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Title: Transport in nanowire MOSFETs: influence of the bandstructure


1
Transport in nanowire MOSFETs influence of the
band-structure
M. Bescond IMEP CNRS INPG (MINATEC),
Grenoble, France Collaborations N. Cavassilas,
K. Nehari, M. Lannoo L2MP CNRS, Marseille,
France A. Martinez, A. Asenov University of
Glasgow, United Kingdom SINANO Workshop,
Montreux 22nd of September
2
Outline
  • Motivation improve the device performances
  • Gate-all-around MOSFET materials and
    orientations
  • Ballistic transport within the Greens functions
  • Tight-binding description of nanowires
  • Conclusion

2
3
Towards the nanoscale MOSFETs
  • Scaling of the transistors

? New device architectures
? Improve potential control
? Gate-all-around MOSFET1 Increasing the number
of gates offers a better control of the potential
? New materials and orientations
? Improve carrier mobility
  • Ge, GaAs can have a higher mobility than silicon
    (depends on channel orientation).
  • Effective masses in the confined directions
    determine the lowest band.
  • Effective mass along the transport determines
    the tunnelling current.

1M. Bescond et al., IEDM Tech. Digest, p. 617
(2004).
3
4
  • 3D Emerging architectures
  • 3D simulations The gate-all-around MOSFET

5
Gate-All-Around (GAA) MOSFETs
TSiWSi4nm TOX1nm
  • Source and drain regions N-doping of 1020 cm-3.
  • Dimensions L9 nm, WSi4 nm, and TSi4 nm,
    TOX1 nm.
  • Intrinsic channel.

5
6
3D Mode-Space Approach
? The 3D Schrödinger 2D (confinement) 1D
( transport)
1D (transport)
2D (confinement)
  • 3D Problem N?1D Problems ? Saving of the
    computational cost!!!!
  • Hypothesis ?n,i is constant along the
    transport axis.

J. Wang et al., J. Appl. Phys. 96, 2192 (2004).
6
7
Different Materials and Crystallographic
Orientations
8
Different Materials and Orientations
?

Effective Mass Tensor (EMT)
Ellipsoid coordinate system (kL, kT1, kT2)
Device coordinate system (X, Y, Z)
?

? Rotation Matrices
8
9
Theoretical Aspects
  • 3D Schrödinger equation

Potential energy
H3D 3D device Hamiltonian
Coupling
F. Stern et al., Phys. Rev. 163, 816 (1967).
9
10
Theoretical Aspects
  • The transport direction X is decoupled from the
    cross-section in the 3D Schrödinger equation

Coupling
  • Where E is given by
  • mtrans is the mass along the transport direction
  • M. Bescond et al., Proc. ULIS Workshop, Grenoble,
    p.73, April 20th-21st 2006.
  • M. Bescond et al. JAP, submitted, 2006.

10
11
3D Mode-Space Approach
? The 3D Schrödinger 2D (confinement) 1D
( transport)
1D (transport)
2D (confinement)
  • Resolution of the 2D Schrödinger equation in the
    cross-section mYY, mZZ, mYZ.
  • Resolution of the 1D Schrödinger equation along
    the transport axis mtrans.

11
12
Semiconductor conduction band
  • Three types of conduction band minima

Electron Energy
  • ? (ellipsoidal) ml?mt ? non diagonal EMT
  • ? (ellipsoidal) ml?mt ? non diagonal EMT

E? E? E?
  • ? (spherical) mlmt ? diagonal EMT

? ? ?
?-valleys
12
13
Results effective masses
  • Wafer orientation lt010gt

13
14
Material Ge
  • Square cross-section 4?4 nm, lt100gt oriented wire

mYY0.2m0 mZZ0.95m0 mtrans0.2m0
Z
?4-valleys
1st
2nd
mYY0.117m0 mZZ0.117m0 mYZ-11/(0.25m0)
mtrans0.6m0
6 nm
?-valleys
Free electron mass
? Non-diagonal terms in the effective mass tensor
couple the transverse directions in the ?-valleys
14
15
Material Ge
  • Square cross-section T?T5?5 nm, lt100gt oriented
    wire
  • Total current is mainly defined by the
    electronic transport through the ?-valleys
    (?bulk)
  • Tunneling component negligible due to the value
    of mtrans in the ?-valleys (0.6m0)

15
16
Material Ge
  • Square cross-section 4?4 nm, lt100gt oriented wire

?4-valleys mYY0.2m0, mZZ0.95m0
?-valleys mYY0.117m0, mZZ0.117m0
? The ?4 become the energetically lowest valleys
due to the transverse confinement
16
17
Material Ge
?4-valleys mtrans0.2m0 versus
?-valleys mtrans0.6m0
? The total current increases by decreasing the
cross-section!
M. Bescond et al., IEDM Tech. Digest, p. 533
(2005).
17
18
  • 3D Emerging architectures
  • Influence of the Band structure Silicon

19
Why?
  • Scaling the transistor size
  • devices nanostructures
  • Electrical properties depend on
  • Band-bap.
  • Curvature of the bandstructure effective
    masses.
  • Atomistic simulations are needed1,2.
  • Aim of this work describe the bandstructure
    properties of Si and Ge nanowires.

1J. Wang et al. IEDM Tech. Dig., p. 537 (2005).
19
2K. Nehari et al. Solid-State Electron. 50, 716
(2006).
20
Tight-Binding method Band structure calculation
  • Concept Develop the wave function of the system
    into a set of atomic orbitals.
  • sp3 tight-binding model 4 orbitals/atom 1 s 3
    p
  • Interactions with the third neighbors.
  • Three center integrals.
  • Spin-orbit coupling.

3rd (12)
2nd (12)
Diamond structure
1st (4)
Reference
20
21
Tight-Binding method Band structure calculation
  • 20 different coupling terms for Ge
  • Coupling terms between atomic orbitals are
    adjusted to give the correct band structure
    semi-empirical method.

Y.M. Niquet et al. Phys. Rev. B, 62
(8)5109-5116, (2000).
21
Y.M. Niquet et al., Appl. Phys. Lett. 77, 1182
(2000).
22
Simulated device Si Nanowire Gate-All-Around
transistor
Silicon
Hydrogen
Schematic view of a Si nanowire MOSFET with a
surrounding gate electrode. Electron transport is
assumed to be one-dimensional in the x-direction.
The dimensions of the Si atomic cluster under the
gate electrode is TSix(WTSi)xLG.
22
23
Energy dispersion relations
  • In the bulk
  • The minimum of the conduction band is the DELTA
    valleys defined by six degenerated anisotropic
    bands.

? Constant energy surfaces are six ellipsoids
23
24
Energy dispersion relations
T2.72 nm
T5.15 nm
T1.36 nm
  • Energy dispersion relations for the Silicon
    conduction band calculated with sp3 tight-binding
    model.
  • The wires are infinite in the 100 x-direction.
  • Direct bandgap semiconductor
  • The minimum of D2 valleys are zone folded, and
    their positions are in k0/- 0.336
  • Splitting between D4 subbands

24
25
Conduction band edge and effective masses
Bandgap increases when the dimensions of cross
section decrease m increases when the dimensions
of cross section decrease
25
26
Results Current-Voltage Caracteristics
1.9 nm
2.98 nm
1.36 nm
ID(VG) characteristics in linear/logarithmic
scales for three nanowire MOSFETs (LG9nm,
VD0.7V) with different square sections.
  • No influence on Ioff, due to the reduction of
    cross section dimension which induces a better
    electrostatic control
  • Overestimation of Ion (detailled on next slide)

26
27
Results Overestimation on ON-Current
When the transverse dimensions decrease, the
effective masses increase and the carrier
velocity decreases.
Overestimation of the Ion current delivered by a
LG9nm nanowire MOSFET as a function of the wire
width when using the bulk effective-masses
instead of the TB E(k)-based values.
K. Nehari et al., Solid-State Electronics, 50,
716 (2006). K. Nehari et al., APL, submitted,
2006.
27
28
  • 3D Emerging architectures
  • Influence of the Band structure Germanium

29
Conduction band minima
  • Three types of conduction band minima
  • L point four degenerated valleys (ellipsoidal).
  • ? point single valley (spherical).
  • ? directions six equivalent minima
    (ellipsoidal).

?-valleys
29
30
Dispersion relations
T5.65 nm
Ge lt100gt
  • Indirect band-gap.
  • The minimum of CB obtained in kX??/a
    corresponding to the 4 ? bulk valleys.
  • Second minimum of CB in kX0, corresponding to
    the single ? bulk valley (75 of s orbitals).

M. Bescond et al. J. Comp. Electron., accepted
(2006).
30
31
Dispersion relations
Ge lt100gt
T1.13 nm
  • The four bands at kX??/a are strongly shifted.
  • The minimum of the CB moves to kX0.
  • The associated state is 50 s (? character) and
    50 p (? and ? character) ? Quantum
    confinement induces a mix between all the bulk
    valleys.
  • ? These effects can not be reproduced by the
    effective mass approximation (EMA).

31
32
Effective masses ? point
Ge lt100gt
(1/m)(4? ²/h²)?(? ²E/? k²)
  • Significant increase compared to bulk value
    (0.04?m0)
  • From 0.071?m0 at T5.65nm to 0.29?m0 at T1.13nm
    ? increase of 70 and 600 respectively.
  • ? Other illustration of the mixed valleys
    discussed earlier in very small nanowires.

32
33
Effective masses kX?/a
Ge lt100gt
  • Small thickness the four subbands are clearly
    separated and gives very different effective
    masses.
  • Larger cross-sections (Dgt4nm) the effective
    masses of the four subbands are closer, and an
    unique effective mass can be calculated around
    0.7?m0 (effective mass mtrans0.6?m0
    for T5nm)
  • The minimum is not obtained exactly at kX?/a

33
34
Band-gap Ge vs Si
Ge lt100gt
  • For both materials the band gap increases by
    decreasing the thickness T (EMA).
  • EG of Ge increases more rapidly than the one of
    Si Si and Ge nanowires have very close band
    gaps.
  • ? Beneficial impact for Ge nano-devices on the
    leakage current (reduction of band-to-band
    tunneling).

34
35
Effective masses Valence Band
  • Strong variations with the cross-section from
    -0.18?m0 to -0.56?m0 (?70 higher than the mass
    for the bulk heavy hole).

35
36
Conclusion
  • Study of transport in MOSFET nanowire using the
    NEGF.
  • Effective Mass Approximation different materials
    and orientations (Tgt4-5nm).
  • Thinner wire bandstructure calculations using a
    sp3 tight-binding model.
  • Evolution of the band-gap and effective masses.
  • Direct band-gap for Si and indirect for Ge except
    for very small thicknesses ( mixed  state
    appears at kX0).
  • Bang-gap of Ge nanowire very rapidly increases
    with the confinement band-to-band tunneling
    should be attenuated.
  • Ge is much more sensitive then Si to the quantum
    confinement
  • ? necessity to use an atomistic description
    Full 3D

A. Martinez, J.R. Barker, A. Asenov, A.
Svizhenko, M.P. Anantram, M. Bescond, J. Comp.
Electron., accepted (2006)

A. Martinez, J.R.
Barker, A. Svizenkho, M.P. Anantram, M. Bescond,
A. Asenov, SISPAD, to be published (2006)
36
37
Description of ballisticity the Landauers
approach
? 1D case Concept of conduction channel and
quantum of conductance
  • Current density from Left to right
  • Total current density
  • Quantum of conductance

extra
38
Resistance of the reservoirs
? Resistance of the reservoirs the Fermi-Dirac
distribution limit the electron quantity injected
in a subband (D02e2/h).
extra
39
Towards the nanoscale MOSFETs
1971
1989
1991
2003
2001
410M
42M
1.2M
transistors /chip
134 000
2300
Channel length of ultimate RD MOSFETs in 2006
10 µm 1 µm 0.1 µm 10 nm
De Broglie length in semiconductors
? quantum effects
Mean free path in perfect semiconductors
? ballistic transport
extra
40
Semi-empirical methods
? Effective Mass Approximation (EMA)
  • Near a band extremum the band structure is
    approximated by an parabolic function

?
(Infinite system at the equilibrium)
extra
41
Numerical Aspects
  • Simulation Code
  • Potential energy profile (valley (010))

Electrostatic potential
2D Schrödinger Resolution
1D density (Green)
Self-consistent coupling
3D density (Green)
New electron density
Poisson
(Neumann)
New electrostatic potential
? The transverse confinement involves a
discretisation of the energies which are
distributed in subbands
Current
Extra
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