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Electrochemical behaviour of (nominally) iron disilicide electrodes in sulphuric acid
Materials
Chcmistr!,
and Ph!,sics,
ELECTROCRJHICAL IN SIJLPWRIC
19
215
( 1988) 2 I S-328
BEBAVIOUR OF (NOMINALLY)
IRON DISILICIDE
ELECTRODES
ACID
A.K. VIJH, G. BELANGER
and R. JACQUES
Institut
de recherche
d'Hydro-Qugbec,
Received
July 22, 1987; accepted
Varennes,
September
Quebec,
JOL 2PO (Canada)
8, 1987
ABSTRACT
Iron
disilicide
metallic
lustre
trode material
(FeSiq)
composition
to its electrochemical
electrocatalytic
metal
(see text)
displays
behaviour
of elec-
has been
examined
cathodic
typical
some
which
and its possibly
stability,
towards
properties
intermetallic
The electrochemical
and high conductivity. of this nominal
H$O,, with regards ing
is a transition
in 1N
interestanodic
and
reactions. The
remarkable
visible
of potentials, some
erosive
noted,
property
signs of electrode
side,
(>l A cm-*) without rates
anomalously
are
V
there
of
high
of a deposit
anodic
potentials
on the electrode
extremely
(2 1.5
high rates
no
(>5 V),
surface
of hydrogen
the overpotentials
damage; V),
Also
however.
side, up to 3.0 V, only a transition
reduction
galvanostatically behaviour
(or more), is
high
is observed;
or for the oxygen polarized
it permits
any surface
quite
On the anodic
40
formation
it displays
etc. in a wide range
is
required
the Tafel
evolution to sustain
slopes
have
high values -ca 5-6 F.
oxide growth,
type
and/or
is that
exfoliation
however.
On the cathodic
such
material
erosion,
-1.6 V to 3.0 V; at very
e.g., attack
electrode
of this corrosion,
also
no activity reaction
with
some
could
in
signs
concomitant
that of
the
evolution
growth
typical
these
at
of
reaction
the electrode
occurs
breakdown at
characteristic evolution
When
densities,
oxide
dielectric
oxygen
region,
the oxygen
be detected.
to very high current
is observed
some
for either
is
valve metal up
that
levels
to around potential; of
anodic
polarization.
0254-0584/88/$3.50
0 Elsevier Sequoia/Printed
in The Netherlands
216
In
solutions
passivation
containing
Tafel
line
.observed are extremely semiconducting)
organics
activity
the
transition
the chlorine
high (= 10 F),
surface
The possible cal
NaCl,
(for
region
evolution)
enters
around
characteristic
of
into
a
post-
4.0 V; the slopes non-conducting
(or
layers on the electrode.
activity
(CH$OO-,
of these electrodes HCOO-,
could be detected,
NH2-NH2
for the anodic
and
CH30H)
was
oxidation
also
of typi-
examined;
no such
however.
INTRODUCTION
Perhaps
the most-desired
surfaces
displaying
chemical
stability.
available,
coatings ting
to achieve
[l-3], chemical
oxides
involves
so
highly
both
with
conducting the early
with
e.g.,
that
does
of noble such
concomitant
be
not
based
have
to
of
electro-
on
readily-
rely
on
of approaches
based
on special
an
have alloy
[4,5] and the use of conducmetals
as
the
[6]. sodium
of these materials
electrochemical
is the discovery
A number
of surfaces
non-metals
to
one
and
must
electrocatalysts
traces
promise
regard
surfaces
noble metals.
modification
in conjuction
although
[7,gl, time
materials
this goal,
properties
such
use of rare and expensive
made
electrochemistry
electrocatalytic
Furthermore,
inexpensive
extensive been
good
goal in modern
Another
approach
tungsten
bronzes
did not stand the test of
stability
and
electrochemical
activity. Intermetallic some
cases,
occur
sive media
report
to
be
examine
namely,
formula
istics,
can
investigates
silicides, the
and
acids.
which
[9].
addition
another
to
the
attractive
inexpensive
can
have
Since
metallic
some
of
lustre
these
materials. of
aforementioned
The present one
desirable
in abundance
and
it is of
of
these giving
character-
from our point of view:
produced
in
compounds
stability,
behaviour
can,
many corro-
Fe 50%; Si 50%, by weight,
feature
material
silicides,
and chemical
as electrode
(nominally
e.g.
are inert towards
electrochemical
iron disilicide
available
hard
they behave general
In
metals,
The compounds
unusually
how
FeSi2).
solids
of high conductivity
the
it possesses
a readily
transition
as hard metallic
the requirements
interest
of some
such as strong
conductivity fulfill
compounds
it is
by the Quebec
mines.
EXPERIMENTAL
SECTION
Cell A
conventional
with gas inlets
three-compartment
and outlets
[LO]
Pyrex
electrochemical
was used for the
measurements.
cell
provided The three
217 could
compartments isolated
be
separated
from the ambient
by
atmosphere
solution
-
sealed
by water-filled
stopcocks
and
bubblers.
Electrodes Iron
disilicide
has
from 'SIDBEC DOSCO', The
real
analysis,
nominal
composition
would
FeSi, with
chromium
understood
composition,
Qugbec,
and
was
obtained
was
found,
by X-ray
diffraction
Si = 41.6 %; Fe = 56.4 %; Cr = 2.2 X.
correspond
[lo]
to a mixture
of FeSi2
In the context
as an impurity.
that
FeSig
Canada.
of the material
to be as follows:
composition
thus
the
Contrecoeur,
the composition
(or Fe$iS)
of this
of the electrode
This
paper,
is only
and it is
nominally
FeSip. The melted
small
lumps
in a vacuum
were
in
placed
The large
furnace.
a surface
of about 0.314 cm*, which
the piece
in Kel-F.
The working
600 grit on a silicon doubly-distilled The
counter
deionized
in heat-shrinkable Hydrogen
CORROSION
For
before
crucible
surface
was
and
was cut to get
to the solution
The electrodes
by sealing
polished
down
were then washed
to
with
using.
from a vitreous
graphite
rod mounted
tubing. were used.
employed
for the measurements
model
a Corrosion
332
System
Software
Hewlett-Packard
variable
power potentiostat
power
(PRT200-IX)
potentials
Princeton
Applied
for use with
were
printed
of
Apple
on an Epson
II.
galvanostatic supply
measurements
(50 V; 500 mA),
in a galvanostatic
were followed
EG/G
Diskette
the results
in line with an Apple
the high-current-density
in Figs. 1-8 consisted
(from
Program
(64 K ram from EG 6 G);
recorder
electrode
alumina
piece thus obtained
electrode
made
electrodes
SOFTWARE
using
II Computer FX-8W-
purity
and Measurements
The instruments a
water
high
was exposed
wheel.
were
Teflon
reference
Instruments
Research)
carbide
electrodes
a
(Fig. g-11),
a
or a Tacussel
high
mode were employed.
The
on an X-t Omega recorder
(Model 585).
Solutions The main ized,
solution
was made
doubly-distilled
(e.g., NaCl, HCOOK,
water.
CHBOH,
from Ultrex To
CHSCOOK
The rest of the procedures
this
sulphuric solution,
acid (IN)
and deion-
appropriate
additives
etc.) were added, as required.
were as in our other recent work
[11,12].
218 RESULTS MD
DISCUSSION
.Electrode Behaviour in the Potential Region, -1.6 V to 3.0 V
The most striking feature of the present electrode material was its shining, metallic appearance which remained completely unchanged even under drastic conditions of prolonged hydrogen evolution at high rates (1 1 A cm-') or on polarization to high (= 3 V) anodic potentials even in extremely aggressive media, e.g., containing NaCl; some electrode attack, however, is observed at extremely high ( >5 V) anodic potentials - see below.
There were
no
visible
signs of corrosion, erosion, growth, deposits, swelling, exfoliation, mechanical distortion or other changes usually seen on other electrode materials under these conditions, except at extremely high anodic potentials.
For example,
under conditions of gas evolution at such high rates, even high-pressure graphite shows visible erosion with the concomitant particle accumulation in the
solution; no
such disintegration was
noted for the iron disflicide,
however.
i$Ei~,, Fig. 1.
-400
-200
, t * f , , ,~ 0
200 400 600 E vs RHE (mV1
800
WOO
A cyclic voltammogram on nominal FeSi* in IN H2S04 with nitrogen bubbling in the working compartment; scan rate is 100 @I/s.
The
anodie peak seen in this first scan, at around 600 mV disappears in the subsequent scans to give a hysteresis region.
A general potentiodynamic profile on a freshly-polished Fe-Si electrode is shown in Fig. 1; a vestigial anodic peak at around 0.7 V is seen on the first sweep.
On repeated cycling this peak disappears giving rise to a small hyster-
esis between the ascending and the descending sweeps. A steady state, potentiostatic current-potentialrelationship for the hydrogen evolution is presented in Fig. 2.
An excellent Tafel region over several
219
IO-*
Fig.
2.
A
106
cathodic
obtained a long
decades being
Tafel
of very
Tafel
region
high Viz. of
by
hydrogen
evolution
the
the
down to
meet
is
potential
the
observed
A similar
current
3)
stayed
nearly
a behavfour
valve-metal
like
behaviour
is
trode
at
formed the these
Tafel
of
a
is
only
at
the
potential;
current
reversible A cme2. cathodic
‘mfxed
current
slope generally nature
density
the
value for
the
The potential potential)
corrosion’
and
is
potential
the
high
Tafel
slope
semiconducting
1 x 1C5
potential
anodlc
at
curves (this
current
meet)
mV.
oxygen
evolution
a long
‘transition’
around be
the
The exchange to
the
-136
would 1131;
value phases
cathodic
constant
Such
Given
bubbling)
electrode
with
around
&,
the
map the
that
potential.
Si02
of
analogue,
to
of
of
line
(commenced
condLtions
in
IN H+SO,+ (N2
this
case.
Tafef
a value
which
attempt (Fig.
in
changes
obtained
surface
present
line
anodic
these
of
the
Tafel
at
5 and 6 $;
the
yields
its
under
successful
in
FeSi2
step-wise
is
presence
extrapolating
nominal
may be noted.
between
cathodic
on W/s)
density
[131, e.g., a hydride obtained
which
(0.5
current
characteristic
plot
by slow
2 x
10q4
consfstent
this
is
not
viz.
1.0
-
region A CIII-~ with with
excluded
that if
2.0
V was
less
was observed; the of
the
increase
an
of
‘incipient’
a surface
layer
of
on anadization. lack
of
anodic
visible potentials
corrosion it
or was
surface
naturally
disintegration of
interest
of to
the
examine
elecIts
An anodlc
3.
Fig.
Tafel
bubbling) would of
lU7l fO26-
plot
normally
oxide
I
(0.3
covering
potential
I
is
1
on nominal regfon
A long
be observed.
growth
1
mV/s steps)
the
observed,
in
FeSi2
which
‘transition’
in IN H2S0, oxygen
region
(N2
evolution
characteristtc
however.
I
I
’
I
I
1
I
’
I
I
962937-
200 Fig.
4.
400 A
cyclic
possible sweep working
(-)
no
evidence from
activity taken
voltammogram and
N2
drawn
600 800 E vs RHE (mV)
first
electrode
then
for the
for
(100
oxygen
oxygen
loo0
(----)
with
oxygen nitrogen
chamber,
is
Tafel
reduction and
virtually
on
nominal
bubbling
reduction
steady-state
the
mV/s)
42co
then no
in
FeS12 the
working
Similar
present.
In
H$O,,,
with
compartment;
conclusions
also
relationships.
In a slow
reaction. with
oxygen
difference
potentiodynamtc
bubbling
was
observed
through (Fig.
the 4).
221
Exactly
similar
runs
where,
from
that
results
again, in
electrode
nitrogen
displays
To examine more
the tion’
were
num descends
‘mirror
down to
the
rise of
current
to
the
the
and
for
curves
potential
region), (=
extremely the
available
It
is
oxygen
reduction
these
electrodes
of
at
are
of
the
region, 358 mV.
followed
for
vigorous
gas
fluctuations
bubble-free
V,
line
the
for
atomic
5)
and
on platibecomes almost
the in the
and the
and
a ‘transi-
is
fluctuations
in
somewhat
then
(which
evolution
at
1.6
The current
are
the
anodic
example,
region
consequent
in
end (Fig.
at
by a Tafel there
that reaction.
large
anodic
state
in oxygen
therefore
commenced
transition
1 A cm-‘),
(&,
clear
covering
passivation
cathodic
steady
indistinguishable
the
by starting
a long
anodic
potentiostatic,
curves
‘mixed’
with the
both
surface
densities
the
region
behaviour
When the
the
to
formation/collapse, potential
6).
in
observed.
no activity
potentiostatic
to
image’ high
owing
again
and cathodic
similar
giving
obtained transition
examined,
end (Fig.
region
very
anodic
regions
cathodic
was
steady-state
cathodic
also
absolutely
the
detail
cathodic
were
a nondescript
real
n
HER; at current bubble
electrode
level)
electrode
surface.
t600-
800% w
358 O-
-800-
Fig.
5.
A
steady-state
tionship anodic potential
(3.3
on nominal and
cathodic
(1.6
V).
mV/s), FeSi2
in
region;
potentiostatic
current
IN H$?O,, (N2 bubbling), the
plot
was
commenced
potential covering
at
the
relaa broad anodfc
-800 t
Fig.
6.
Same conditions cathodic
When one examines the
cathodic (Fig.
anodic
side
experiment formed to
6)
is
around
also
supported
the
two cases;
(Fig.
the
6)
concluded. found
cathodic It
as
hydride
but
it
is
it
is
A final (Fig.
6)
potentials, was also
electrodes
is
the
is
probably that
fact
that
on the on point
even
is
cathodic
side
anodic
when the
the
so
(Fig.
indicate
(Fig.
a normal
are
no
the
corrosion’
current-potential
are
when
the
phase
is rise
run is
presumably transition
transition
‘bump’
structure/composition conclusions
potential
is
hydrides
‘surface
transition
the
giving
cathodic
These
surface
on
when the
small
in the
where
thus
oxides’
involved.
where
that
51,
side,
transition
oxide’
However,
that
6);
cathodic
curve
are
oxides’
region was
are
different
on the
in
indicated have
been
anodic
side
commenced
at
the
be expected.
interest anodic
side
highest
started
‘surface
‘surface
due to a change
‘mixed
as would of
any
probably
that
side
region
the
the
a
regions.
case
the
anodic
run was
would
cathodic
transition
phases
thought
towards
together
Tafel
at
the
the
when the
potentials,
potentials,
indeed
by the
observed
on the
run from
although
anodic
cathodic
1 x 10e3 A cm-* of
is
the
the
results
the
reduced
run was commenced V).
disappears
that
These at
cathodic
arise,
etc.
as
the
(-1.4
by starting
nearly
and cathodic
in
5 but plot
same curve
5).
high
need
the
steep
slowly
reduced
region
as
anodic
at
Fig.
in
region
commenced
which
started
is
(Fig. is
clear-cut
already
the
transition
region
as in
potential
to
explore
oxidation
of
the
possible
organic
activity
molecules
and
of
these
chloride
223
ions.
If potassium
(cf. -
Figs.
observed
3,
(Fig.
acetate
5 and 7).
6)
is added to the sulphuric
extending
over
a long
no indications
Similarly,
acid, a transition
range
of anodic
suggesting
anodic
region
potentials
is
oxidation
of
FeSi2
IN
2400-
1800 5 w Coo-
600-
I ( pAlcm2) Fig. 7.
Anodic H2S04
polarization
possibly
associated
only a transition
either
methanol
curves
taken
of
potential
the transition that
the
properties zinc. up
or
in
V;
shifted region
or hydrazine
to less anodic
penetrate to the
novel
potentials
are discussed
conceptual
origins
step)
curve
on
nominal
No evidence
evolution
and/or
of a Tafel the Kolbe
the
conclusions
separately
quite
noted
similar
values
to somewhat
cases
features
were
in
in
region
reaction;
current-potential
of
Even
higher values; oxide'
acetate,
the case
(Fig. 8) except
and the current
'surface
in the next section,
and
formate
polarization high owing
( >5
the
at which
this would
methanol,
at extremely
that
density
present
refer to the anodic observed
of the experimental
the
or potentiodynamically.
ions was
is observed
Lens
contrast
some
oxygen
potentiostatically
All the foregoing
to 3.0
with
of chloride
chloride
mV/s
(N2 bubbling).
region is seen.
formate
either
the oxidation
mixed
(0.83
+ 0.1 N CH$OOK
suggest
modify
its
or hydravalues of V)
anodic
to the different
data at these high anodic
potentials.
224
00
10
IO0 I(pA/cm2)
Same as in Fig. 7 except
Fig. 8.
+
1M NaCl.
growth
Electrode
V,
one
curiosFty
only
at Extremely
observes
as to what,
PAR system
is not designed
acidic
passivation'
NaCl Tafel
of a transition electrolytes,
the
around
trode
occurring
reactions
electrodes the absence
covered
of oxide for oxygen
in the
slopes
V;
layers
(z LOP)
enters of
supply
(50 V;
this
mode.
into
a
'post-
line
is
around
of elec-
with
semicon-
evolution
in anhydrous
since
are characteristic
electrodes
presumably
The
out these experi-
power
covered
[13] and have been previously
e.g., anodic
layer,
ions, which
slope
to
up
region
potentials;
in a galvanostatic
region
the
that
growth.
post-transition
we carried
(PRT 200-1X)
(Figs. 3, 5, 6, clear
of an oxide
a Hewlett-Packard
transition 4.0
processes,
by a NiF2
of chloride
place
region
at very high anodic
conducting
on
thick surface
in many electrochemical
with
potentiostat
Such high Tafel
ducting/insulating
takes
for this type of work,
600 mV (Fig. 9).
line
it was
characteristic
of FeSiR
either
at
Tafel
Polarizations
in various
solutions, line
characteristic
occurrence
if anything,
galvanostatically,
region
of a possible
High Anodic
the behaviour
now is 1N H$O,,
solution
evolution.
a behavtour
500 mA) or with a Tacussel In
a transition
no evidence
polarization
led us to explore
ments,
only
of the persistent
7, 8) on anodic
I$
that the electrolyte
and/or chlorine
Behaviour
Because
Again
is observed;
evolution
3.0
lo2
of fluorine
hydrofluoric
penetrate
acid
observed on nickel [Lb].
into the surface
In
oxide
225
7-
I
I
111111~
I
I
I
I
IllIll
I
I
I
lllll~
lllll
6-
KP
0'
Iv Current density , A/cm2
Fig. 9.
Galvanostatic
anodic
NaCl solutions chlorine
making high
typical
on
Nb,
enough
metal
Zn
Hf,
gets
evolution.
At
Si
etc.
converted low
line appears
cates
that it is an oxide evolution.
build-up the
oxide
metal
growth
type
11, where function tions;
CH30H;
the magnitude
data
(Fig.
of behaviour
(Fig.
build-up
curves acid
HCOOK;
clearly
sol"tio"s
CH3COOK;
NH*-NH2;
waiting
with
region
clearly
one
of
In solutions
potential
sense
The general
indicated, oxide
metal
tndi-
in the sense
in this
only.
however,
in a variety
characteristics following
containing
of
these valve-
in Fig.
has been followed
the
a
line, for example,
for the termination
of 1 A cm-'
valve
oxygen
resembling
the initial
density;
a
high
on Ta,
(3.5 V/decade)
after
at
iron-silicon,
concomitantly
interest
without
NaCe.
value
the growing
classic or
IM
to
very
growth
the
than a Tafel
current
polarization
have with
oxide
a linear
without
10) is more across
up
10) are not steady-state
density
at the chosen
build
case,
of its slope
rather
(Fig. 10) are of qualitative
the voltage
the
region
anodic
oxides
(albeit
IN HZSO,, leads
can
present
although
over lo-15 minutes) process
the
iron-silicon
of time at an anodic
sulphuric
In
densities,
These
+
line for the
evolution
in
one
for the case
to the next current
(occurring
relationships
as
growth
in IN H$O,+
a Tafel
chlorine
polarization
lo), a,
[13].
(Fig. lo),
FeSiZ
densities;
vigorous
anodic (Fig.
to
current
Tafel
that one shifted
the
polarization,
and
of nominal
around 4.0 V may be noted.
to sustain
behaviour
anodic
presumably,
for oxygen
starting
polarizations),
valve
voltages Al,
evolution
it conducting anodic
polarization
up to very high current
as a
of solu[13]
in
additives:
chloride
ions,
Current density Fig. 10. Galvanostatic very
high
layers, the
I
densities;
the
to the oxygen
'electrode
potentials'
attained,
layers)
behaviour 6@
current
polarization
concomitant
high
oxide
anodic
, A/cm2
so
of nominal build-up
FeSip
of
evolution, (actually
up to
insulating
oxide
thick
is clearly voltage
characteristic
in 1N HpS04
of
indicated
drops
a
across
valve-metal
by the type
[13].
I
I
I
I
I
I
I
I
*?/A-A-
A
4 A-A
,,,; .
.-.
A do-mOo
I to
I 20
I
I
30
40
Fig. 11. The potential-time nominal
FeSi,
&lM
NH2-NH 2;
l,lM
I
50 60 Time 1s) curve observed
in H$O,,
(where applicable):
I
solutions
70
on anodic
90
100
polarization
containing
x, none; A, 1M CH30H; NaCl.
60
the
(1 A cmq2) of
following
0, 1M HCOOK;
A, 1M
additives CH3COOK;
227 the oxide growth stops at around 4.0 V (Fig. 11) with chlorine evolution as the preferred reaction (Fig. 9); in the presence of the organic molecules, the valve-metal type of characteristics, as indicated by the oxide growth up to quite high voltages, are maintained however.
At these very high anodizations
there are some visible signs of electrode attack, with erosion and/or formation of a whitish deposit is some cases; also, at the higher end of oxide growth voltages, potential oscillations, characteristic of dielectric breakdown in valve metal oxides [15], were also noted in some cases.
CONCLUSIONS
Electrodes of (nominally) iron disilicide composition display a remarkable electrochemical stability and can sustain some electrodic reactions at quite high rates, e.g., hydrogen evolution reaction.
RElWU3NCl3S
D.E. Brown, M.N. Mahmood, A.K. Turner, S.M. Hall and P.O. Fogarty, Int. J. Hydrogen Energy, 1 (1982)
405.
D.E. Brown and M.N. Mahmood, Eur. Pat. 0 009
406
(1980).
A.K. Vijh, G. Bclanger and R. Jacques, Prog. Bat. Solar Cells, 2 (1984) 255; JEC Press, Cleveland, Ohio.
R.W. Murray, Acct. Chem. Res., -13 (1980) 135; e, (London), A302 (1981) 253.
I. Rubinstein and A.J. Bard, J. Am.
Phil. Trans. R. Sot.
Chem. Sot., -102 (1980) 6641.
J.P. Randin in J.O'M. Bockris, B.E. Conway, E. Yeager and R.E. White, (eds.), Comprehensive Treatise
of
Electrochemistry, Vol,
4,
Plenum
Publishing Corporation, New York, 1981, p. 473.
J.P. Randin, J. Electrochem. Sot., -121 (1974) 1029; a, 742.
J.P. Randin, J. Electroanal. Chem., 51 (1974) 471.
ibid, 122 (1975)
228 9
J.C.
Bailar, H.J.
Emel&s,
R.
Nyholm
and
A.F.
Trotman-Dickenson,
Comprehensive Inorganic Chemistry Vol. 1, Pergamon Press, New York, 1973, p. 1356.
10
R.L. Rickett in T. Lyman, (Ed.) Metals Handbook, Amer. Sot. for Metals, Novelty, Ohio, 1960, p. 1217.
11
A.K. Vijh, G. Bglanger and R. Jacques, J. Power Sources, fi (1981) 229; A.K. Vijh, R. Jacques and G. Bblanger, J. Power Sources, 2 (1983) 10.
12
A. B'elangerand A.K. Vijh, Surface Tech., -15 (1982) 59.
13
A.K. Vijh, Electrochemistry of Metals and Semiconductors, Marcel Dekker, New York, 1973, p. 167.
14
A.K. Vijh, Surface Tech., 4 (1976) 401.
15
A.K. Vijh, Corr. Sci., 11 (1971) 411.
Chcmistr!,
and Ph!,sics,
ELECTROCRJHICAL IN SIJLPWRIC
19
215
( 1988) 2 I S-328
BEBAVIOUR OF (NOMINALLY)
IRON DISILICIDE
ELECTRODES
ACID
A.K. VIJH, G. BELANGER
and R. JACQUES
Institut
de recherche
d'Hydro-Qugbec,
Received
July 22, 1987; accepted
Varennes,
September
Quebec,
JOL 2PO (Canada)
8, 1987
ABSTRACT
Iron
disilicide
metallic
lustre
trode material
(FeSiq)
composition
to its electrochemical
electrocatalytic
metal
(see text)
displays
behaviour
of elec-
has been
examined
cathodic
typical
some
which
and its possibly
stability,
towards
properties
intermetallic
The electrochemical
and high conductivity. of this nominal
H$O,, with regards ing
is a transition
in 1N
interestanodic
and
reactions. The
remarkable
visible
of potentials, some
erosive
noted,
property
signs of electrode
side,
(>l A cm-*) without rates
anomalously
are
V
there
of
high
of a deposit
anodic
potentials
on the electrode
extremely
(2 1.5
high rates
no
(>5 V),
surface
of hydrogen
the overpotentials
damage; V),
Also
however.
side, up to 3.0 V, only a transition
reduction
galvanostatically behaviour
(or more), is
high
is observed;
or for the oxygen polarized
it permits
any surface
quite
On the anodic
40
formation
it displays
etc. in a wide range
is
required
the Tafel
evolution to sustain
slopes
have
high values -ca 5-6 F.
oxide growth,
type
and/or
is that
exfoliation
however.
On the cathodic
such
material
erosion,
-1.6 V to 3.0 V; at very
e.g., attack
electrode
of this corrosion,
also
no activity reaction
with
some
could
in
signs
concomitant
that of
the
evolution
growth
typical
these
at
of
reaction
the electrode
occurs
breakdown at
characteristic evolution
When
densities,
oxide
dielectric
oxygen
region,
the oxygen
be detected.
to very high current
is observed
some
for either
is
valve metal up
that
levels
to around potential; of
anodic
polarization.
0254-0584/88/$3.50
0 Elsevier Sequoia/Printed
in The Netherlands
216
In
solutions
passivation
containing
Tafel
line
.observed are extremely semiconducting)
organics
activity
the
transition
the chlorine
high (= 10 F),
surface
The possible cal
NaCl,
(for
region
evolution)
enters
around
characteristic
of
into
a
post-
4.0 V; the slopes non-conducting
(or
layers on the electrode.
activity
(CH$OO-,
of these electrodes HCOO-,
could be detected,
NH2-NH2
for the anodic
and
CH30H)
was
oxidation
also
of typi-
examined;
no such
however.
INTRODUCTION
Perhaps
the most-desired
surfaces
displaying
chemical
stability.
available,
coatings ting
to achieve
[l-3], chemical
oxides
involves
so
highly
both
with
conducting the early
with
e.g.,
that
does
of noble such
concomitant
be
not
based
have
to
of
electro-
on
readily-
rely
on
of approaches
based
on special
an
have alloy
[4,5] and the use of conducmetals
as
the
[6]. sodium
of these materials
electrochemical
is the discovery
A number
of surfaces
non-metals
to
one
and
must
electrocatalysts
traces
promise
regard
surfaces
noble metals.
modification
in conjuction
although
[7,gl, time
materials
this goal,
properties
such
use of rare and expensive
made
electrochemistry
electrocatalytic
Furthermore,
inexpensive
extensive been
good
goal in modern
Another
approach
tungsten
bronzes
did not stand the test of
stability
and
electrochemical
activity. Intermetallic some
cases,
occur
sive media
report
to
be
examine
namely,
formula
istics,
can
investigates
silicides, the
and
acids.
which
[9].
addition
another
to
the
attractive
inexpensive
can
have
Since
metallic
some
of
lustre
these
materials. of
aforementioned
The present one
desirable
in abundance
and
it is of
of
these giving
character-
from our point of view:
produced
in
compounds
stability,
behaviour
can,
many corro-
Fe 50%; Si 50%, by weight,
feature
material
silicides,
and chemical
as electrode
(nominally
e.g.
are inert towards
electrochemical
iron disilicide
available
hard
they behave general
In
metals,
The compounds
unusually
how
FeSi2).
solids
of high conductivity
the
it possesses
a readily
transition
as hard metallic
the requirements
interest
of some
such as strong
conductivity fulfill
compounds
it is
by the Quebec
mines.
EXPERIMENTAL
SECTION
Cell A
conventional
with gas inlets
three-compartment
and outlets
[LO]
Pyrex
electrochemical
was used for the
measurements.
cell
provided The three
217 could
compartments isolated
be
separated
from the ambient
by
atmosphere
solution
-
sealed
by water-filled
stopcocks
and
bubblers.
Electrodes Iron
disilicide
has
from 'SIDBEC DOSCO', The
real
analysis,
nominal
composition
would
FeSi, with
chromium
understood
composition,
Qugbec,
and
was
obtained
was
found,
by X-ray
diffraction
Si = 41.6 %; Fe = 56.4 %; Cr = 2.2 X.
correspond
[lo]
to a mixture
of FeSi2
In the context
as an impurity.
that
FeSig
Canada.
of the material
to be as follows:
composition
thus
the
Contrecoeur,
the composition
(or Fe$iS)
of this
of the electrode
This
paper,
is only
and it is
nominally
FeSip. The melted
small
lumps
in a vacuum
were
in
placed
The large
furnace.
a surface
of about 0.314 cm*, which
the piece
in Kel-F.
The working
600 grit on a silicon doubly-distilled The
counter
deionized
in heat-shrinkable Hydrogen
CORROSION
For
before
crucible
surface
was
and
was cut to get
to the solution
The electrodes
by sealing
polished
down
were then washed
to
with
using.
from a vitreous
graphite
rod mounted
tubing. were used.
employed
for the measurements
model
a Corrosion
332
System
Software
Hewlett-Packard
variable
power potentiostat
power
(PRT200-IX)
potentials
Princeton
Applied
for use with
were
printed
of
Apple
on an Epson
II.
galvanostatic supply
measurements
(50 V; 500 mA),
in a galvanostatic
were followed
EG/G
Diskette
the results
in line with an Apple
the high-current-density
in Figs. 1-8 consisted
(from
Program
(64 K ram from EG 6 G);
recorder
electrode
alumina
piece thus obtained
electrode
made
electrodes
SOFTWARE
using
II Computer FX-8W-
purity
and Measurements
The instruments a
water
high
was exposed
wheel.
were
Teflon
reference
Instruments
Research)
carbide
electrodes
a
(Fig. g-11),
a
or a Tacussel
high
mode were employed.
The
on an X-t Omega recorder
(Model 585).
Solutions The main ized,
solution
was made
doubly-distilled
(e.g., NaCl, HCOOK,
water.
CHBOH,
from Ultrex To
CHSCOOK
The rest of the procedures
this
sulphuric solution,
acid (IN)
and deion-
appropriate
additives
etc.) were added, as required.
were as in our other recent work
[11,12].
218 RESULTS MD
DISCUSSION
.Electrode Behaviour in the Potential Region, -1.6 V to 3.0 V
The most striking feature of the present electrode material was its shining, metallic appearance which remained completely unchanged even under drastic conditions of prolonged hydrogen evolution at high rates (1 1 A cm-') or on polarization to high (= 3 V) anodic potentials even in extremely aggressive media, e.g., containing NaCl; some electrode attack, however, is observed at extremely high ( >5 V) anodic potentials - see below.
There were
no
visible
signs of corrosion, erosion, growth, deposits, swelling, exfoliation, mechanical distortion or other changes usually seen on other electrode materials under these conditions, except at extremely high anodic potentials.
For example,
under conditions of gas evolution at such high rates, even high-pressure graphite shows visible erosion with the concomitant particle accumulation in the
solution; no
such disintegration was
noted for the iron disflicide,
however.
i$Ei~,, Fig. 1.
-400
-200
, t * f , , ,~ 0
200 400 600 E vs RHE (mV1
800
WOO
A cyclic voltammogram on nominal FeSi* in IN H2S04 with nitrogen bubbling in the working compartment; scan rate is 100 @I/s.
The
anodie peak seen in this first scan, at around 600 mV disappears in the subsequent scans to give a hysteresis region.
A general potentiodynamic profile on a freshly-polished Fe-Si electrode is shown in Fig. 1; a vestigial anodic peak at around 0.7 V is seen on the first sweep.
On repeated cycling this peak disappears giving rise to a small hyster-
esis between the ascending and the descending sweeps. A steady state, potentiostatic current-potentialrelationship for the hydrogen evolution is presented in Fig. 2.
An excellent Tafel region over several
219
IO-*
Fig.
2.
A
106
cathodic
obtained a long
decades being
Tafel
of very
Tafel
region
high Viz. of
by
hydrogen
evolution
the
the
down to
meet
is
potential
the
observed
A similar
current
3)
stayed
nearly
a behavfour
valve-metal
like
behaviour
is
trode
at
formed the these
Tafel
of
a
is
only
at
the
potential;
current
reversible A cme2. cathodic
‘mfxed
current
slope generally nature
density
the
value for
the
The potential potential)
corrosion’
and
is
potential
the
high
Tafel
slope
semiconducting
1 x 1C5
potential
anodlc
at
curves (this
current
meet)
mV.
oxygen
evolution
a long
‘transition’
around be
the
The exchange to
the
-136
would 1131;
value phases
cathodic
constant
Such
Given
bubbling)
electrode
with
around
&,
the
map the
that
potential.
Si02
of
analogue,
to
of
of
line
(commenced
condLtions
in
IN H+SO,+ (N2
this
case.
Tafef
a value
which
attempt (Fig.
in
changes
obtained
surface
present
line
anodic
these
of
the
Tafel
at
5 and 6 $;
the
yields
its
under
successful
in
FeSi2
step-wise
is
presence
extrapolating
nominal
may be noted.
between
cathodic
on W/s)
density
[131, e.g., a hydride obtained
which
(0.5
current
characteristic
plot
by slow
2 x
10q4
consfstent
this
is
not
viz.
1.0
-
region A CIII-~ with with
excluded
that if
2.0
V was
less
was observed; the of
the
increase
an
of
‘incipient’
a surface
layer
of
on anadization. lack
of
anodic
visible potentials
corrosion it
or was
surface
naturally
disintegration of
interest
of to
the
examine
elecIts
An anodlc
3.
Fig.
Tafel
bubbling) would of
lU7l fO26-
plot
normally
oxide
I
(0.3
covering
potential
I
is
1
on nominal regfon
A long
be observed.
growth
1
mV/s steps)
the
observed,
in
FeSi2
which
‘transition’
in IN H2S0, oxygen
region
(N2
evolution
characteristtc
however.
I
I
’
I
I
1
I
’
I
I
962937-
200 Fig.
4.
400 A
cyclic
possible sweep working
(-)
no
evidence from
activity taken
voltammogram and
N2
drawn
600 800 E vs RHE (mV)
first
electrode
then
for the
for
(100
oxygen
oxygen
loo0
(----)
with
oxygen nitrogen
chamber,
is
Tafel
reduction and
virtually
on
nominal
bubbling
reduction
steady-state
the
mV/s)
42co
then no
in
FeS12 the
working
Similar
present.
In
H$O,,,
with
compartment;
conclusions
also
relationships.
In a slow
reaction. with
oxygen
difference
potentiodynamtc
bubbling
was
observed
through (Fig.
the 4).
221
Exactly
similar
runs
where,
from
that
results
again, in
electrode
nitrogen
displays
To examine more
the tion’
were
num descends
‘mirror
down to
the
rise of
current
to
the
the
and
for
curves
potential
region), (=
extremely the
available
It
is
oxygen
reduction
these
electrodes
of
at
are
of
the
region, 358 mV.
followed
for
vigorous
gas
fluctuations
bubble-free
V,
line
the
for
atomic
5)
and
on platibecomes almost
the in the
and the
and
a ‘transi-
is
fluctuations
in
somewhat
then
(which
evolution
at
1.6
The current
are
the
anodic
example,
region
consequent
in
end (Fig.
at
by a Tafel there
that reaction.
large
anodic
state
in oxygen
therefore
commenced
transition
1 A cm-‘),
(&,
clear
covering
passivation
cathodic
steady
indistinguishable
the
by starting
a long
anodic
potentiostatic,
curves
‘mixed’
with the
both
surface
densities
the
region
behaviour
When the
the
to
formation/collapse, potential
6).
in
observed.
no activity
potentiostatic
to
image’ high
owing
again
and cathodic
similar
giving
obtained transition
examined,
end (Fig.
region
very
anodic
regions
cathodic
was
steady-state
cathodic
also
absolutely
the
detail
cathodic
were
a nondescript
real
n
HER; at current bubble
electrode
level)
electrode
surface.
t600-
800% w
358 O-
-800-
Fig.
5.
A
steady-state
tionship anodic potential
(3.3
on nominal and
cathodic
(1.6
V).
mV/s), FeSi2
in
region;
potentiostatic
current
IN H$?O,, (N2 bubbling), the
plot
was
commenced
potential covering
at
the
relaa broad anodfc
-800 t
Fig.
6.
Same conditions cathodic
When one examines the
cathodic (Fig.
anodic
side
experiment formed to
6)
is
around
also
supported
the
two cases;
(Fig.
the
6)
concluded. found
cathodic It
as
hydride
but
it
is
it
is
A final (Fig.
6)
potentials, was also
electrodes
is
the
is
probably that
fact
that
on the on point
even
is
cathodic
side
anodic
when the
the
so
(Fig.
indicate
(Fig.
a normal
are
no
the
corrosion’
current-potential
are
when
the
phase
is rise
run is
presumably transition
transition
‘bump’
structure/composition conclusions
potential
is
hydrides
‘surface
transition
the
giving
cathodic
These
surface
on
when the
small
in the
where
thus
oxides’
involved.
where
that
51,
side,
transition
oxide’
However,
that
6);
cathodic
curve
are
oxides’
region was
are
different
on the
in
indicated have
been
anodic
side
commenced
at
the
be expected.
interest anodic
side
highest
started
‘surface
‘surface
due to a change
‘mixed
as would of
any
probably
that
side
region
the
the
a
regions.
case
the
anodic
run was
would
cathodic
transition
phases
thought
towards
together
Tafel
at
the
the
when the
potentials,
potentials,
indeed
by the
observed
on the
run from
although
anodic
cathodic
1 x 10e3 A cm-* of
is
the
the
results
the
reduced
run was commenced V).
disappears
that
These at
cathodic
arise,
etc.
as
the
(-1.4
by starting
nearly
and cathodic
in
5 but plot
same curve
5).
high
need
the
steep
slowly
reduced
region
as
anodic
at
Fig.
in
region
commenced
which
started
is
(Fig. is
clear-cut
already
the
transition
region
as in
potential
to
explore
oxidation
of
the
possible
organic
activity
molecules
and
of
these
chloride
223
ions.
If potassium
(cf. -
Figs.
observed
3,
(Fig.
acetate
5 and 7).
6)
is added to the sulphuric
extending
over
a long
no indications
Similarly,
acid, a transition
range
of anodic
suggesting
anodic
region
potentials
is
oxidation
of
FeSi2
IN
2400-
1800 5 w Coo-
600-
I ( pAlcm2) Fig. 7.
Anodic H2S04
polarization
possibly
associated
only a transition
either
methanol
curves
taken
of
potential
the transition that
the
properties zinc. up
or
in
V;
shifted region
or hydrazine
to less anodic
penetrate to the
novel
potentials
are discussed
conceptual
origins
step)
curve
on
nominal
No evidence
evolution
and/or
of a Tafel the Kolbe
the
conclusions
separately
quite
noted
similar
values
to somewhat
cases
features
were
in
in
region
reaction;
current-potential
of
Even
higher values; oxide'
acetate,
the case
(Fig. 8) except
and the current
'surface
in the next section,
and
formate
polarization high owing
( >5
the
at which
this would
methanol,
at extremely
that
density
present
refer to the anodic observed
of the experimental
the
or potentiodynamically.
ions was
is observed
Lens
contrast
some
oxygen
potentiostatically
All the foregoing
to 3.0
with
of chloride
chloride
mV/s
(N2 bubbling).
region is seen.
formate
either
the oxidation
mixed
(0.83
+ 0.1 N CH$OOK
suggest
modify
its
or hydravalues of V)
anodic
to the different
data at these high anodic
potentials.
224
00
10
IO0 I(pA/cm2)
Same as in Fig. 7 except
Fig. 8.
+
1M NaCl.
growth
Electrode
V,
one
curiosFty
only
at Extremely
observes
as to what,
PAR system
is not designed
acidic
passivation'
NaCl Tafel
of a transition electrolytes,
the
around
trode
occurring
reactions
electrodes the absence
covered
of oxide for oxygen
in the
slopes
V;
layers
(z LOP)
enters of
supply
(50 V;
this
mode.
into
a
'post-
line
is
around
of elec-
with
semicon-
evolution
in anhydrous
since
are characteristic
electrodes
presumably
The
out these experi-
power
covered
[13] and have been previously
e.g., anodic
layer,
ions, which
slope
to
up
region
potentials;
in a galvanostatic
region
the
that
growth.
post-transition
we carried
(PRT 200-1X)
(Figs. 3, 5, 6, clear
of an oxide
a Hewlett-Packard
transition 4.0
processes,
by a NiF2
of chloride
place
region
at very high anodic
conducting
on
thick surface
in many electrochemical
with
potentiostat
Such high Tafel
ducting/insulating
takes
for this type of work,
600 mV (Fig. 9).
line
it was
characteristic
of FeSiR
either
at
Tafel
Polarizations
in various
solutions, line
characteristic
occurrence
if anything,
galvanostatically,
region
of a possible
High Anodic
the behaviour
now is 1N H$O,,
solution
evolution.
a behavtour
500 mA) or with a Tacussel In
a transition
no evidence
polarization
led us to explore
ments,
only
of the persistent
7, 8) on anodic
I$
that the electrolyte
and/or chlorine
Behaviour
Because
Again
is observed;
evolution
3.0
lo2
of fluorine
hydrofluoric
penetrate
acid
observed on nickel [Lb].
into the surface
In
oxide
225
7-
I
I
111111~
I
I
I
I
IllIll
I
I
I
lllll~
lllll
6-
KP
0'
Iv Current density , A/cm2
Fig. 9.
Galvanostatic
anodic
NaCl solutions chlorine
making high
typical
on
Nb,
enough
metal
Zn
Hf,
gets
evolution.
At
Si
etc.
converted low
line appears
cates
that it is an oxide evolution.
build-up the
oxide
metal
growth
type
11, where function tions;
CH30H;
the magnitude
data
(Fig.
of behaviour
(Fig.
build-up
curves acid
HCOOK;
clearly
sol"tio"s
CH3COOK;
NH*-NH2;
waiting
with
region
clearly
one
of
In solutions
potential
sense
The general
indicated, oxide
metal
tndi-
in the sense
in this
only.
however,
in a variety
characteristics following
containing
of
these valve-
in Fig.
has been followed
the
a
line, for example,
for the termination
of 1 A cm-'
valve
oxygen
resembling
the initial
density;
a
high
on Ta,
(3.5 V/decade)
after
at
iron-silicon,
concomitantly
interest
without
NaCe.
value
the growing
classic or
IM
to
very
growth
the
than a Tafel
current
polarization
have with
oxide
a linear
without
10) is more across
up
10) are not steady-state
density
at the chosen
build
case,
of its slope
rather
(Fig. 10) are of qualitative
the voltage
the
region
anodic
oxides
(albeit
IN HZSO,, leads
can
present
although
over lo-15 minutes) process
the
iron-silicon
of time at an anodic
sulphuric
In
densities,
These
+
line for the
evolution
in
one
for the case
to the next current
(occurring
relationships
as
growth
in IN H$O,+
a Tafel
chlorine
polarization
lo), a,
[13].
(Fig. lo),
FeSiZ
densities;
vigorous
anodic (Fig.
to
current
Tafel
that one shifted
the
polarization,
and
of nominal
around 4.0 V may be noted.
to sustain
behaviour
anodic
presumably,
for oxygen
starting
polarizations),
valve
voltages Al,
evolution
it conducting anodic
polarization
up to very high current
as a
of solu[13]
in
additives:
chloride
ions,
Current density Fig. 10. Galvanostatic very
high
layers, the
I
densities;
the
to the oxygen
'electrode
potentials'
attained,
layers)
behaviour 6@
current
polarization
concomitant
high
oxide
anodic
, A/cm2
so
of nominal build-up
FeSip
of
evolution, (actually
up to
insulating
oxide
thick
is clearly voltage
characteristic
in 1N HpS04
of
indicated
drops
a
across
valve-metal
by the type
[13].
I
I
I
I
I
I
I
I
*?/A-A-
A
4 A-A
,,,; .
.-.
A do-mOo
I to
I 20
I
I
30
40
Fig. 11. The potential-time nominal
FeSi,
&lM
NH2-NH 2;
l,lM
I
50 60 Time 1s) curve observed
in H$O,,
(where applicable):
I
solutions
70
on anodic
90
100
polarization
containing
x, none; A, 1M CH30H; NaCl.
60
the
(1 A cmq2) of
following
0, 1M HCOOK;
A, 1M
additives CH3COOK;
227 the oxide growth stops at around 4.0 V (Fig. 11) with chlorine evolution as the preferred reaction (Fig. 9); in the presence of the organic molecules, the valve-metal type of characteristics, as indicated by the oxide growth up to quite high voltages, are maintained however.
At these very high anodizations
there are some visible signs of electrode attack, with erosion and/or formation of a whitish deposit is some cases; also, at the higher end of oxide growth voltages, potential oscillations, characteristic of dielectric breakdown in valve metal oxides [15], were also noted in some cases.
CONCLUSIONS
Electrodes of (nominally) iron disilicide composition display a remarkable electrochemical stability and can sustain some electrodic reactions at quite high rates, e.g., hydrogen evolution reaction.
RElWU3NCl3S
D.E. Brown, M.N. Mahmood, A.K. Turner, S.M. Hall and P.O. Fogarty, Int. J. Hydrogen Energy, 1 (1982)
405.
D.E. Brown and M.N. Mahmood, Eur. Pat. 0 009
406
(1980).
A.K. Vijh, G. Bclanger and R. Jacques, Prog. Bat. Solar Cells, 2 (1984) 255; JEC Press, Cleveland, Ohio.
R.W. Murray, Acct. Chem. Res., -13 (1980) 135; e, (London), A302 (1981) 253.
I. Rubinstein and A.J. Bard, J. Am.
Phil. Trans. R. Sot.
Chem. Sot., -102 (1980) 6641.
J.P. Randin in J.O'M. Bockris, B.E. Conway, E. Yeager and R.E. White, (eds.), Comprehensive Treatise
of
Electrochemistry, Vol,
4,
Plenum
Publishing Corporation, New York, 1981, p. 473.
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J.P. Randin, J. Electroanal. Chem., 51 (1974) 471.
ibid, 122 (1975)
228 9
J.C.
Bailar, H.J.
Emel&s,
R.
Nyholm
and
A.F.
Trotman-Dickenson,
Comprehensive Inorganic Chemistry Vol. 1, Pergamon Press, New York, 1973, p. 1356.
10
R.L. Rickett in T. Lyman, (Ed.) Metals Handbook, Amer. Sot. for Metals, Novelty, Ohio, 1960, p. 1217.
11
A.K. Vijh, G. Bglanger and R. Jacques, J. Power Sources, fi (1981) 229; A.K. Vijh, R. Jacques and G. Bblanger, J. Power Sources, 2 (1983) 10.
12
A. B'elangerand A.K. Vijh, Surface Tech., -15 (1982) 59.
13
A.K. Vijh, Electrochemistry of Metals and Semiconductors, Marcel Dekker, New York, 1973, p. 167.
14
A.K. Vijh, Surface Tech., 4 (1976) 401.
15
A.K. Vijh, Corr. Sci., 11 (1971) 411.