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Characterization of annealed oxides on n-type 6HSiC by high- and low-frequency CV-measurements
MICROELECTRONIC ENGINEERING
ELSEVIER
Microelectronic
Characterization
of Annealed
Low-Frequency E. Stein
A. G&z,
Institut
fiir Halhleitertechnik,
RWTH
Aachen,
rements differ
on Wtype
and
in the
same
relations
stat,es
and
oxide
of Oxides
GH-SIC
by High-
and
and
and QSCV
measu-
Aachen,
on 6HSiC
with
to the
samples.
is observed
from HFCV
by the Terman bandgap.
positive fixed
charge
bias stress.
oxide
and the HF-LF
However,
Negative
during
to the initial
Germany
are extracted
calculated
respect
for different
correlate
H. Kurz
II,
Di, values
position
traps
devices
J. Stein
23, D-520i’4
24°C to 300°C.
in hight
different
Oxides
Lehrstuhl
Sommerfeldstr.
properties
from
28 (1995) 201-204
CV--Measurements
von Kamienski,
Electrical
Engineering
charge
both
trapping The
method
methods in slow
trapping
result, interface
properties
of
densities.
1. INTRODUCTION Among terial
the wide
band
gap
(2.9 eV for 6HSiC)
cations.
Currently
is under
investigation
properties
SiOz
interpretations
[4]. In this first
The
standard
for the
interface
contribution
we compare method
time,
trapping
properties
transferable state
the
density
(Di,)
high field stress
on this for the
between
material electrical
Capacitance
be found states
appli-
[3]. Con-
Stat,ic
can
of interface
[3] at temperatures
during
based
methods
QSCV(Quasi
ma-
high-power
to the MOSXiCsystem
and
calculation
as an attractive and
in MOSFET’s
Frequency)-
and by the Terman
SIC appears
high-frequency characterization
are not easily of HF-(High
Voltage)-measurements HF-LF
materials
for use as gate-insulator [1,2].
of MOSsystems
traverse
semiconduct,or
for high--temperature,
in literature
obtained
by the
20°C and 300°C.
For the
of differentely
annealed
samples
are
invest,igated.
SAMPLE
2.
PREPARATION
Commercially 2 x 1Ol6
cme3)
a standard oxide
RCA-clean.
thickness
Nz immediately The
samples
MOS 3.
available
capacitors
(CREE
on GH-SIC
Oxidation
of 30nm. after were
At the
oxidation
metallized
with
Fig.
1 and
Fig.
Static
Capa.citance
2 show
same
temperat)ure The
at 1150°C the
paramet,ers
evapora.tion
n-type
6H-SIC
were cleaned
epilayers
in wet or dry
samples
were
are specified of Al or Cr/Ni
(ND:
in acetone O2
annealed at the and
and up
by
to an
in Ar or data
patterned
plots. into
of 0.4 mm.
AND HFCV
Siifaced
1 x 10” cmp3)
was performed
by e-beam
CHARACTERIZATION
Inc.)
(No:
(POA).
a diameter
(Quasi
R esearch,
subst.rates
(IIigh
Voltage)-data
RESULTS Frequency
Capactance
performed
at tempera,tures
0167.9317/95/$09.50 o 1995 - Elsevier Science B.V. All rights reserved. SSDI 0167-93 17(95)00043-7
Voltage)) between
and
QSCV-
24°C and
E. Stein von Kamienski
202
et al. / Microelectronic
Engineering
28 (1995) 201-204
o,oLi, n -8 -6 1. Normalized
CV-data
measured
Figure
at 100 kHz, 0.1 V/ set and 24, 100, 200 and 300°C;
sample:
POA:
wet oxidation,
300°C
on the same depletion
For the voltage curve
At room
caused
sweep
cy in the is not with
this hump sweep
towards
The
elevated
at room
temperature It is remarkable
MIS-( Metal directions.
This
and in the reverse densities
rise. deeper
towards that
towards
reproduced Fig.
the conduction
in the high
and
or nega.tive Ditpvalues
Ditpdata
calculated
annealed
this
discrepancy
CV-curves,
for the With
increasing
voltages
two
(data
direction
Terman
For the HF-LF
method data
not
and
in a limited
towards
charging
accumulation
the charge states
the onset
by the
are
We note
accumulation
directions
the position
carrier that
of asymmetry
respectively.
towards sweep
sweep
are larger
to a fast
of interface
This shifts
for both
volt,age
direction
temperatures
in the CV-curves, sweep
plateau
of Si-based
the Ditpvalues
direction
dynamics
are involved.
by the
by a high
V/set
d a t a is attributed
sweep
capacity
[6].
for the
for the opposite
CV
measurements
samples.
results
of the
for the
temperature
of 0.15~10-~
method
than
gap was calculated by the Berglund method. by a factor of 1.5 slightly smaller and shifted We explain
comparable
discharging
band
inversion
an emerging
for HFCV-measurements
HF-LF
Di,p and
respectively.
below
differently
reveal by the
states
rate
At elevated
and the discrepan-
The
1 show
only
carriers.
in the QSCV-
direction.
to a plateau
is observed
that
charge
is observable
voltages.
sweep
indicate
sweep
mea-
1, voltage
(170 K) HFCV-measurements
accumulation
charging
values
4
by arrows.
for minority
in Fig.
effect
as in Fig.
indicated
a hump
direct,ions
slow voltage
in the
that
low temperature
4 shows
for three
A similar
of interface
direction,
2
24. 100, 200 and
measurements rate
negative
to the asymmetry
With
lower energy
the
sweep
towards
calculated
a slow discharging
located
a very
asymmet,ry
’
’
0
QSCV--data and
sample
for t,he opposit,e
HFCV-curves
Semiconductor)
D;,-data
direction
range.
both
that. low temperature
Corresponding
for the sweep energy
too.
with
Insulator
3 shows
for both
is shifted
temperatures,
same direction
accumulation smaller
corresponding
shown). Fig.
emerges
directions
reached.
300°C; sweep
temperature.
is much
Normalized
at O.O5V/cm
by t,he low generation
dire&ion
(at 1 V in Fig. 2). which
temperatures
and
(lox: 30 nm,
sample.
occures,
2.
sured
60 min in Ar at 1150°C.
deep
I
-2
Voltage IV]
Voltage [V] Figure
n
-4
(Fig.
HF-LF within
are 3). method
the band
The values from the Terman method are towards lower energy values by ca. 0.25 eV.
Dit value
at the conduction
band
edge,
introducing
E. Stein von Kamienski et al. /Microelectronic
203
Engineering 28 (1995) 201-204
1,X
2,0
2,2
2,4
2,6
2,8
Ei, - E, Ievl Figure
3.
Interface
state
density
ted by HF-LF-method 1 and
Fig.
from
2, sweep
cumulation:
calcula-
data
direction
Figure
of Fig.
towards
3.
culated
ac-
bols)
TA.
Interface
by
and Terman
Samples:
to the
level.
However,
Berglund
three
samples.
were reported
at high flatband
POA
in Ar and
N2 reduces
for samples
(Vm)
is plotted
in Fig. 5. The was observed
captured
charges
are coulombic (lNr) of the increasing
curves
indicat~es
values
above
PO4
time
up to above
values.
be found
[7]. Tl ie correlation
No such
t,he two types
of defects.
to be intrinsic
defects
band edge remarkable explained
after
These
in the injection
Dit is increased that the peak by a chemically
even
by positive
initial
of Ni,,j = 9
x
the D;, and
Fig.
indicating defect formation value of D,t around 2.2~V conversion
180 min
6 shows
of the samples. The
or at elevated of defects.
oxide
charge
a.nnealed
sample
of the
t,hus they
the effect 011 Di,.
with reveals
devices
chemical
traps
densities
Not reduce
the same
tem-
N,i, a.nd
Nf and
in all samples electrons
The samples
that, the oxide
Nsit values
N,, indicates
lO’“cm-”
fixed
yuantities
arc detect,ed
SiOL-SiCsystem.
imply
the initial Both
devices
up to 300°C.
st,ress
sections
the
tunneling.
charging
in two types
cross
whereas
Nr and
defects
voltagr
are trapped
to the
between
in
relations
in Ar annealed
a negative
5, too.
of t,he
annealed
we biased
Nordheim
for temperatures
30 min,
relation
(N,,),
for differently
For comparision, in Fig.
traps
stress,
charges
doping
for Ar anneals
in Nz. The same
of Fowler
time
for the capture
centers.
a.re listed
enhanced
high field stress
the
on the Dit values
not shown).
threshold
he freed
the results
demonst,rate
bias
pa.rtly that
(data
symbols).
30 nm, POA:
[5]. Our samples
annealed
and oxide
the stress
clearely
10-15cm”
attractive samples
(N,it)
for positive
can only
This
Not. High
at 1200°C
(solid d,,:
sensitively
Similar
calsym-
in Ar or Na.
bet,ween
t,echniyue
to the samples
states
shift, versus
depends
relations
t,he conductance
method
for 60min
Dit drastically.
up to a.bove the
No effect
method
the same
compared
fabricated
voltages
voltage
peratures.
using
slow int,erface
positive
Terman
show
lower values
To investigate
The
calculations
in lit,erature
_4r show slightly were found
method.
both
density (open
dry oxidat,ion,
at 1150°C
errors
state
HF-LF-method
could
nature
of
are likely
of a 5.2MV’/cm At
the conduction
due to the high field applied. It is in Fig. 6 is reduced. This might be
of Nsit t,o N,t due to the charging.
204
E. Stein von Kamienski et al. / Microelectronic Engineering 28 (1995) 201-204
097 06 OS 0,4 0,3 02 i
E
-“,I
10
0
20
30
40
1,8
50
2,O
2,2
tstress [mini
2,4
2,6
2,8
E,- E, levl
Figure 5. Relative shift of flat,ba.nd voltage versus stress time at 5.2MV/cm, Jinj = 4 x 10-‘A/cm2, N;,j(35min) = ; dry oxidation at 1150°C. ’ 7 X 1013cmPOA in Ar at 115O”C, time as parameter.
Figure 6. D;t-data before and after 1 h stress at 5.2MV/cm, Ni,j(60min) = 9 x 10’3cm-2, calculated by Terman method; same sample as in Fig. 5, P0.4: 18Omin.
4. CONCLUSIONS
Interface method dence
state
reveal
densities
on the voltage
of interface
states.
temperatures.
states
and oxide
indicates creases
The
direction,
effect
During traps
on SIC calculated
results.
sweep This
higher
for Di, and
of oxides
comparable
taken
resulting t.owards
high
field The
is observed.
chemical
nature
Dit at the conduction
band
a fast
HF-LF
charging values
stress
negative
charge
trapping
oxide
traps
of the
are coulombic
two types
whereas
Dit located
Terman a depen-
in the band
between
The
gap for
in slow interface
attractive
A correlation of defects.
the
show
and slow discharging
energy
in Ar.
and
techniques
deeper
by a POA edge
by the
wit,h both
from
is shifted
Nf, Not can be reduced
the same
data
cha.rge
deeper
below
and J. A. Edmond;
Proc.
centers.
As
Not and trapping the band
Nf in-
edge
is reduced.
REFERENCES 1.
R.. F. Davis,
2.
D. M. Brown,
G. Kelner,
M. Shur,
J. W. Palmour
IEEE
79, 677,
(1991). Trans.
M. Ghezzo,
on Electron and
,J. Kretchmer,
Devices,
3.
E. H. Nicollian
4.
P. Neudeck,
J. Brews;
5.
T. Ouisse,
6.
L. S. Wei and
7.
E. Stein von Kamienski,
S. Kang, N. Bkcourt?
E. Downey,
J. Pimbley,
J. Palmour;
IEEE
41, 618. (1994).
J. Petit.
MOS
Physics
and
M. Tabib-Azar;
Technology .J. .4ppl.
(Wiley,
Phys.
New York:
1982).
75, 7949, (1994).
Phys. 75, 604, (1994). 17, 1021, (1974). A. G61z and H. Km-z; Mat. Sci. a. Engin. B, 29, 131, (1995).
C. Jaussaud
J. G. Simmons;
Solid
and
F. Templier;
State
Electronics,
J. Appl.
ELSEVIER
Microelectronic
Characterization
of Annealed
Low-Frequency E. Stein
A. G&z,
Institut
fiir Halhleitertechnik,
RWTH
Aachen,
rements differ
on Wtype
and
in the
same
relations
stat,es
and
oxide
of Oxides
GH-SIC
by High-
and
and
and QSCV
measu-
Aachen,
on 6HSiC
with
to the
samples.
is observed
from HFCV
by the Terman bandgap.
positive fixed
charge
bias stress.
oxide
and the HF-LF
However,
Negative
during
to the initial
Germany
are extracted
calculated
respect
for different
correlate
H. Kurz
II,
Di, values
position
traps
devices
J. Stein
23, D-520i’4
24°C to 300°C.
in hight
different
Oxides
Lehrstuhl
Sommerfeldstr.
properties
from
28 (1995) 201-204
CV--Measurements
von Kamienski,
Electrical
Engineering
charge
both
trapping The
method
methods in slow
trapping
result, interface
properties
of
densities.
1. INTRODUCTION Among terial
the wide
band
gap
(2.9 eV for 6HSiC)
cations.
Currently
is under
investigation
properties
SiOz
interpretations
[4]. In this first
The
standard
for the
interface
contribution
we compare method
time,
trapping
properties
transferable state
the
density
(Di,)
high field stress
on this for the
between
material electrical
Capacitance
be found states
appli-
[3]. Con-
Stat,ic
can
of interface
[3] at temperatures
during
based
methods
QSCV(Quasi
ma-
high-power
to the MOSXiCsystem
and
calculation
as an attractive and
in MOSFET’s
Frequency)-
and by the Terman
SIC appears
high-frequency characterization
are not easily of HF-(High
Voltage)-measurements HF-LF
materials
for use as gate-insulator [1,2].
of MOSsystems
traverse
semiconduct,or
for high--temperature,
in literature
obtained
by the
20°C and 300°C.
For the
of differentely
annealed
samples
are
invest,igated.
SAMPLE
2.
PREPARATION
Commercially 2 x 1Ol6
cme3)
a standard oxide
RCA-clean.
thickness
Nz immediately The
samples
MOS 3.
available
capacitors
(CREE
on GH-SIC
Oxidation
of 30nm. after were
At the
oxidation
metallized
with
Fig.
1 and
Fig.
Static
Capa.citance
2 show
same
temperat)ure The
at 1150°C the
paramet,ers
evapora.tion
n-type
6H-SIC
were cleaned
epilayers
in wet or dry
samples
were
are specified of Al or Cr/Ni
(ND:
in acetone O2
annealed at the and
and up
by
to an
in Ar or data
patterned
plots. into
of 0.4 mm.
AND HFCV
Siifaced
1 x 10” cmp3)
was performed
by e-beam
CHARACTERIZATION
Inc.)
(No:
(POA).
a diameter
(Quasi
R esearch,
subst.rates
(IIigh
Voltage)-data
RESULTS Frequency
Capactance
performed
at tempera,tures
0167.9317/95/$09.50 o 1995 - Elsevier Science B.V. All rights reserved. SSDI 0167-93 17(95)00043-7
Voltage)) between
and
QSCV-
24°C and
E. Stein von Kamienski
202
et al. / Microelectronic
Engineering
28 (1995) 201-204
o,oLi, n -8 -6 1. Normalized
CV-data
measured
Figure
at 100 kHz, 0.1 V/ set and 24, 100, 200 and 300°C;
sample:
POA:
wet oxidation,
300°C
on the same depletion
For the voltage curve
At room
caused
sweep
cy in the is not with
this hump sweep
towards
The
elevated
at room
temperature It is remarkable
MIS-( Metal directions.
This
and in the reverse densities
rise. deeper
towards that
towards
reproduced Fig.
the conduction
in the high
and
or nega.tive Ditpvalues
Ditpdata
calculated
annealed
this
discrepancy
CV-curves,
for the With
increasing
voltages
two
(data
direction
Terman
For the HF-LF
method data
not
and
in a limited
towards
charging
accumulation
the charge states
the onset
by the
are
We note
accumulation
directions
the position
carrier that
of asymmetry
respectively.
towards sweep
sweep
are larger
to a fast
of interface
This shifts
for both
volt,age
direction
temperatures
in the CV-curves, sweep
plateau
of Si-based
the Ditpvalues
direction
dynamics
are involved.
by the
by a high
V/set
d a t a is attributed
sweep
capacity
[6].
for the
for the opposite
CV
measurements
samples.
results
of the
for the
temperature
of 0.15~10-~
method
than
gap was calculated by the Berglund method. by a factor of 1.5 slightly smaller and shifted We explain
comparable
discharging
band
inversion
an emerging
for HFCV-measurements
HF-LF
Di,p and
respectively.
below
differently
reveal by the
states
rate
At elevated
and the discrepan-
The
1 show
only
carriers.
in the QSCV-
direction.
to a plateau
is observed
that
charge
is observable
voltages.
sweep
indicate
sweep
mea-
1, voltage
(170 K) HFCV-measurements
accumulation
charging
values
4
by arrows.
for minority
in Fig.
effect
as in Fig.
indicated
a hump
direct,ions
slow voltage
in the
that
low temperature
4 shows
for three
A similar
of interface
direction,
2
24. 100, 200 and
measurements rate
negative
to the asymmetry
With
lower energy
the
sweep
towards
calculated
a slow discharging
located
a very
asymmet,ry
’
’
0
QSCV--data and
sample
for t,he opposit,e
HFCV-curves
Semiconductor)
D;,-data
direction
range.
both
that. low temperature
Corresponding
for the sweep energy
too.
with
Insulator
3 shows
for both
is shifted
temperatures,
same direction
accumulation smaller
corresponding
shown). Fig.
emerges
directions
reached.
300°C; sweep
temperature.
is much
Normalized
at O.O5V/cm
by t,he low generation
dire&ion
(at 1 V in Fig. 2). which
temperatures
and
(lox: 30 nm,
sample.
occures,
2.
sured
60 min in Ar at 1150°C.
deep
I
-2
Voltage IV]
Voltage [V] Figure
n
-4
(Fig.
HF-LF within
are 3). method
the band
The values from the Terman method are towards lower energy values by ca. 0.25 eV.
Dit value
at the conduction
band
edge,
introducing
E. Stein von Kamienski et al. /Microelectronic
203
Engineering 28 (1995) 201-204
1,X
2,0
2,2
2,4
2,6
2,8
Ei, - E, Ievl Figure
3.
Interface
state
density
ted by HF-LF-method 1 and
Fig.
from
2, sweep
cumulation:
calcula-
data
direction
Figure
of Fig.
towards
3.
culated
ac-
bols)
TA.
Interface
by
and Terman
Samples:
to the
level.
However,
Berglund
three
samples.
were reported
at high flatband
POA
in Ar and
N2 reduces
for samples
(Vm)
is plotted
in Fig. 5. The was observed
captured
charges
are coulombic (lNr) of the increasing
curves
indicat~es
values
above
PO4
time
up to above
values.
be found
[7]. Tl ie correlation
No such
t,he two types
of defects.
to be intrinsic
defects
band edge remarkable explained
after
These
in the injection
Dit is increased that the peak by a chemically
even
by positive
initial
of Ni,,j = 9
x
the D;, and
Fig.
indicating defect formation value of D,t around 2.2~V conversion
180 min
6 shows
of the samples. The
or at elevated of defects.
oxide
charge
a.nnealed
sample
of the
t,hus they
the effect 011 Di,.
with reveals
devices
chemical
traps
densities
Not reduce
the same
tem-
N,i, a.nd
Nf and
in all samples electrons
The samples
that, the oxide
Nsit values
N,, indicates
lO’“cm-”
fixed
yuantities
arc detect,ed
SiOL-SiCsystem.
imply
the initial Both
devices
up to 300°C.
st,ress
sections
the
tunneling.
charging
in two types
cross
whereas
Nr and
defects
voltagr
are trapped
to the
between
in
relations
in Ar annealed
a negative
5, too.
of t,he
annealed
we biased
Nordheim
for temperatures
30 min,
relation
(N,,),
for differently
For comparision, in Fig.
traps
stress,
charges
doping
for Ar anneals
in Nz. The same
of Fowler
time
for the capture
centers.
a.re listed
enhanced
high field stress
the
on the Dit values
not shown).
threshold
he freed
the results
demonst,rate
bias
pa.rtly that
(data
symbols).
30 nm, POA:
[5]. Our samples
annealed
and oxide
the stress
clearely
10-15cm”
attractive samples
(N,it)
for positive
can only
This
Not. High
at 1200°C
(solid d,,:
sensitively
Similar
calsym-
in Ar or Na.
bet,ween
t,echniyue
to the samples
states
shift, versus
depends
relations
t,he conductance
method
for 60min
Dit drastically.
up to a.bove the
No effect
method
the same
compared
fabricated
voltages
voltage
peratures.
using
slow int,erface
positive
Terman
show
lower values
To investigate
The
calculations
in lit,erature
_4r show slightly were found
method.
both
density (open
dry oxidat,ion,
at 1150°C
errors
state
HF-LF-method
could
nature
of
are likely
of a 5.2MV’/cm At
the conduction
due to the high field applied. It is in Fig. 6 is reduced. This might be
of Nsit t,o N,t due to the charging.
204
E. Stein von Kamienski et al. / Microelectronic Engineering 28 (1995) 201-204
097 06 OS 0,4 0,3 02 i
E
-“,I
10
0
20
30
40
1,8
50
2,O
2,2
tstress [mini
2,4
2,6
2,8
E,- E, levl
Figure 5. Relative shift of flat,ba.nd voltage versus stress time at 5.2MV/cm, Jinj = 4 x 10-‘A/cm2, N;,j(35min) = ; dry oxidation at 1150°C. ’ 7 X 1013cmPOA in Ar at 115O”C, time as parameter.
Figure 6. D;t-data before and after 1 h stress at 5.2MV/cm, Ni,j(60min) = 9 x 10’3cm-2, calculated by Terman method; same sample as in Fig. 5, P0.4: 18Omin.
4. CONCLUSIONS
Interface method dence
state
reveal
densities
on the voltage
of interface
states.
temperatures.
states
and oxide
indicates creases
The
direction,
effect
During traps
on SIC calculated
results.
sweep This
higher
for Di, and
of oxides
comparable
taken
resulting t.owards
high
field The
is observed.
chemical
nature
Dit at the conduction
band
a fast
HF-LF
charging values
stress
negative
charge
trapping
oxide
traps
of the
are coulombic
two types
whereas
Dit located
Terman a depen-
in the band
between
The
gap for
in slow interface
attractive
A correlation of defects.
the
show
and slow discharging
energy
in Ar.
and
techniques
deeper
by a POA edge
by the
wit,h both
from
is shifted
Nf, Not can be reduced
the same
data
cha.rge
deeper
below
and J. A. Edmond;
Proc.
centers.
As
Not and trapping the band
Nf in-
edge
is reduced.
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