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Electrochemical and morphological characterization of prefilmed aluminium brass
Materials Chemistry and Physics, 8 (1983) 337-348
ELECTROCHEMICAL PREFILMED
G.
AND
Centro
and
di studi
mica, O”
MORPHOLOGICAL
ALUMINIUM
BRUNORO’
0
Via
L.
Corso Received
P.
SPINELLl
sulla
degli
46,
“A.
Dacco”,
FERRARA
1982;
e lngegneria
TURIN
24,
Universita
di Ferrara,
lstituto
Chi-
(Italy)
dei Materiali
Abruzzi
8 November
OF
O”
Corrosione
di Scienra
Duca
CHARACTERIZATION
BRASS
Borsari
Dipartimento
337
accepted
Chimica,
Politecnico
di Torino,
(Italy)
6 December
1982
ABSTRACT
Electrochemical with
and
morphological
Benzimidazole-2-thioi
rious
plls.
tective
of
action
of
film.
between
mitation
layer
as
/ NTRODUCT The
inhibitor
cathodic
shown
in 0.1
the
immersion
in the
sodium
giving
rise
and
metal
seems
to be
current
density of the
for
oxygen
inhibitor
with is
resistance
brass
chloride
layer
temperature
film
never
the
Alum~nium
sodium
a surface
prefilming
that
of N
occurs,
a consequence
to
very
chloride
on the
solution,
localized
reduction.
interaction
is
for
va-
pro-
the
pro-
pH
of the
a uniform
attack.
responsible
of
good
increase
depends
to
prefilmed
solutions
An
inter-
a marked
A stabilization
ii-
of the
suggested.
I ON
protective
effectiveness
copper
and
copper
proved
the
practical
nium
film
made produces
of the
was
prolongued
surface the
of the
effect
It
Upon the
characterization
was
treatment
The
the
solution.
removal
oxide
prefilming
properties.
tectivity test
The
(BIE)
alloys,
of Benzimidazol
has
been
importance
of
e-2-thiol
investigated this
(BIE)
in a series
substance
as
as
an
of papers
a prefilming
inhibitor
for
(I-4)
which
for
Alumi-
agent
brass. Recently
tored
by
prefilming it was
(5)
treatment.
I ast
et ectrochemical a sol ution
growth
el lipsometry,
immersed
These
the
thus
of
the
individuating
Characterization
in an aggressive results
suggested
properties
containing
copper-inhibitor
of the
of
the
optimal
the
film
environment to extend films
film
was the
formed
during
experimental
properties also
and
Aluminium
was
conditions its
investigated
investigation on
prefilming
for
behaviour
the when
(6).
to morphological brass
moni-
by
and
immersion
in
BI E.
0
Etsevier Sequoia~~nted
in The N~therlaRds
338 This
paper
observations
reports
and
filming
temperature
EXPER
I MENTAL
The were The
electric
back
(0.25
Prefilming of
curves
were
thodic
branch
not
only
chloride
prefilmed
electrodes
The in
at
stirred
obtained tests
for
192
the
(5-6).
to evaluate
ratures.
These samples
of cast
n.
films
the
both
effect
by
SEM
of the
Aluminium
an
exposed
wire,
sealed
800
emery
electrodes
for
These
pre-
brass
surface
and
of 2 cm’.
J
in a smal
paper
and
which
had
been
curves
were
glass
then
alumi-
to
localized
at
at
desired
After
was
of nor-
prefilming,
the
in air.
sodium
chloride
25OC.
Anodic
to
those
tests
55O and
various
affects
obtained
were
the
with
performed
85OC
water
at
rest
at
polarization
substantially
the
amount
temperature
in distilled
on prefilmed
aspects
protective
proved,
started
solutions
in 0.1
same
in a neutral
at
and
ca-
nonin 0.1
with
non-
5S”
or
85’C
potentiai
and
were
which
were
192
hours
car-
.
samples
hours
N
BIE
prefilmed
were
made
chloride
The
the
85OC.
compared
pre-treated
-1
1 mV.s
adding
dried
at
with
range.
electrodes
of
prefilmed
were
for
the
tests
pH
and
in 0.1
prefilming
5 minutes
prefilming
and
traced
curves
same
55”
water
ef ectrodes
by
The
at
led
were
morphological
552
made
pH=7
rate
prepared
water.
were
since
in the
the
was
in distil
non-prefilmed and
in order
prefiimed
on
N sodium
with
bars
with
immersing
curves
observations
The
temperature.
ar,
a copper
polishing
tests
Polarization
0.1
particui
to obtain
through
solution
rinsed
9)
at
a scan
SEM
in order
considered,
N sodium
out
resin
by
some
7 and
5 minutes.
of cylindrical
to bi-distilled
was
electrodes
ried
BIE
but
prefilmed
for
such
electrode.
The
polarization 5,
In
out
included
BIE.
surface
(pH=3,
studying
account.
made
obtained
reagent
Cathodic pHs
the
by
tests.
into
cut
was
of
was
25 2 1 OC,
electrode
obtained
pm).
10W3M
grade
mally
were
preparation
na polishing
solution
taken
in “Epophix”
the
Surface
pure
was
connection
from
results
electrochemical
electrodes
embedded
tube,
by
the
at pH=3, of the
under
the
N sodium
attack.
same
time,
7 and
samples same
chloride
effectiveness the
electrodes 9 for
were
conditions.
very
at pH=7 at
scarce
the
at
room
to those
Moreover,
solutions
of prefilming the
compared
immersed
immersion were
various
tendency
made tempe-
of the
339 RESULTS
AND
1
Fig. rious
Dl SCUSS
shows
the
experimental
dium
chloride
electrodes
for
with
occur.
30
of
the
minutes.
increasing
It
of cupric
the
ions
can
potentials
be
solution nobler
as
seen
pH.
noble
a consequence
been
the
non-prefilmed to -0.201
no appreciable
variation
potential
va-
N so-
-0.136
electrode
of alloy
the
in 0.1
of the
(from
pH=7,
under
immersed
potential
values
of the
1 recorded,
corr
had
that
Above
values
(E
which
I ess
towards
the
that
rest
on electrodes
displace
We argued
presence
values
conditions,
markedly
V/SCE)
ION
were
due
did to
the
dissolution.
-0.10 _
* “/SCE
:
-0.15
A
_
\ ‘lo, O-0
\
-0.20.
-0
t -0.25.
Fig.
1.
pH:
0
*
Corrosion
some the
this
tests.
minutes
As
potential
very
Prefiiming of the
test
at pH=5
there
towards
positive
in 0.1
the
toward
to
25’YI
solution. seems
that
to be
values
of
cupric positive
ions
pH=3
no effect,
does
occur
addition,
an
was
5.10
-5
the
potential whereas (see
fig.
as
a function
of
electrodes;
at pH=3;
added
to the
immediate
A
non-pre-
For
M cupric
chloride,
without
of prefilmed at pH=?
and
example, an
cupric
potential,
solution
in
displacement
observed.
electrode
1).
N&I,
non-prefiimed
pH=3.
were
in a solution
affects the
at
ions
values
determined
N
l
+ 5. 10m4M CuC12 CuC12
cupric
containing
differently At
N NaCl
amounts
in 0.1
T=25%;
+ 5.10-‘M
in a sol ution
close at
of
brass
low3 M f3lE,
N NaCl
small
a result
immersion
potential
pH
in 0.1
reason,
electrode
in
electrodes
electrodes
PH
of Al uminium
ei ectrodes
non-prefilmed
For
9
potentials
prefiimed
filmed
7
5
3
ions
after
9 a small
is
30
electrode was
depending
electrodes
of
obtained. on the
I ess
noble,
displacement
340
I owering
The sing of
of cupric
the
been
film.
ions On
reported
filming stabil
electrode
other
previous1 may
effect
Figures
the
y (2)
be
show
the
various
pHs,
observed
that
the
polarization
for
the
first
for
the
curves
of part
the
of the
traced
a consequence increase and
explained
by
was
attributed
of the
in the copper
initial
potential alloys
to the
decrea-
protective
at
pH
7,
in the
presence inhibitor
the
adsorption
of the
polarization
curves
obtained
action which
has
of preor
by
its
oxide.
cathodic
both
on prefil curves
current
at pH=3
on copper
surface
at
values
the
simply
sol utions
smaller
as
hand,
on the
2 - 5
potential
concentration
the
agents, izing
of
density,
cathodic
med
for
and
the
non-prefilmed
prefilmed
compared
The
electrodes.
electrodes
to the
polarization.
in sodium It
always
can
be
present
non-prefilmed
ones,
noticeable
differences
most
chloride
at
least appear
at pH=7.
-0.5 _
-0.8
_ 0.1
Fig.
A.om-*
2.
Cathodic
solution (-----)
prefil
By curve low
of pH=3, med
anal ysing for
the
polarization.
non
polarization T=25OC: electrodes,
the
curves (-----I E
polarization
prefilmed
100
lo
on Aluminium non-prefi
corr
= -0.165
curves
electrode
I med
in aerated E
V/SCE.
in detail,
exhibits
brass
electrodes,
it can
a maximum
be
seen
current
0.1
corr
N NaCl
= -0.136
that density
V/SCE;
at pH=3
the
vat ue at
341
Fig.
3.
solution (-----)
Cathodic of pH=5, prefilmed
polarization
curves
( -_)
T=2S°C: el ectrodes,
\ “/SW
\
.
E
.
on Aluminium
non-prefilmed = -0.177
corr
-.
brass electrodes,
in aerated E
V/SCE.
corr
0.1 = -0.173
N NaCl V/SCE;
\
-0.5 _
: I I I1
-0.8 _
0.1
),.c,,,-~
100
lo
'r
Fig.
4.
solution (-----)
Cathodic of pH=7, prefilmed
polarization T=25”C: electrodes,
curves
( -)
on Aluminium
non-prefilmed E
corr
= -0.180
brass electrodes,
V/SCE.
in aerated E
corr
0.1 = -0.201
N NaCl V/SCE;
342 Tests peak
carried
of the
current
thodic
polarization
V/SCE,
which which
cess,
hydrogen
is
ions
by
by
is
been
even
in this
of
oxygen
occurs
at
more
is
the
not
under
potential
step
reduction
pH
affected,
and
control
appears after
and
action peak
while
on the
ions. at
that
seems
this
first
When
the
ca-
about
-0.4
a third
pro-
to be due
to
value.
reduction
vat ues
confirmed
controlled
protective
ions
substantially
negative
solution,
of cupric
diffusion
initial
cupric
the
reduction
to oxygen
an
the
to the
corresponding
to exert of
to
a diffusion
case
at
absence
ions
to be due
attributed
reduction
duction
cupric
increased,
seems
the
adding
density
has
Prefiiming shown
out
even
at pH=3,
on the
the
cathodic
discharge
prefilmed
as
it
is
curve.
Re-
of hydrogen
ions
el ectrodes.
-0.2
\ V/SCL
\ \ \ \
-0.5
\
.
\
-0.t I _
.
_ _
0.1
Fig.
5.
Cathodic
solution (-----)
trend. with can be
There
is a slight
be
close
to for
oxygen the
galvanostatic
conditions.
It
was
initiates
at
shown
tests
a potential
of
E
non-prefilmed
The
and first
whereas
carried
in aerated
polarization
which
one,
that,
for
densities.
reduction,
second
of
I ow
brass electrodes,
V/SCE.
curves
at
current
med
-0.190
cathodic
fexion
in a series
oxide
Ecorr=
the
I imiting
attributed
responsible
9,
on Aluminium non-prefil
electrodes,
7 and
very
curves ( -)
T=25%:
pH=5,
_ __
100
lo
P
polarization
of pH=9, prefilmed
At
A.,3,,-2
l
out
in the
solution
-0.45
V/SCE.
corr
two
of these of cuprous
at
-0.45
V/SCE.
strict1
y control
under under
test,
the
V/SCE;
have
reduction
reduction
appears
N NaCl
electrodes
then
one
0.1
= -0.203
two
This
reduction
processes
processes,
oxide
led
similar
seems was
to
shown
experimental of cuprous
343
-0.8
’ r
,,.~,,'2
Fig.
6 a.
solution
Cathodic of pH=7,
5 minutes, for
polarization T=2S°C: = -0.181;
E
5 minutesyrr
E
100
lo
curves
on Aluminium
brass
(-----)
electrodes
prefil
med
( -)
electrodes
pi-e-treated
in aerated
in
10F3M
BIE
in distilled
0.1 at
N NaCl 55’C
water
at
for 55OC
V/SCE .
= -0.203
cot-r-
- 0.8,
1
0.1
Fig.
6 b.
solution
’ r Cathodic of
5 minutes, at
85*C
p&7, E
for
A .cm-2
I
I
IO
100
pal arization T=X°C: = -0.214
Y?*&k&es,
curves
(-----) V/SCE; E
corr
on Aluminium
electrodes (------
= -0.192
prefiimed
1 electrodes V/SCE.
brass in
in3aerated 10
pre-treated
M BIE
0.1 at
N NaCi 85%
in distilled
for water
344 For to that
the
prefilmed
obtained
with
decreasing
of the
up to -0.6
V/SCE.
At smaller
pH=7
increasing V/SCE,
pH=9
the
wered
the
Figures polarization ced
on
water
inhibited.
sion
in
sing
the
which
10
7d,
indicates After
non-prefilmed of and
specimens did
not
two
of
cathodic than
prefilmed
curve
ViSCE,
potentials
the
are
for
It
for
ten
times
to disappear
more
almost
prefilmes
at pH=7. curves
polarization
are
tends
close
a sl ight
cathodic
difference
very
being
electrodes
electrodes
that
the
is
negative
the
prefil
be
seen
med
and
than
same.
electrodes
can
by
At is
that
lo-
starting
non-prefii
med
the
influence
electrodes
of
prefilmed
at pH=7,
are
ming
agent the
must
is
be
the
shown.
for
same
It
that
the
figures
tra-
the
catho-
immersion
in
appears
become
blocking
these
Cathodic
5 minutes,
cl early
curves
under
into
85OC
in a 5 minutes
show
Electron
temperature.
and
On
cathodic
formed
taken
Scanning
55O
also
the water
which
at
consisting are
in distilled
prefilming
reported.
temperature,
oxide,
the
that,
more
action
conditions.
and
more
cannot A
be
specific
account.
Microscope
observations
under
the
va-
conditions. b,
and at
c,
refer 55*
25O,
the
high of three
that
the
hours
the
surface
85’C,
and
of
specimens It
respectively.
it increases
aspect
the
brightness
area of
after
is
immer-
that
increa-
evident
covered
the
5 minutes
with
specimen
by
a surface
and
which
product is on1 y
magnifications. these
surfaces
with
temperatures,
for
surface
must
layer
immersion
specimens prefilmed present
to and
temperature,
very
192
of
electrode
temperatures,
tests
change
same
part
for
a pre-treatment
10 show
not
the
the
after
M BIE
at
show
surface
A comparison at
6b
prefilming
prefilming
evidenced
of -0.45
the
7a,
does
the
difference
This
kinds
compressed
chloride
experimental
-3
two
where
for
prefil
Figures
the
at pH=5
only
ones.
in fact
traced
ctose.
blank
7 -
for
more
and
to the
of the
potential;
value
the
Figs.
non-prefilmed
region
at
The
attributed
ter
the
very
increasing
rious
for
obtained
led
effect
values
N sodium
curves
distil
density
curves
in 0.1
dic
current
curves
6a
the initial
far
are
electrodes, the
potential
electrodes
curve
during
cathodic
is
cathodic
density
potential
down,
non-prefilmed
on the
the
the
current
those
the
-0.6
from
the
than
electrodes,
appeared at
any
in 0.1
the
attack
to be
three even
those which be
of
no surface attributed
N sodium highly
were
immersed
in distilled
modification to
chloride
corroded,
temperatures if they
samples
maintained observed
the
inhibitive
at pH=?, Fig.
occurs,
the
8,
while
their
initial
at high
waFig.
species. surface the
of
surfaces
brightness
magnification.
7d
7c
Fig.
7.
SEM
10-3M c)
prefilmed
at
85OC
slight
in any
The to
where is
10e3M
the
shown.
Aluminium
brass
prefilmed
85OC
for
in
5
all
surface can
time
min.;
after
simple of
of be
test,
specimens:
lo-
3 M
d)
pre-treated
a seen
specimen that
the
fig.
BIE
a)
at
prefilmed
55OC
for
in
distilled
to
552
in
5
min.; water
solution,
25°C
was
observed,
fig.
samples
up
9a.
leading
Prefil
prefilmed
hours,
ming at
85OC
to
at
a the
55OC
did
forma-
resulted
not
present
85OC
did
fig.
10,
9b.
immersion oxides,
in
distilled is
pre-treated after
test
products, and
protective
the at
corrosion
this
that
in
prefilmed
resistance,
formation
It
of b)
immersion
distributed
evidence
the
at
specimens
corrosion
the
4000)
min.;
BIE
the
uniformly
at
5
min.
on
better
(X
for
prolonging
attack
lead
25OC
in 5
attack of
a
at
for
By
tion
micrographs
BIE
192
given for
hours
water
5
in
the
at
and
photograph
minutes
immersion
55’C
in in
distil the
0.1
of led
water
N
sodium
at
not
85°C
chloride
346
Fig.
8.
SEM
immersion
micrograph
in 0.1
solution
at
pH=7,
however
it
is
The test pH=3
cl early
of pH=3
samples, was
of
non-prefilmed
is
higher
compared
and
9,
attack,
after
not
as
of by
marked
as
to the
prefil
film
formed
the
carrying
only
slightly
Even
in the
this
out smaller case
brass
after
192
hours
med at
non
of the
samples,
specimens. 25“C
hours than
pre-treated
was
also
immersion
that
experiments.
observed
solutions
considered
on the
at pH=9
in At
non-pre-
a moderate
at-
test.
9b
9.
SEM
5 minutes, a)
on the
192
9a
Fig.
Aluminium
of pH=7.
attack
appeared.
obtained
340)
solution
effectiveness
a generalised
filmed tack
the
protective
solutions
(X
N NaCl
prefilming
micrographs
after
552
hours
temperature
(X
340)
of
immersion 25°C;
Aluminium in 0.1
b) prefilming
brass
N
NaCl
prefilmed solution
temperature
85’C.
in
10
of pH=7:
-3
M BIE
for
347
Fig. at
10.
SEM
85OC
lution
for
micrograph
5 minutes
(X
and
350)
of Aiuminium
subsequently
brass
immersed
pre-treated
for
192
in distilled
hours
in 0.1
water
N NaCi
so-
of pH=?.
CONCLUSIONS The ments
overall
containing
protective
chloride
pH
10
that
the
the
in neutral
of
seems
I ocal
attacks
ized As
far
that
the
films
protective
pH
a duration
5 minutes
prefilming of
action
ceases
numerous
the
after
markedly
solution.
film
192
brass,
lasts
It
hours.
smaller
In for
Even
than
acidic
a very for
that
so-
whose
temperature.
test
of the
experi-
in a aqueous
on aluminium
the
on the
of the
of
I ayer
increasing
completely
have
results
treatment
depends
and
the
a surface
with
resistance
as
tal-inhibitor The 500
layer,
by
were
higher
observed
that
due
hours), stabilizing
shown
by
I imits
course
it
interaction
of BIE
on the
protective
suggests
that
it and means
the
to an
compound the
as
mechanism
strongly
surface
in the
uniformly
protective
film be
film,
of the
is
evidenced
is
concerned,
immersion by
the
in the
fact
that
aggressive
in no case
observed.
adsorption
fact
(over
surface
the
may
the
the
to occur
the
effect
viously
produces
minutes)
from
a prefilming
increase
protective
solution,
through
30
out
solutions.
Removal
This
that
environments,
(about
values,
comes
M BIE,
film
containing time
dicate
-3
characteristics
shown
short
which
indicates
performed,
lution
was
picture
by
can
cathodic between metal
also
be
action,
at
the
inhibitor
lowering
of photo-effects
its
or
current the
considered at
measurements
density
oxide.
for and
The
tests
oxygen the
reduction.
metal
formation
in-
surface, of a me-
(7,8). pH=7,
undergoes electronic
electrochemical
inhibitor
on the
least
the
an
lasts
for
a very
interaction
with
conductivity, (5).
as
is
long the was
time oxide
pre-
348 ACKNOWLEDGMENT The authors tal
have
appreciated
the help
of Dr.
R.
Nagliati
with
the experimen-
work.
REFERENCES 1
G. TRABANELLI, Korros.
2
F.
F.
ZUCCHI,
G.
BRUNORO,
V. CARASSITI
- Werkstoffe
u.
, 23, 602 (1973).
ZUCCHI,
G.
BRUNORO,
G. TRABANELL
I - Werkstoffe
G.
TRABANELL
I - Metall.
ZUCCHINI
- Mater.
u.
Korros.,
2,
834
(1977). 3
F.
ZUCCHI,
4
G.
BRUNORO,
F.
ZUCCHI,
M.
5
G.
BRUNORO,
F.
ZUCCHI
, M.
Symp. 6
P.
G. BRUNORO,
Corros.
Inhibit.,
SPINELLI,
Korros.,
3l,
7
N.
D.
8
T.
NOTOYA,
M.
MAJA,
Ferrara,
MAJA,
G.
P.
1980,
BRUNORO,
SPINELLI
p.
Ital., Chem., -
69, 5,
Proc.
493 (1977). 135 (1980).
of the
G.
TRABANELLI
- Werkstoffe
918 (1980).
HOBBINS,
R.
F.
ROBERTS
J. W. POLING
-
Surface
- Corrosion,
5th Europ.
977.
Technol.,
35_, 193 (1979).
2,
235 (1979).
u.
ELECTROCHEMICAL PREFILMED
G.
AND
Centro
and
di studi
mica, O”
MORPHOLOGICAL
ALUMINIUM
BRUNORO’
0
Via
L.
Corso Received
P.
SPINELLl
sulla
degli
46,
“A.
Dacco”,
FERRARA
1982;
e lngegneria
TURIN
24,
Universita
di Ferrara,
lstituto
Chi-
(Italy)
dei Materiali
Abruzzi
8 November
OF
O”
Corrosione
di Scienra
Duca
CHARACTERIZATION
BRASS
Borsari
Dipartimento
337
accepted
Chimica,
Politecnico
di Torino,
(Italy)
6 December
1982
ABSTRACT
Electrochemical with
and
morphological
Benzimidazole-2-thioi
rious
plls.
tective
of
action
of
film.
between
mitation
layer
as
/ NTRODUCT The
inhibitor
cathodic
shown
in 0.1
the
immersion
in the
sodium
giving
rise
and
metal
seems
to be
current
density of the
for
oxygen
inhibitor
with is
resistance
brass
chloride
layer
temperature
film
never
the
Alum~nium
sodium
a surface
prefilming
that
of N
occurs,
a consequence
to
very
chloride
on the
solution,
localized
reduction.
interaction
is
for
va-
pro-
the
pro-
pH
of the
a uniform
attack.
responsible
of
good
increase
depends
to
prefilmed
solutions
An
inter-
a marked
A stabilization
ii-
of the
suggested.
I ON
protective
effectiveness
copper
and
copper
proved
the
practical
nium
film
made produces
of the
was
prolongued
surface the
of the
effect
It
Upon the
characterization
was
treatment
The
the
solution.
removal
oxide
prefilming
properties.
tectivity test
The
(BIE)
alloys,
of Benzimidazol
has
been
importance
of
e-2-thiol
investigated this
(BIE)
in a series
substance
as
as
an
of papers
a prefilming
inhibitor
for
(I-4)
which
for
Alumi-
agent
brass. Recently
tored
by
prefilming it was
(5)
treatment.
I ast
et ectrochemical a sol ution
growth
el lipsometry,
immersed
These
the
thus
of
the
individuating
Characterization
in an aggressive results
suggested
properties
containing
copper-inhibitor
of the
of
the
optimal
the
film
environment to extend films
film
was the
formed
during
experimental
properties also
and
Aluminium
was
conditions its
investigated
investigation on
prefilming
for
behaviour
the when
(6).
to morphological brass
moni-
by
and
immersion
in
BI E.
0
Etsevier Sequoia~~nted
in The N~therlaRds
338 This
paper
observations
reports
and
filming
temperature
EXPER
I MENTAL
The were The
electric
back
(0.25
Prefilming of
curves
were
thodic
branch
not
only
chloride
prefilmed
electrodes
The in
at
stirred
obtained tests
for
192
the
(5-6).
to evaluate
ratures.
These samples
of cast
n.
films
the
both
effect
by
SEM
of the
Aluminium
an
exposed
wire,
sealed
800
emery
electrodes
for
These
pre-
brass
surface
and
of 2 cm’.
J
in a smal
paper
and
which
had
been
curves
were
glass
then
alumi-
to
localized
at
at
desired
After
was
of nor-
prefilming,
the
in air.
sodium
chloride
25OC.
Anodic
to
those
tests
55O and
various
affects
obtained
were
the
with
performed
85OC
water
at
rest
at
polarization
substantially
the
amount
temperature
in distilled
on prefilmed
aspects
protective
proved,
started
solutions
in 0.1
same
in a neutral
at
and
ca-
nonin 0.1
with
non-
5S”
or
85’C
potentiai
and
were
which
were
192
hours
car-
.
samples
hours
N
BIE
prefilmed
were
made
chloride
The
the
85OC.
compared
pre-treated
-1
1 mV.s
adding
dried
at
with
range.
electrodes
of
prefilmed
were
for
the
tests
pH
and
in 0.1
prefilming
5 minutes
prefilming
and
traced
curves
same
55”
water
ef ectrodes
by
The
at
led
were
morphological
552
made
pH=7
rate
prepared
water.
were
since
in the
the
was
in distil
non-prefilmed and
in order
prefiimed
on
N sodium
with
bars
with
immersing
curves
observations
The
temperature.
ar,
a copper
polishing
tests
Polarization
0.1
particui
to obtain
through
solution
rinsed
9)
at
a scan
SEM
in order
considered,
N sodium
out
resin
by
some
7 and
5 minutes.
of cylindrical
to bi-distilled
was
electrodes
ried
BIE
but
prefilmed
for
such
electrode.
The
polarization 5,
In
out
included
BIE.
surface
(pH=3,
studying
account.
made
obtained
reagent
Cathodic pHs
the
by
tests.
into
cut
was
of
was
25 2 1 OC,
electrode
obtained
pm).
10W3M
grade
mally
were
preparation
na polishing
solution
taken
in “Epophix”
the
Surface
pure
was
connection
from
results
electrochemical
electrodes
embedded
tube,
by
the
at pH=3, of the
under
the
N sodium
attack.
same
time,
7 and
samples same
chloride
effectiveness the
electrodes 9 for
were
conditions.
very
at pH=7 at
scarce
the
at
room
to those
Moreover,
solutions
of prefilming the
compared
immersed
immersion were
various
tendency
made tempe-
of the
339 RESULTS
AND
1
Fig. rious
Dl SCUSS
shows
the
experimental
dium
chloride
electrodes
for
with
occur.
30
of
the
minutes.
increasing
It
of cupric
the
ions
can
potentials
be
solution nobler
as
seen
pH.
noble
a consequence
been
the
non-prefilmed to -0.201
no appreciable
variation
potential
va-
N so-
-0.136
electrode
of alloy
the
in 0.1
of the
(from
pH=7,
under
immersed
potential
values
of the
1 recorded,
corr
had
that
Above
values
(E
which
I ess
towards
the
that
rest
on electrodes
displace
We argued
presence
values
conditions,
markedly
V/SCE)
ION
were
due
did to
the
dissolution.
-0.10 _
* “/SCE
:
-0.15
A
_
\ ‘lo, O-0
\
-0.20.
-0
t -0.25.
Fig.
1.
pH:
0
*
Corrosion
some the
this
tests.
minutes
As
potential
very
Prefiiming of the
test
at pH=5
there
towards
positive
in 0.1
the
toward
to
25’YI
solution. seems
that
to be
values
of
cupric positive
ions
pH=3
no effect,
does
occur
addition,
an
was
5.10
-5
the
potential whereas (see
fig.
as
a function
of
electrodes;
at pH=3;
added
to the
immediate
A
non-pre-
For
M cupric
chloride,
without
of prefilmed at pH=?
and
example, an
cupric
potential,
solution
in
displacement
observed.
electrode
1).
N&I,
non-prefiimed
pH=3.
were
in a solution
affects the
at
ions
values
determined
N
l
+ 5. 10m4M CuC12 CuC12
cupric
containing
differently At
N NaCl
amounts
in 0.1
T=25%;
+ 5.10-‘M
in a sol ution
close at
of
brass
low3 M f3lE,
N NaCl
small
a result
immersion
potential
pH
in 0.1
reason,
electrode
in
electrodes
electrodes
PH
of Al uminium
ei ectrodes
non-prefilmed
For
9
potentials
prefiimed
filmed
7
5
3
ions
after
9 a small
is
30
electrode was
depending
electrodes
of
obtained. on the
I ess
noble,
displacement
340
I owering
The sing of
of cupric
the
been
film.
ions On
reported
filming stabil
electrode
other
previous1 may
effect
Figures
the
y (2)
be
show
the
various
pHs,
observed
that
the
polarization
for
the
first
for
the
curves
of part
the
of the
traced
a consequence increase and
explained
by
was
attributed
of the
in the copper
initial
potential alloys
to the
decrea-
protective
at
pH
7,
in the
presence inhibitor
the
adsorption
of the
polarization
curves
obtained
action which
has
of preor
by
its
oxide.
cathodic
both
on prefil curves
current
at pH=3
on copper
surface
at
values
the
simply
sol utions
smaller
as
hand,
on the
2 - 5
potential
concentration
the
agents, izing
of
density,
cathodic
med
for
and
the
non-prefilmed
prefilmed
compared
The
electrodes.
electrodes
to the
polarization.
in sodium It
always
can
be
present
non-prefilmed
ones,
noticeable
differences
most
chloride
at
least appear
at pH=7.
-0.5 _
-0.8
_ 0.1
Fig.
A.om-*
2.
Cathodic
solution (-----)
prefil
By curve low
of pH=3, med
anal ysing for
the
polarization.
non
polarization T=25OC: electrodes,
the
curves (-----I E
polarization
prefilmed
100
lo
on Aluminium non-prefi
corr
= -0.165
curves
electrode
I med
in aerated E
V/SCE.
in detail,
exhibits
brass
electrodes,
it can
a maximum
be
seen
current
0.1
corr
N NaCl
= -0.136
that density
V/SCE;
at pH=3
the
vat ue at
341
Fig.
3.
solution (-----)
Cathodic of pH=5, prefilmed
polarization
curves
( -_)
T=2S°C: el ectrodes,
\ “/SW
\
.
E
.
on Aluminium
non-prefilmed = -0.177
corr
-.
brass electrodes,
in aerated E
V/SCE.
corr
0.1 = -0.173
N NaCl V/SCE;
\
-0.5 _
: I I I1
-0.8 _
0.1
),.c,,,-~
100
lo
'r
Fig.
4.
solution (-----)
Cathodic of pH=7, prefilmed
polarization T=25”C: electrodes,
curves
( -)
on Aluminium
non-prefilmed E
corr
= -0.180
brass electrodes,
V/SCE.
in aerated E
corr
0.1 = -0.201
N NaCl V/SCE;
342 Tests peak
carried
of the
current
thodic
polarization
V/SCE,
which which
cess,
hydrogen
is
ions
by
by
is
been
even
in this
of
oxygen
occurs
at
more
is
the
not
under
potential
step
reduction
pH
affected,
and
control
appears after
and
action peak
while
on the
ions. at
that
seems
this
first
When
the
ca-
about
-0.4
a third
pro-
to be due
to
value.
reduction
vat ues
confirmed
controlled
protective
ions
substantially
negative
solution,
of cupric
diffusion
initial
cupric
the
reduction
to oxygen
an
the
to the
corresponding
to exert of
to
a diffusion
case
at
absence
ions
to be due
attributed
reduction
duction
cupric
increased,
seems
the
adding
density
has
Prefiiming shown
out
even
at pH=3,
on the
the
cathodic
discharge
prefilmed
as
it
is
curve.
Re-
of hydrogen
ions
el ectrodes.
-0.2
\ V/SCL
\ \ \ \
-0.5
\
.
\
-0.t I _
.
_ _
0.1
Fig.
5.
Cathodic
solution (-----)
trend. with can be
There
is a slight
be
close
to for
oxygen the
galvanostatic
conditions.
It
was
initiates
at
shown
tests
a potential
of
E
non-prefilmed
The
and first
whereas
carried
in aerated
polarization
which
one,
that,
for
densities.
reduction,
second
of
I ow
brass electrodes,
V/SCE.
curves
at
current
med
-0.190
cathodic
fexion
in a series
oxide
Ecorr=
the
I imiting
attributed
responsible
9,
on Aluminium non-prefil
electrodes,
7 and
very
curves ( -)
T=25%:
pH=5,
_ __
100
lo
P
polarization
of pH=9, prefilmed
At
A.,3,,-2
l
out
in the
solution
-0.45
V/SCE.
corr
two
of these of cuprous
at
-0.45
V/SCE.
strict1
y control
under under
test,
the
V/SCE;
have
reduction
reduction
appears
N NaCl
electrodes
then
one
0.1
= -0.203
two
This
reduction
processes
processes,
oxide
led
similar
seems was
to
shown
experimental of cuprous
343
-0.8
’ r
,,.~,,'2
Fig.
6 a.
solution
Cathodic of pH=7,
5 minutes, for
polarization T=2S°C: = -0.181;
E
5 minutesyrr
E
100
lo
curves
on Aluminium
brass
(-----)
electrodes
prefil
med
( -)
electrodes
pi-e-treated
in aerated
in
10F3M
BIE
in distilled
0.1 at
N NaCl 55’C
water
at
for 55OC
V/SCE .
= -0.203
cot-r-
- 0.8,
1
0.1
Fig.
6 b.
solution
’ r Cathodic of
5 minutes, at
85*C
p&7, E
for
A .cm-2
I
I
IO
100
pal arization T=X°C: = -0.214
Y?*&k&es,
curves
(-----) V/SCE; E
corr
on Aluminium
electrodes (------
= -0.192
prefiimed
1 electrodes V/SCE.
brass in
in3aerated 10
pre-treated
M BIE
0.1 at
N NaCi 85%
in distilled
for water
344 For to that
the
prefilmed
obtained
with
decreasing
of the
up to -0.6
V/SCE.
At smaller
pH=7
increasing V/SCE,
pH=9
the
wered
the
Figures polarization ced
on
water
inhibited.
sion
in
sing
the
which
10
7d,
indicates After
non-prefilmed of and
specimens did
not
two
of
cathodic than
prefilmed
curve
ViSCE,
potentials
the
are
for
It
for
ten
times
to disappear
more
almost
prefilmes
at pH=7. curves
polarization
are
tends
close
a sl ight
cathodic
difference
very
being
electrodes
electrodes
that
the
is
negative
the
prefil
be
seen
med
and
than
same.
electrodes
can
by
At is
that
lo-
starting
non-prefii
med
the
influence
electrodes
of
prefilmed
at pH=7,
are
ming
agent the
must
is
be
the
shown.
for
same
It
that
the
figures
tra-
the
catho-
immersion
in
appears
become
blocking
these
Cathodic
5 minutes,
cl early
curves
under
into
85OC
in a 5 minutes
show
Electron
temperature.
and
On
cathodic
formed
taken
Scanning
55O
also
the water
which
at
consisting are
in distilled
prefilming
reported.
temperature,
oxide,
the
that,
more
action
conditions.
and
more
cannot A
be
specific
account.
Microscope
observations
under
the
va-
conditions. b,
and at
c,
refer 55*
25O,
the
high of three
that
the
hours
the
surface
85’C,
and
of
specimens It
respectively.
it increases
aspect
the
brightness
area of
after
is
immer-
that
increa-
evident
covered
the
5 minutes
with
specimen
by
a surface
and
which
product is on1 y
magnifications. these
surfaces
with
temperatures,
for
surface
must
layer
immersion
specimens prefilmed present
to and
temperature,
very
192
of
electrode
temperatures,
tests
change
same
part
for
a pre-treatment
10 show
not
the
the
after
M BIE
at
show
surface
A comparison at
6b
prefilming
prefilming
evidenced
of -0.45
the
7a,
does
the
difference
This
kinds
compressed
chloride
experimental
-3
two
where
for
prefil
Figures
the
at pH=5
only
ones.
in fact
traced
ctose.
blank
7 -
for
more
and
to the
of the
potential;
value
the
Figs.
non-prefilmed
region
at
The
attributed
ter
the
very
increasing
rious
for
obtained
led
effect
values
N sodium
curves
distil
density
curves
in 0.1
dic
current
curves
6a
the initial
far
are
electrodes, the
potential
electrodes
curve
during
cathodic
is
cathodic
density
potential
down,
non-prefilmed
on the
the
the
current
those
the
-0.6
from
the
than
electrodes,
appeared at
any
in 0.1
the
attack
to be
three even
those which be
of
no surface attributed
N sodium highly
were
immersed
in distilled
modification to
chloride
corroded,
temperatures if they
samples
maintained observed
the
inhibitive
at pH=?, Fig.
occurs,
the
8,
while
their
initial
at high
waFig.
species. surface the
of
surfaces
brightness
magnification.
7d
7c
Fig.
7.
SEM
10-3M c)
prefilmed
at
85OC
slight
in any
The to
where is
10e3M
the
shown.
Aluminium
brass
prefilmed
85OC
for
in
5
all
surface can
time
min.;
after
simple of
of be
test,
specimens:
lo-
3 M
d)
pre-treated
a seen
specimen that
the
fig.
BIE
a)
at
prefilmed
55OC
for
in
distilled
to
552
in
5
min.; water
solution,
25°C
was
observed,
fig.
samples
up
9a.
leading
Prefil
prefilmed
hours,
ming at
85OC
to
at
a the
55OC
did
forma-
resulted
not
present
85OC
did
fig.
10,
9b.
immersion oxides,
in
distilled is
pre-treated after
test
products, and
protective
the at
corrosion
this
that
in
prefilmed
resistance,
formation
It
of b)
immersion
distributed
evidence
the
at
specimens
corrosion
the
4000)
min.;
BIE
the
uniformly
at
5
min.
on
better
(X
for
prolonging
attack
lead
25OC
in 5
attack of
a
at
for
By
tion
micrographs
BIE
192
given for
hours
water
5
in
the
at
and
photograph
minutes
immersion
55’C
in in
distil the
0.1
of led
water
N
sodium
at
not
85°C
chloride
346
Fig.
8.
SEM
immersion
micrograph
in 0.1
solution
at
pH=7,
however
it
is
The test pH=3
cl early
of pH=3
samples, was
of
non-prefilmed
is
higher
compared
and
9,
attack,
after
not
as
of by
marked
as
to the
prefil
film
formed
the
carrying
only
slightly
Even
in the
this
out smaller case
brass
after
192
hours
med at
non
of the
samples,
specimens. 25“C
hours than
pre-treated
was
also
immersion
that
experiments.
observed
solutions
considered
on the
at pH=9
in At
non-pre-
a moderate
at-
test.
9b
9.
SEM
5 minutes, a)
on the
192
9a
Fig.
Aluminium
of pH=7.
attack
appeared.
obtained
340)
solution
effectiveness
a generalised
filmed tack
the
protective
solutions
(X
N NaCl
prefilming
micrographs
after
552
hours
temperature
(X
340)
of
immersion 25°C;
Aluminium in 0.1
b) prefilming
brass
N
NaCl
prefilmed solution
temperature
85’C.
in
10
of pH=7:
-3
M BIE
for
347
Fig. at
10.
SEM
85OC
lution
for
micrograph
5 minutes
(X
and
350)
of Aiuminium
subsequently
brass
immersed
pre-treated
for
192
in distilled
hours
in 0.1
water
N NaCi
so-
of pH=?.
CONCLUSIONS The ments
overall
containing
protective
chloride
pH
10
that
the
the
in neutral
of
seems
I ocal
attacks
ized As
far
that
the
films
protective
pH
a duration
5 minutes
prefilming of
action
ceases
numerous
the
after
markedly
solution.
film
192
brass,
lasts
It
hours.
smaller
In for
Even
than
acidic
a very for
that
so-
whose
temperature.
test
of the
experi-
in a aqueous
on aluminium
the
on the
of the
of
I ayer
increasing
completely
have
results
treatment
depends
and
the
a surface
with
resistance
as
tal-inhibitor The 500
layer,
by
were
higher
observed
that
due
hours), stabilizing
shown
by
I imits
course
it
interaction
of BIE
on the
protective
suggests
that
it and means
the
to an
compound the
as
mechanism
strongly
surface
in the
uniformly
protective
film be
film,
of the
is
evidenced
is
concerned,
immersion by
the
in the
fact
that
aggressive
in no case
observed.
adsorption
fact
(over
surface
the
may
the
the
to occur
the
effect
viously
produces
minutes)
from
a prefilming
increase
protective
solution,
through
30
out
solutions.
Removal
This
that
environments,
(about
values,
comes
M BIE,
film
containing time
dicate
-3
characteristics
shown
short
which
indicates
performed,
lution
was
picture
by
can
cathodic between metal
also
be
action,
at
the
inhibitor
lowering
of photo-effects
its
or
current the
considered at
measurements
density
oxide.
for and
The
tests
oxygen the
reduction.
metal
formation
in-
surface, of a me-
(7,8). pH=7,
undergoes electronic
electrochemical
inhibitor
on the
least
the
an
lasts
for
a very
interaction
with
conductivity, (5).
as
is
long the was
time oxide
pre-
348 ACKNOWLEDGMENT The authors tal
have
appreciated
the help
of Dr.
R.
Nagliati
with
the experimen-
work.
REFERENCES 1
G. TRABANELLI, Korros.
2
F.
F.
ZUCCHI,
G.
BRUNORO,
V. CARASSITI
- Werkstoffe
u.
, 23, 602 (1973).
ZUCCHI,
G.
BRUNORO,
G. TRABANELL
I - Werkstoffe
G.
TRABANELL
I - Metall.
ZUCCHINI
- Mater.
u.
Korros.,
2,
834
(1977). 3
F.
ZUCCHI,
4
G.
BRUNORO,
F.
ZUCCHI,
M.
5
G.
BRUNORO,
F.
ZUCCHI
, M.
Symp. 6
P.
G. BRUNORO,
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Inhibit.,
SPINELLI,
Korros.,
3l,
7
N.
D.
8
T.
NOTOYA,
M.
MAJA,
Ferrara,
MAJA,
G.
P.
1980,
BRUNORO,
SPINELLI
p.
Ital., Chem., -
69, 5,
Proc.
493 (1977). 135 (1980).
of the
G.
TRABANELLI
- Werkstoffe
918 (1980).
HOBBINS,
R.
F.
ROBERTS
J. W. POLING
-
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