Transcript Document

CHAPTER 6
OXIDE AND INTERFACE
TRAPPED CHARGES,
OXIDE THICKNESS
1
6.1 INTRODUCTION
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INTRODUCTION
Charges and their location for
thermally oxidized silicon.
(1)
(2)
(3)
(4)
Interface trapped charge (Qit, Nit, Dit)
Fixed oxide charge (Qf, Nf)
Oxide trapped charge (Qot, Not)
Mobile oxide charge (Qm, Nm)
“Deal triangle” showing the
reversibility of heat treatment
effects on Qf.
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6.2 FIXED, OXIDE TRAPPED,
AND MOBILE OXIDE CHARGE
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Cross section and potential band diagram of an MOS capacitor.
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Capacitance-Voltage Curves
Qs=Qp+Qb+Qn+Qit
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Capacitances of an MOS capacitor for various bias
conditions as discussed in the text.
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In order for the inversion charge to be able
to respond, Jscr = qniW/τg ≦ Jd = CdVg/dt
W in μm, tox in nm, τg in μs
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is the dimensionless semiconductor surface
electric field. Us=φs/kT, UF=qφF/kT
= ±1
is the intrinsic Debye length
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dd stands for
deep depletion
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Low-frequency (lf), high-frequency (hf), and deep-depletion (dd) normalized
SiO2-Si capacitance-voltage curves of an MOS-C; (a) p-substrate NA= 1017
cm-3, (b) n-substrate ND = 1017 cm-3, tox= 10nm, T=300K.
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(a)
(b)
Effect of sweep direction on the hf MOS-C capacitance on an p-substrate,
(a) entire C-VG curve, (b) enlarged portion of (a) showing the dc sweep
direction; f=1 MHz.
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Flatband Voltage
There is a built-in potential at epi-sub. junction
normalized CFB
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CFB/COX versus NA as a function of tox for the SiO2 -Si system at T=300K.
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Schematic illustration of an MOS-C with finite gate doping density,
showing gate depletion for positive gate voltage.
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Low-frequency and high-frequency capacitance-voltage curves for various
n+ polysilicon gate doping densities. The lowest Chf curve is for ND (gate)
=1018 cm-3. Substrate NA =1016 cm-3, tox =10nm.
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Capacitance Measurement
for RG<<1 and (ωRC)2<<RG
From the in-phase and
out of phase component
G and C can be
determined.
Simplified capacitance
measuring circuit.
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(a)
(b)
Block diagram of circuits to measure the current and
charge of an MOS capacitor.
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Low Frequency : Current-Voltage
Low Frequency : Charge-Voltage
CF is the feedback capacitance.
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Ideal (line) and experimental (point) MOS-C curves. NA =5×1016 cm-3,
tox=20nm, T=300K, CFB/Cox=0.77.
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Fixed Charge
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Gate-Semiconductor Work Function Difference
Potential band diagram of a metal-oxide-semiconductor system at flatband.
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Potential band diagram of (a) n+ polysilicon-p substrate, and
(b) p+ polysilicon-n substrate at flatband.
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Oxide Trapped Charge
Flatband voltage of polysilicon-SiO2-Si MOS
devices as a function of oxide thickness.
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Work function difference as a function of doping density
for polysilicon-SiO2 MOS devices.
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Mobile Charge
Drift time for Na, Li, K, and Cu for an oxide electric
field of 106 V/cm and tox =100 nm.
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C-VG curves illustrating the effect of mobile charge motion.
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CIf and Chf measured at T=250OC. The mobile charge density is
determined from the area between the two curves.
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6.3 INTERFACE
TRAPPED CHARGE
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Low-Frequency (Quasi-static) Method
•
Semiconductor band diagram illustrating the effect of interface traps;
(a) V=0, (b) V>0, (c) V<0. Electron-occupied interface traps are
indicated by the small horizontal heavy lines and unoccupied traps by
the light lines
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(a)
(c)
Theoretical ideal (Dit=0) and Dit ≠0
(a) hf , (b) If and (c) experimental lf
C-V curves.
(b)
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CS=Cb+Cn
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High- and low-frequency C-VG curves showing the offset
△C/Cox due to interface traps.
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Interface trapped charge density from the hf curve and the offset △C/Cox.
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Conductance Method
Cox
Cox
Cox
Rit
Cit
G
Rit
Cp
Gp C m
Gm
CS
Gt
Cit
rS
(a)
(b)
(c)
(d)
(a) MOS-C with interface trap time constant τit=RitCit , (b) simplified circuit of (a),
(c) measured circuit, (d) including series rs resistance and tunnel conductance Gt.
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Gp/ω versus ω for a single level, a continuum and experimental
data. For all curves: Dit =1.9×109 cm-2 eV-1, τit=7×10-5s.
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Interface trapped charge density versus energy from the quasi-static and
conductance methods. (a) (111) n-Si, (b) (100) n-Si.
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High-Frequency Methods
Terman method:
Gray-Brown method:
The hf capacitance is measured as a function
of temperature.
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Charge Pumping Method
Circuit diagram and energy bands for charge pumping measurement.
The figures are explained in the text.
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(c)
(d)
(e)
(f)
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Bilevel chare pumping waveforms.
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Dit=7×109cm-2eV-1
MOSFET Qcp versus frequency
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Trilevel charge pumping waveform and corresponding band diagrams.
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(a) Icp as a function of tstep showing τe at the point where Icp begins to
saturate.
(b) insulator trap density versus insulator depth from the insulator/Si
interface for Al2O3 and SiO2.
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Interface trap density as a function of energy through the band gap for
various measurement techniques. Reprinted with permission
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Charge pumping current versus base voltage for two voltage pulse
heights before and after gate leakage current correction. tox=1.8nm, f=1kHz.
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MOSFET Subthreshold Current Method
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MOSFET subthreshold characteristic.
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MOSFET substhreshold characteristics before and after stress.
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Band diagram for (a) VG =VMG (φs=ψF) (a) VG =VT (φs≒2ψF).
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DC-IV
(a) DC-IV measurement set-up.
(b) surface space charge region for different gate bias.
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With the surface in strong inversion or
accumulation, the recombination rate is low. The
rate is highest with the surface in depletion.
I B  qAG ni sr exp(qVBS / 2kT )
sr  (  / 2 ) o v th N it
If charge is injected into oxide, leading to a VT shift,
ID will also shift. ΔID→ΔVT→ΔQot
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IB before and after stress.
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6.4 OXIDE THICKNESS
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C-V Measurements
Assume:
1. The interface trap capacitance is negligible in
accumulation at 100kHz to 1MHz.
2. The differential interface trap charge density
between flatband and accumulation is negligible.
3. The oxide charge density is negligible.
4. Quantum effects are negligible.
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C-V Measurements
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1/C versus 1/(VG-VFB) for
two oxide thicknesses. Data
adapted from Ref. 101.
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D=Gp/ωCp.
(a) MOSC equivalent circuit with tunnel conductance and series
resistance. (b) parallel and (c) series equivalent circuit .
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•
Measurement error dependence on device area and oxide thickness.
The two-frequency measured capacitance is in error less than 4% in
the shaded region. At higher frequencies the D=1.1 border shifts to
thinner oxides. Adapted from ref. 109
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I-V Measurements
J FN  AEox2 exp(B / Eox )
Eox is the oxide electric field and A and B are
constants.
J A
FN
J dir
AVG kT
B( 1  ( 1  qVox /  B )1.5 )
 2
C exp(
)
E ox
t ox q
Both currents are very sensitive to oxide
thickness.
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