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Concerning the use of the Kramers-Kronig transforms for the validation of impedance data
Corrosion Science, Voi. 28, No. 9, pp. 9 3 3 - 9 3 8 , 1988 Printed in Great Britain
0010-938X/88 $3.00 + 0.00 Pergamon Press plc.
SHORT COMMUNICATION CONCERNING
THE USE OF THE KRAMERS-KRONIG
TRANSFORMS
F O R THE VALIDATION OF IMPEDANCE DATA
H O N G S H I N AND FLORIAN M A N S F E L D
University of Southern California, Materials Science Department University Park, Los Angeles, CA
90089-0241
Abstract: The a p p l i c a t i o n o f t h e K r a m e r s - K r o n i g t r a n s f o r m s t o a number typical corrosion systems has shown that severe proble m s e xis t with the ir for validation of experimental impedance data. Even f o r t h e o r e t i c a l data agreement with the transforms is observed if the impedance data have r e a c h e d t h e i r dc l i m i t w i t h i n t h e f r e q u e n c y r a n g e u s e d f o r t h e t r a n s f o r m .
of use no not
INTRODUCTION The i n c r e a s i n g to
the
study
application
of a variety
means o f v a l i d a t i o n the
EIS
models. will
data
of such data.
have
a
produce semicircles
preted fulness
out
form
that
or other
cannot
experimental
curves
(3,4) have given examples
important be
data
Such c u r v e s al
(K-K) t r a n s f o r m s
of electrochemical
necessary
with
simple
can be o b t a i n e d
"which
impedance
plot,
cannot,
data.
b u t w h i c h do
then,
(2) h a v e p o i n t e d
as a tool
(EIS)
to define
in cases where
explained
in a complex plane
Van N e i r h a e g h e e t
of the Kramsrs-Kronig
interpretation
especially
and
the Kramsrs-Kronig relationsl
as impedance = (1).
impedance spectroscopy
p h e n o m e n a makes i t
This is
complicated
Cahan h a s p o i n t e d
not satisfy
of electrochemical
of corrosion
be i n t e r -
out the use-
for the evaluation
Recently,
and
Macdonald et
al
for the use of the K-K relations as diagnostic cri-
teria for determining the validlty of EIS data. The application of the K-K relations to EIS data for a number of corrosion systems obtained in this laboratory has shown that serious problems exist with this approach of validation of impedance data. sion resistant systems,
In many studies of very corro-
such as inhibited solutions,
polymer coated metals and
anodized surfaces,
the impedance data do not show a d c
limit within the lowest
frequencies
which
result
range
demonstrates
can
the excellent
be
studied.
corrosion
While
resistance
this
by
itself
of the system studied,
been found that the K-K relations suggest that the data are not valid. apparently
due
to
the
fact
that
the
impedance
Manuscript ~.eived for publication 22 June 1988. 933
data
were
not
finite
often it has
This is in
the
934
HONG SHIH and FLORIAN MANSFELD
investigated frequency range. involve
a Warburg
impedance
the K-K relations results,
It has also been observed that for systems which (Randles-circuit)
again suggest
it is proposed
that
or a transmission
that the data are not valid.
the use of
the K-K relations
line element
Based on these
for validation
of
experimental EIS data be considered only with severe reservations until further analyses
of
this problem have been made.
In the following
some examples
for
the erroneous transforms will be given. RESULTS AND DISCUSSION The first example involves the simple case of a resistance Rp in parallel with a capacitance Cd and in series with a resistance R s.
If the lowest fre-
quency used for the recording of EIS data for this system is 0.01 Hz, then the spectrum will quency
end
in the capacitive
is about 0.0016 Hz
transforms
from
the
(5).
region,
since
the lower break-point
fre-
The real part Z' of the impedance obtained by
imaginary
part
Z"
shows
large
discrepancies
from
the
"measured" value of Z' at the lowest frequencies which could be interpreted as being
due
to errors
in these
(theoretical)
data
(Fig.
1).
The same analysis
with the lowest frequency at 10 -5 Hz results in perfect agreement between both curves.
When ~
was
lowered from 106 ohm to 104 ohm, very good agreement was
observed for a low frequency limit of the K-K transform at 0.01 Hz. The second e x ~ p l e impedance. quencies
deals with the Randles-circuit which involves a Warburg
As shown in Fig.
which
Nyquist-plots transforms.
2 a discrepancy is found again at the lowest fre-
is especially for
The
the
curve
pronounced
theoretical calculated
data with
for Z" and
(Fig.
those
2b).
Fig.
calculated
the K-K relations
3 shows
using
the
the K-K
does not agree with
that for a Randles-circuit. The
third
passivated pitting
example
in CeC13
is observed
and after
uses then
experimental exposed
this time.
data
for
to 0.5 N NaCl
AI
6061
for
7 days
The experimental
which
had
(6,7).
been Some
data can be fitted to
the pitting model described recently which involves a transmission line element for the reactions
in the pits
(6,7).
Again,
that the data are not valid as shown in Fig. parameters
were
used
to produce
theoretical
the K-K relations would suggest 4 and 5. data down
Only when the fitting to 10 -7 Hz
(!)
it was
possible to validate these data with the K-K relatlons. CONCLUSIONS A transfer function can only be called an impedance when the conditions of causallty,
linearity#
and stability
are
fulfilled
and the
impedance
data
are
Short C o m m u n i c a t i o n
o
•
2
~
2
935
E
~r
m--
'
<
o
° ~ 4--
°~
T
3
T
I
~
°
t~
(~1..IO 1
°
t~l
o
o (t~q0)
~ued 6ewz.Z-
._
al
~Jed Ieau-z
N
"
.u
m
C
~o
J
0 0
0 0
.4
,,~
_j
I 0
I
0 ~'
00wlwqolSetu~Z-
O
I11
00$/(tut.10
ul;
Z)~eauz
~
936
HONG SHIn and FLORIAN MANSFELD 0 0
w~
,A 0 0
~
l
¢
¢
0 0
0 0
0 0
o
~
o
0 0
0 0
o
0 0
o
o
0 0
~
o
t
0
(mClO ul Z) ~emIZel
..;=
A
A
e
d
•I-
~e
~o
0 ~
0 0 0
(.,q0)
0 0 0
~Jecl
0 0 0
0 0 0
o 0 0
0
0 o o
(gqO)
OemIz-
o o o
!
o 0 o
~Jed
leeu-Z
o
E
w ..Jol
0
0
i
I
0
0
i
i
o
o
(mqo uT Z)
eie,.1:Z-
&
Short Communication finite.
The
present
criterion
in the use of the K-K transforms
impedance data. which K-K
is due
shows
that
a problem
with
the
last
for the validation of experimental
the
results
problems
indicated
in real systems, were subjected to the
that
these
data were
the K-K transforms agree with the experimental
in those cases where these data approach a d c used for the K-K transform. apparently
exists
When theoretical data calculated for a lower frequency limit, to experimental
analysis,
ently,
discussion
937
cannot
detect
not
valid.
Appar-
or theoretical data only
limit within the frequency range
These results and the fact that the K-K analysis
errors
due
to
non-linearity
justify
the
suggestion
that at the present state of knowledge the K-K relations should not be used for validation
of
impedance
experimental
data.
Further
work
is
in progress
evaluate solutions to these problems and to define alternative approaches.
to The
question of non-linearity will be addressed next in this evaluation. The authors still agree with the necessity for criteria for validation of experimental which data
impedance
are being
data
reported
especially
for
many
of
in the rapidly expanding
do not seem to agree with
the
complicated
literature.
systems
Many of these
any of the models which describe
the physical
realities of such systems. Acknowledgment The
authors
acknowledge
pointed out some deficiencies
the
comments
by
in the original
W.J.
Lorenz
and
M.
Ebert
authors for the use of the K-K transforms and suggested some improvements. initial
approach
Macdonald.
was
based
on
the
computer
who
computer program written by the
program
kindly
supplied
The
by D.D.
This work has been performed under Contract No. DAAL 03-86-K-0156.
with the U.S. Army Research Office. REFERENCES 1.
B.D. Cahan and C.-T. Chen, J. Electrochem.
2.
R.L. van Meirhaeghe, Acta 21, 39 (1976).
3.
D.D. Macdonald and M. Urquidi, J. Electrochem.
4.
M. Urquidi-Macdonald,
5.
F. Mansfeld, Corrosion 37, 301
6.
F. Mansfeld,
7.
F. Mansfeld, S. Lin, S. Kim and H. Shih, Corrosion/88, Mo., paper No. 380, submitted to Corrosion.
E.C.
Dutoit,
Soc. 129, 474
F. Cardon
and W.P.
(1982).
Gomes,
Electrochim.
Soc. 132, 2316
S. Real, and D.D. Macdonald,
(1985).
ibid. 133, 2018
(1986).
(1981).
S. Lin, S. Kim and H. Shih, Corr. Sci. 27, 997
(1987).
NACE,
St.
Louis,
938
HONG SHIH and FLORIANMANSFELD
Figure Captions
1.
Theoretical and K-K transform data Cd = 10-4F).
(Rs = 10 ohm, Rp = 106 ohm,
2.
Theoretical and K-K transform data for Randles-circuit.
3.
Nyquist-plots for data in Fig. 2.
4.
Experimental and K-K transform data for A1 6061, passivated in 1000 ppm CeCl 3, after exposure in 0.5 N NaC1 for 7 days.
5.
Nyquist-plots for data in Fig. 4.
0010-938X/88 $3.00 + 0.00 Pergamon Press plc.
SHORT COMMUNICATION CONCERNING
THE USE OF THE KRAMERS-KRONIG
TRANSFORMS
F O R THE VALIDATION OF IMPEDANCE DATA
H O N G S H I N AND FLORIAN M A N S F E L D
University of Southern California, Materials Science Department University Park, Los Angeles, CA
90089-0241
Abstract: The a p p l i c a t i o n o f t h e K r a m e r s - K r o n i g t r a n s f o r m s t o a number typical corrosion systems has shown that severe proble m s e xis t with the ir for validation of experimental impedance data. Even f o r t h e o r e t i c a l data agreement with the transforms is observed if the impedance data have r e a c h e d t h e i r dc l i m i t w i t h i n t h e f r e q u e n c y r a n g e u s e d f o r t h e t r a n s f o r m .
of use no not
INTRODUCTION The i n c r e a s i n g to
the
study
application
of a variety
means o f v a l i d a t i o n the
EIS
models. will
data
of such data.
have
a
produce semicircles
preted fulness
out
form
that
or other
cannot
experimental
curves
(3,4) have given examples
important be
data
Such c u r v e s al
(K-K) t r a n s f o r m s
of electrochemical
necessary
with
simple
can be o b t a i n e d
"which
impedance
plot,
cannot,
data.
b u t w h i c h do
then,
(2) h a v e p o i n t e d
as a tool
(EIS)
to define
in cases where
explained
in a complex plane
Van N e i r h a e g h e e t
of the Kramsrs-Kronig
interpretation
especially
and
the Kramsrs-Kronig relationsl
as impedance = (1).
impedance spectroscopy
p h e n o m e n a makes i t
This is
complicated
Cahan h a s p o i n t e d
not satisfy
of electrochemical
of corrosion
be i n t e r -
out the use-
for the evaluation
Recently,
and
Macdonald et
al
for the use of the K-K relations as diagnostic cri-
teria for determining the validlty of EIS data. The application of the K-K relations to EIS data for a number of corrosion systems obtained in this laboratory has shown that serious problems exist with this approach of validation of impedance data. sion resistant systems,
In many studies of very corro-
such as inhibited solutions,
polymer coated metals and
anodized surfaces,
the impedance data do not show a d c
limit within the lowest
frequencies
which
result
range
demonstrates
can
the excellent
be
studied.
corrosion
While
resistance
this
by
itself
of the system studied,
been found that the K-K relations suggest that the data are not valid. apparently
due
to
the
fact
that
the
impedance
Manuscript ~.eived for publication 22 June 1988. 933
data
were
not
finite
often it has
This is in
the
934
HONG SHIH and FLORIAN MANSFELD
investigated frequency range. involve
a Warburg
impedance
the K-K relations results,
It has also been observed that for systems which (Randles-circuit)
again suggest
it is proposed
that
or a transmission
that the data are not valid.
the use of
the K-K relations
line element
Based on these
for validation
of
experimental EIS data be considered only with severe reservations until further analyses
of
this problem have been made.
In the following
some examples
for
the erroneous transforms will be given. RESULTS AND DISCUSSION The first example involves the simple case of a resistance Rp in parallel with a capacitance Cd and in series with a resistance R s.
If the lowest fre-
quency used for the recording of EIS data for this system is 0.01 Hz, then the spectrum will quency
end
in the capacitive
is about 0.0016 Hz
transforms
from
the
(5).
region,
since
the lower break-point
fre-
The real part Z' of the impedance obtained by
imaginary
part
Z"
shows
large
discrepancies
from
the
"measured" value of Z' at the lowest frequencies which could be interpreted as being
due
to errors
in these
(theoretical)
data
(Fig.
1).
The same analysis
with the lowest frequency at 10 -5 Hz results in perfect agreement between both curves.
When ~
was
lowered from 106 ohm to 104 ohm, very good agreement was
observed for a low frequency limit of the K-K transform at 0.01 Hz. The second e x ~ p l e impedance. quencies
deals with the Randles-circuit which involves a Warburg
As shown in Fig.
which
Nyquist-plots transforms.
2 a discrepancy is found again at the lowest fre-
is especially for
The
the
curve
pronounced
theoretical calculated
data with
for Z" and
(Fig.
those
2b).
Fig.
calculated
the K-K relations
3 shows
using
the
the K-K
does not agree with
that for a Randles-circuit. The
third
passivated pitting
example
in CeC13
is observed
and after
uses then
experimental exposed
this time.
data
for
to 0.5 N NaCl
AI
6061
for
7 days
The experimental
which
had
(6,7).
been Some
data can be fitted to
the pitting model described recently which involves a transmission line element for the reactions
in the pits
(6,7).
Again,
that the data are not valid as shown in Fig. parameters
were
used
to produce
theoretical
the K-K relations would suggest 4 and 5. data down
Only when the fitting to 10 -7 Hz
(!)
it was
possible to validate these data with the K-K relatlons. CONCLUSIONS A transfer function can only be called an impedance when the conditions of causallty,
linearity#
and stability
are
fulfilled
and the
impedance
data
are
Short C o m m u n i c a t i o n
o
•
2
~
2
935
E
~r
m--
'
<
o
° ~ 4--
°~
T
3
T
I
~
°
t~
(~1..IO 1
°
t~l
o
o (t~q0)
~ued 6ewz.Z-
._
al
~Jed Ieau-z
N
"
.u
m
C
~o
J
0 0
0 0
.4
,,~
_j
I 0
I
0 ~'
00wlwqolSetu~Z-
O
I11
00$/(tut.10
ul;
Z)~eauz
~
936
HONG SHIn and FLORIAN MANSFELD 0 0
w~
,A 0 0
~
l
¢
¢
0 0
0 0
0 0
o
~
o
0 0
0 0
o
0 0
o
o
0 0
~
o
t
0
(mClO ul Z) ~emIZel
..;=
A
A
e
d
•I-
~e
~o
0 ~
0 0 0
(.,q0)
0 0 0
~Jecl
0 0 0
0 0 0
o 0 0
0
0 o o
(gqO)
OemIz-
o o o
!
o 0 o
~Jed
leeu-Z
o
E
w ..Jol
0
0
i
I
0
0
i
i
o
o
(mqo uT Z)
eie,.1:Z-
&
Short Communication finite.
The
present
criterion
in the use of the K-K transforms
impedance data. which K-K
is due
shows
that
a problem
with
the
last
for the validation of experimental
the
results
problems
indicated
in real systems, were subjected to the
that
these
data were
the K-K transforms agree with the experimental
in those cases where these data approach a d c used for the K-K transform. apparently
exists
When theoretical data calculated for a lower frequency limit, to experimental
analysis,
ently,
discussion
937
cannot
detect
not
valid.
Appar-
or theoretical data only
limit within the frequency range
These results and the fact that the K-K analysis
errors
due
to
non-linearity
justify
the
suggestion
that at the present state of knowledge the K-K relations should not be used for validation
of
impedance
experimental
data.
Further
work
is
in progress
evaluate solutions to these problems and to define alternative approaches.
to The
question of non-linearity will be addressed next in this evaluation. The authors still agree with the necessity for criteria for validation of experimental which data
impedance
are being
data
reported
especially
for
many
of
in the rapidly expanding
do not seem to agree with
the
complicated
literature.
systems
Many of these
any of the models which describe
the physical
realities of such systems. Acknowledgment The
authors
acknowledge
pointed out some deficiencies
the
comments
by
in the original
W.J.
Lorenz
and
M.
Ebert
authors for the use of the K-K transforms and suggested some improvements. initial
approach
Macdonald.
was
based
on
the
computer
who
computer program written by the
program
kindly
supplied
The
by D.D.
This work has been performed under Contract No. DAAL 03-86-K-0156.
with the U.S. Army Research Office. REFERENCES 1.
B.D. Cahan and C.-T. Chen, J. Electrochem.
2.
R.L. van Meirhaeghe, Acta 21, 39 (1976).
3.
D.D. Macdonald and M. Urquidi, J. Electrochem.
4.
M. Urquidi-Macdonald,
5.
F. Mansfeld, Corrosion 37, 301
6.
F. Mansfeld,
7.
F. Mansfeld, S. Lin, S. Kim and H. Shih, Corrosion/88, Mo., paper No. 380, submitted to Corrosion.
E.C.
Dutoit,
Soc. 129, 474
F. Cardon
and W.P.
(1982).
Gomes,
Electrochim.
Soc. 132, 2316
S. Real, and D.D. Macdonald,
(1985).
ibid. 133, 2018
(1986).
(1981).
S. Lin, S. Kim and H. Shih, Corr. Sci. 27, 997
(1987).
NACE,
St.
Louis,
938
HONG SHIH and FLORIANMANSFELD
Figure Captions
1.
Theoretical and K-K transform data Cd = 10-4F).
(Rs = 10 ohm, Rp = 106 ohm,
2.
Theoretical and K-K transform data for Randles-circuit.
3.
Nyquist-plots for data in Fig. 2.
4.
Experimental and K-K transform data for A1 6061, passivated in 1000 ppm CeCl 3, after exposure in 0.5 N NaC1 for 7 days.
5.
Nyquist-plots for data in Fig. 4.