variation for both parameters could reach levels from 15% to 25%, fact that would allow a design procedure without the stress caused by variability in current conventional technology.
CASTNESS’11 WORKSHOP ON TERACOMP FET Projects, Rome , January 17 th-18th 2011
Circuit level
Conclusions
• CNFETs can be also considered as a potential alternative to CMOS in memory systems.
• CNT technology presents better performance than CMOS technologies. However the implementation maturity of CNFET is still pending of several years of development.
• Variability analysis shows as a promising prospect, that even for todays CNFETs performance, its variability is comparable with that of Si-MOS technology in a scenario which we have called ”moderated”.
• Therefore, improvements in the control of chirality, the variability of CNFETs could be lower than in that moderated scenario.
Thanks for your attention!
CASTNESS’11 WORKSHOP ON TERACOMP FET Projects, Rome , January 17 th-18th 2011
CASTNESS’11 WORKSHOP ON TERACOMP FET Projects, Rome , January 17 th-18th 2011
Carbon Nanotubes (CNTs)
Graphene
Carbon nanotube Diameter & VTH
Device level
CASTNESS’11 WORKSHOP ON TERACOMP FET Projects, Rome , January 17 th-18th 2011
Mean (μ) of VTH and K
• Mean of Vth as Tm • Mean of Vth as N
• Mean of K as Tm
• Mean of K as N
Device level
