Post on 31-Dec-2015
1
Numerical Simulation of Electronic Noise
in Si MOSFETs
C. Jungemann
Institute for ElectronicsBundeswehr University
Munich, Germany
Acknowledgments: B. Neinhüs, B. Meinerzhagen, A. Scholten, A. Heringa
EIT4
2
Outline
• Introduction
• Theory
• Acceleration Effects
• Noise source modeling
• Noise in NMOSFETs
• Noise in a BJT
• Noise in an IMOS
• Conclusions
3
Introduction
4
Introduction
• Noise is a fundamental property of electron transport and cannot be avoided
• Fluctuation-dissipation theorems (e.g.: Nyquist theorem) are only valid at equilibrium (Shot and thermal noise are macroscopic manifestations of microscopic noise.)
• Transport in nanoscale devices is nonlocal and quasi-ballistic
Physics-based methods required for device level simulations!
5
Introduction
• Terminal current fluctuations are due to electron scattering within the device via displacement and conduction currents
• Noise theory describes the variance and the correlation of the fluctuations
NN++NNNN++ structure at zero bias structure at zero bias
5*105*101717 2*102*101515 5*105*101717
6
Introduction
• PSD vanishes at very high frequencies due to acceleration effects (finite electron mass means no real white noise)
• nonquasistationary• Plasma resonance at
very high frequencies (>1THz) in silicon
Power spectral density (PSD)Power spectral density (PSD)
detItIES tiII )()(2
7
Theory
8
Theory
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LBE is the basis for LHD and LDD modelsLBE is the basis for LHD and LDD models
9
Theory
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10
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11
Theory
• Transport and noise parameters of the LDD are calculated consistently under homogeneous bulk conditions based on the single particle LBE
• The parameters are generated for a wide range of doping concentrations, lattice temperatures, strain conditions, driving fields etc, and stored in lookup tables for later use.
12
Impact of the Acceleration Term
13
Acceleration Effects
In the DD approximation the mobility and the PSD of the In the DD approximation the mobility and the PSD of the velocity fluctuations are assumed to be frequency independentvelocity fluctuations are assumed to be frequency independent
Up to about 100GHz this is correct for siliconUp to about 100GHz this is correct for siliconThe macroscopic relaxation time approximation failsThe macroscopic relaxation time approximation fails
NNdopdop=10=101717/cm/cm33
14
Acceleration Effects
NN++NNNN++ structure (Full LBE) structure (Full LBE)
Up to about 100GHz acceleration effects Up to about 100GHz acceleration effects can be neglected in siliconcan be neglected in silicon
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Acceleration Effects
Undoped silicon at room temperatureUndoped silicon at room temperatureE(t) = 30kV/cm[1+cos(2E(t) = 30kV/cm[1+cos(2ft)]ft)]
Above 100GHz nonquasistationary effects occur in siliconAbove 100GHz nonquasistationary effects occur in silicon
16
Noise source modeling
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Noise source modelingNN++NNNN++ structure structure
Diffusion noise source yields the best resultsDiffusion noise source yields the best resultsHD model yields similar good resultsHD model yields similar good results
Device results strongly deviate from thermal or shot noiseDevice results strongly deviate from thermal or shot noise
Bulk, NBulk, NDD=10=101717/cm/cm33
18
Noise source modeling
NN++NNNN++ structure biased at 6V structure biased at 6V
Generation noise due to impact ionizationGeneration noise due to impact ionizationNoise source is given by microscopic white shot noiseNoise source is given by microscopic white shot noise
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Noise source modeling
NN++NNNN++ structure biased at 0 and 1V structure biased at 0 and 1V
Terminal current noise is due to cold and warm electronsTerminal current noise is due to cold and warm electronsHot electrons can produce noise via impact ionizationHot electrons can produce noise via impact ionization
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Noise in NMOSFETs
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Noise in NMOSFETs
Measurements and Tsuprem simulations by Philips (A. Scholten)Measurements and Tsuprem simulations by Philips (A. Scholten)Simulation includes quantum correction for channelSimulation includes quantum correction for channel
DD and HD simulations performed without any parameter matchingDD and HD simulations performed without any parameter matching
180nm Technology, t180nm Technology, toxox = 3nm, V = 3nm, Vdraindrain = 1.8V, f=2.5GHz = 1.8V, f=2.5GHz
Lgate=1m
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Noise in NMOSFETs
Also in MOSFETs drain noise is not due to hot electronsAlso in MOSFETs drain noise is not due to hot electrons
180nm gate length, t180nm gate length, toxox = 3nm, V = 3nm, Vdraindrain = 1.8V, V = 1.8V, Vgategate=1.0V=1.0V
Gate noiseDrain noiseDrain noise
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Noise in NMOSFETs
50nm channel length, 1.3nm oxide, V50nm channel length, 1.3nm oxide, Vdraindrain=0.9V, f=10GHz=0.9V, f=10GHz
Noise specs of small Noise specs of small NMOSFETs increase NMOSFETs increase
only moderatelyonly moderately
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Noise in a BJT
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Noise in a BJT
Overestimation of shot noise is caused by model failure Overestimation of shot noise is caused by model failure
1D 50nm Si NPN bipolar transistor1D 50nm Si NPN bipolar transistor
Fano factor of electron collector noise at VCE=0.5V
Doping profileDoping profile
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Noise in a BJT
Quasiballistic transport leads to model failureQuasiballistic transport leads to model failure
50nm Si bipolar transistor50nm Si bipolar transistor
VCE=0.5V, VBE=0.65V
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Noise in an IMOS
F. Mayer et al., TED, Vol. 53, p. 1852, 2006F. Mayer et al., TED, Vol. 53, p. 1852, 2006
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Noise in an IMOS
CMOS has a Fano factor of less than one for inversionCMOS has a Fano factor of less than one for inversionIMOS generates two or more orders of magnitude more noiseIMOS generates two or more orders of magnitude more noise
CIMPAT, VCIMPAT, Vgate/draingate/drain=-3.5V, L=-3.5V, Lchannelchannel=5.0=5.0mm
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Conclusions
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Conclusions
• Consistent hierarchy of noise models (DD, HD, LBE)
• Transport and noise parameters are consistently generated for the DD and HD models by LBE bulk simulations
• The transport and noise parameters are local in real space and frequency independent
• Acceleration effects can be neglected below 100GHz in silicon
• Modified noise sources (diffusion noise) give good results
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Conclusions
• Good agreement of measurements and simulations for MOSFETs
• Terminal current noise is produced by cold or warm electrons
• Hot electrons can produce noise via impact ionization
• No dramatic increase of noise in scaled MOSFETs
• IMOS suffers from huge noise due to avalanche breakdown