- Email: [email protected]
Factors in hydrogen embrittlement of high strength steels
materials
Chemistry
and Pl~ysics,
21 (1989)
437
446
437
SHORT COMMUNICATION
FACTORS
IN HYDROGEN
EMBRITTLEMENT
E. QUADRINI CIRM - Dipartimento 60131 Ancona Received
OF HIGH STRENGTH
Universitci
di Meccanica,
STEELS
di Ancona,
Via
Brecce
Bianche,
(Italy)
September
12, 1988; accepted
October
17, 1988
ABSTRACT The effect of pH and current 39NiCrMo3
steel was studied
The hydrogen in
a
was introduced
sulphuric
acid
density
using
on a hydrogen
the delayed
into the material
solution
at
different
failure
induced
by means of cathodic pH
on UN1
fracture
test at a constant
values.
The
load.
polarization
current
density
impos d on the samples during the embrittlement test ranged from 5 to 20 !? mA/cm . The results obtained showed a noticeable influence of the pH and current density on threshold load values and crack incubation times. This behaviour was attributed to the effect of the pH and current density on rate at which atomic
hydrogen
adsorbs
on the material
surface.
INTRGDUCTXON The susceptibility hydrogen
embrittlement
environment-sensitive Despite
the
have been proposed 'These theories proposed the
mechanical
0254-0584/89/$3.50
the
of
to explain basically
theory,
fall
work
three
proposes
present
into molecular
that
steels, examples
to of
modified
embrittlement after
this
argument
Several
theories
phenomena.
groups.
in the material
on
an enigma.
embrittlement
[5] and most recently
which
documented
performed
still remain
into
strength
of metals.
research
the hydrogen
high
often
most
behaviour
of this phenomenon
in the microvoids
atomic hydrogen
of
amount
by Zapffe and Sims
pressure
pressure
one
is
enormous
11-41, many aspects
in particular
of iron alloys,
The
first
of
by Tetelman results
these, [8], is
from
the transformation
high of
hydrogen.
0 Elsevier Sequoia/Printed
in The Netherlands
438 The second theory, proposed by Troiano and his co-workers 17-101 is the 'decohesion theory', which Proposes that hydrogen diffuses under the influence of a stress gradient to regions where plastic deformation is greater, reducing the interatomic cohesion forces. The third model, proposed by Petch and Stables cl11 is the 'Surface energy theory'.This theory proposes that fracture stress is lowered by a reduction in the surface energy of the material at the internal surfaces of the microcrack. Another model attributed a material's loss of ductility to the temporary or permanent interaction of
hydrogen with
the
dislocations, inclusions and
microcavities, point faults and grain joints [12-131. Since none of these theories can explain on its own the complex phenomena which determine the behaviour of a material toward the embrittling action of hydrogen, it is logical to think of a simultaneous action of the various mechanisms. However, a generally recognized common feature of all theories is that some critical concentration of hydrogen must be reached at potential crack sites for failure to initiate. The critical concentration is influenced by complex environmental and
metallurgical interactions such as
potential crack site, the mechanical resistence of
the
the
nature of
the
i-342 I
the
steel
microstructure [15-161, the state of the stress at the site, etc. The purpose of this work is to determine the effect of pH and current density on delayed failure tests carried out on the sample of UN1 39NiCrMo3 steel. Hydrogen charging was affected by means of cathodic polarization. Indeed, since, is it has
been
observed [17], by means of electrochemical
investigation, that atomic hydrogen formation is influenced by hydrogen ion concentration and current density imposed on the sample during failure tests, it is possible that a variation in these parameters causes more or less marked embrittlement effects.
EXPERIMENTAL Specimens for this investigation were UN1 4ONiCrMo7 steel, the chemical composition of which is reported in Table I. Sample geometry and discussions as regards length and the gage length were similar to those previously used [15].
439
Table I. Chemical c
After
composition
of steel used.
(wt%). Mn = 0.75
= 0.40
cu = 0.17
Ni = 1.74
Si = 0.26
Sn = 0.022
Cr = 0.81
P
= 0.019
Al = 0.028
MO = 0.23
s
= 0.015
mechanical
the
finishing,
specimens
were
austenitized
for
one
hour
at
870°C and oil quenched. The
heat
constant
treatment
a special
quenching
oven
also
specimen
enabled
in
a
tubular
us to achieve
releasing
structure
in Fig. 1. The homogeneity the samples
to Rockwell
other mechanical
failure
out
oven
provided
with
a
device
extremely
allowed
the
drastic
specimen
quenching, to
reach
a
bath very rapidly.
The metallographic
The
carried
supply of argon.
The vertical since
was
influence
of the sample
of the heat treatment
C hardness
characteristics of
after heat treatment
surface
tests:
the values
are reported finishing
tests was found in a recent work
was checked
on
obtained
in Table the
is reported
by subjecting together
with the
II.
results
obtained
in
delayed
[la].
100 pm
1000 MESH
Fig. 1. Metallographic
aspect
of
the steel after oil quenched.
all
Fig. 2. Roughness
profile.
440 Table II. Mechanical
properties
Heat Treatment
of steel used.
Hardness
Yeld Strength
HRC
(MPa)
Ultimate Tensile
Strength
(MPa) oil quenched
55
1650
2050
Tempered
44
1100
1250
at 500°C
In order to reduce made of the sample by
Perther.
In
measurements The
surface
Fig.
polarization
This
the
was
of which
sample
which
was
the
carried
from 10
of
out
profile
obtained
the
pH
to 10
l-l), varying
-1
a check
was
machine
made
from
these
gionl
of
current
the current
quantity
studied
thermostatically
of
cathodic
regulated
glass
circulated.
was
by
Inside
assembled,
imposing
on
the hydrogen
to
the
cylinder the
while
a
in the
cylinder
the
platinum
coil
the
samples
an
ion concentration
electrode
that ranged
. density
was
the
studied
at
a constant
pH
-1 (10
g
ion
from 5 to 15 mA/cm'.
conditions
of oxygen,
means
with the atmosphere.
liquid
cathode
density
In the galvanostatic
by
of 2 cm acted as a counterelectrode.
was
-1
material
in a double-walled
of 1300 mV SSE and varying
The effect
small
the
solution,
thermostatic
constituted
effect
-4
into
acid
round it at distance
potential
type C5D electronic
roughness
of 22O + l°C, and in contact
operation
The
average
introduced
in a sulphuric
cavity
wrapped
2
using a Perthometer
therefore,
is reported.
hydrogen
temperature
this effect as much as possible,
only
indicated, possible
apart
from
process
the
is the
reduction
reduction
of of
a
the
hydrogen. The measurement was applied
of failure
time began at the moment
in which
the whole load
to the sample.
The tests which
did
not
since this is a sufficiently
reach
failure
long period
in 150-200
hours
were
of time for ascertaining
interrupted the treshold
load. Immediately scanning
electron
after
fracture,
microscope.
the
specimens
were
examined
by
means
of
a
441 RESULTS The
AND DISCUSSION effect
of
pH
and
the
current
density
are
results
of
sustained
load
tests and are shown in Figs. 3 and 4. Figure charged
3 refers
varying
tests performed
to results
the pH value, at different
obtained while
current
in the tests
Fig.
4 refers
density
in which
the hydrogen
to results
obtained
in
was the
values. o pH=
d(MPa)
1,2
A p H=2,2 n
pH=
l
pHz4.2
3.2
I
lo-'
10"
10'
10'
10'
10' TIMElmin)
Fig.
3.
Effect
of the applied
stress on time to failure
for different
l
d (MPal
n
pH value.
5 (mAcrf?)
10
020
II
I/
II
11
500
400
300
l
200
0
I(I-’
.
^
10’
10
9
10'
_^1
10' _”
1lJTIMEt
Fig. 4. Effect of the applied density.
stress
on time
to failure
mln
for different
) current
442 It
is
apparent
considerably imposed
effected
current
The
trend
material
from
these
results
by hydrogen
that
hydrogen
ion concentration
induced
fracture
in the electrolyte
is
and by
density. of
the
to hydrogen
curve
shows
a greater
embrittlement
sensitivity
at low pH values
on
and
the
high
part
current
of
the
density
values. The results
may be interpreted
which the atomic hydrogen internal
structure.
the metal during
taking
adsorbed
consideration
on the surface
The elementary
the cathodic
into
reactions
polarization
of metal
the mechanisms penetrates
that take place
can be expressed
by
into its
on the surface
of
as:
(1)
H+ + eads K_
-1
K H
+H ads
H
+H
&H ads
+
K
-2
+e-2
H
ads
K
were H
is
(3)
2
-3
hydrogen
adsorbed
on
the
surface
of
the
metal.
The
hydrogen
ads
adsorbed,
given
structure
of
microcavites These traps
(2)
2
its
a
present
for these
atoms.
atoms
hydrogen
accumulates
reaching
a critical
dimensions divides
(1.04
itself
present During
into the and
zones
damages
their
the
triaxal
mechanical
the
spreading dislocations
lattice,
deformation
of greater
concentration,
the
and in the interstitial
in the crystal
plastic
while
A),
between
on the grain boundaries
always
faults,
the hydrogen
modest
material,
plastic
the
and
the
positions.
constitute
excellent
dislocations
transport
stress.
In these
characteristics
zone
into
fractures
zones
until,
on
and
the
cycle
hydrogen
to
reach
environmental
and
continues. It critical
has
been
concentration
metallurgical hydrogen
the hydrogen
materials
interstitial
that
prior
to
the
time
depends,
characteristics,
in the material
Indeed, the
noted
but
necessary
not
only
also
at the moment
upon
upon the
the the
presence
or
otherwise
of
of stress application.
diffusion
mechanism
testing.
The
jumps, dislocation
for
depends
hydrogen
atmospheres
may
upon move
the initial in
the
or along short circuit
state
lattice paths.
of by
443 In
our
material the
provided
tests,
is simultaneous
surface
interaction
will
the
contact
between
the
major
role
the dislocations
the
hydrogen
the dislocations
with the load application,
have
between
that
in
hydrogen
and the
hydrogen
was
the
present The
transport. atoms
and
on
energy
estimated
at
about 0.3 eV at room temperature. At equal levels equal,
and therefore
upon hydrogen From
the curves
critical
value
of dislocations of
in movement
concentration
depends
is also
exclusively
on the surface.
as the equilibrium
the
concentration
the number
1, it can be seen
reaction
conditions,
the
adsorbed
low pH values,
time
that
the hydrogen
reaction
necessary
value and nucleate
for
shifts
the
adsorbed
towards
hydrogen
the fracture
to
is shorter
is greater
at
the right.
In these
reach
critical
the
(leftward
movement
of
in Fig. 3). from
Furthermore,
[20] that hydrogen upon
of stress,
current
concentration
the electrochemical
permeability
density
values.
is reached
investigation,
does not depend
Also
upon
in this second
more quickly
(leftward
it has
been
the electrolyte
case,
the
movement
observed used,
critical
but
hydrogen
of the curves
in Fig.
4). While
these
propagation,
stress.
to explain
Creep phenomena
of very modest
and in particular
micronotches
on the surface,
deformations
stress relaxation
During
there
where
reaches
the critical In this
is an increase
both
in the
of
the
in points stress
consider
the
when
occur
it
is greater.
phenomena
and
which
is subjected
in the material
corresponding
are induced
nucleation
load values.
moment
proportions
cavitation
tip.
Some
at
phenomena
at the crack
subcritical
in fracture
to already
As a consequence
into the crack
to
during
existing of the
tip with
a
in time.
these deformations
local stress
delays
we must
this behaviour, of a material
rate decreasing
the
the lower threshold
the behaviour
load application,
tension
justify
they do not explain
In order determine
considerations
phenomena
occur
value and consequently way,
at
microvoid
every
in the sites there
moment
population
of and
in which
is a release
load
of
application,
in the
sites
with
stress values. these
cause cavitation.
sites
have
a value
very
close
to
the
stress
necessary
to
444
Some authors suppose (19-201 that during the initial relaxation phenomenon the number of subcritically stressed sites decreases with time, and this reduction is greater in the initial phase of the relaxation phenomenon. In our tests, since for the reasons explained above, hydrogen diffusion is helped at low pH values and at high current density values it will be in these conditions that hydrogen will interact with a greater number of subcritically stressed microvoids. In this way, these microvoids will reach the critical stress necessary for growth as a result of
the reduction in cohesion strength caused by
the
hydrogen. The growth of the microvoids, as well as facilitating hydrogen diffusion in the zones in front of the apex of the crack, will weaken the mechanical resistance of this area and therefore the stress necessary to propagate the fracture will be less (upward movement of the curves in Figs. 3 and 4). From
examination of
the
fractographs of
Fig.
5,
a
predominantly
intergranular type failure can be seen with limited areas of quasi-cleavage. This morphology, which is typical of the fragile fracture induced by hydrogen, does not seem to be modified by test conditions.
Fig. 5. SEM fractography with predominant‘intergranufarfracture.
445 CONCLUSIONS On the basis of the experimental and current
density
substantially incubation
the values
obtained
during
of both
we can affirm
the hydrogen
the threshold
that the pH
embrittlement load
and
of
tests failure
time.
embrittlement
it was
is greater
behaviour
rate of atomic
was
observed
that
the
at low pH values
attributed
hydrogen
Fractographic fracture
imposed on a sample
influence
In particular
This
results
to
adsorption
examination
the
and at high
influence
of
by the surface
highlighted
which was not modified
materials
resistence current
these
to hydrogen
density
parameters
values. upon
the
of the material.
a predominantly
intergranular
type of
by test conditions.
REFERENCES 1 M-1. Podobaev
and G.G. Klimov,
2 R. Padmanabhan
Prot. Met,, _i
and W.E. Wood, Metall.
Trans.,
-14A (1983) 2347.
3 Y.B. Wang, W.Y. Chu and C.M. Hsiao, corrosion, 4 T.A. Parthasarathy,
(1983) 345.
41
H.F. Lopez and P.G. Shewmon,
(1985) 427. Metall.
Trans.,
-16A (1985)
1164. 5 C. Zapffe 6 A.S.
Tetelman,
446-464, 7 R.P.
and C. Sims, AIME Trans., Fundamental
National
Frohmberg,
145 (1941) 225-237. -
Aspects
of
Assoc. of Corrosion W.J.
Barnett
and
Stress
Corrosion
Engineers, A.R.
Cracking
(1969)
ASM,
47
(1955)
212 -
(1958)
Houston.
Troiano,
Trans.
892-925. 8 H.H.
Johnson,
J.G.
Morlet
and
A.R.
Troiano,
Trans.
TMS-AIME,
528-536. 9 E.A.
Steigerwald,
F.W.
Scholler
and
A.R.
Troiano,
Trans.
TMS-AIME,
215 -
Hochmann,
R.D.
(1959) 1048-1052. 10 A.R. Troiano,
Trans.
ASM, 52 (1960) 54-80.
11 N.O. Petch and P. Stables, 12 G.E.
Kerns,
McCnight
and
embrittlement
M.T.
Wang
J.E. of
and R.W.
Slater
iron
Assoc. of Corrosion
Nature, --
base
Stabhle,
teds.) alloys,
Engineers,
169 (1952) 842-843. in R.W.
stress
Stachle,
corrosion
Unicux-Firminy
1977, p. 700
J.
cracking 1973,
and
hydrogen
Houston,
National
446 13 G.M.
Pressouyre,
connaissances Memoires
J.
et Etudes
and
Dollet,
concernant
B.
Vieillard-Baron,
fraqilisation
la
Scientifiques
des
de la Revue
'Evolution
aciers
de Metallurgic
Par 2
des
l'hydrogene, (41) (1982).
p. 161 and 79 (5) 1982, p. 227. 14 E. Quadrini,
J. Mater.
15 E. Quadrini,
Mater.
16 M.D. Tumuluru, 17 A. Kawashima, 18 E. Quadrini,
Sci. (in press).
Chem. Phys., 15 (1986) 155.
Corrosion, K. Hashimoto
R. Fratesi
41 (1985) 406. and S. Shimodaira,
and G. Roventi,
Corrosion,
Mater. -
32 (1976) 321.
Sci. Enqng., 96
19 R.A. Oriani
and P.H. Josephic,
Acta Metall.,
5,
997-1005.
20 R.A. Oriani
and P.H. Josephic,
Acta Metall.,
29, 660-74
(1981).
(1987) 51.
Chemistry
and Pl~ysics,
21 (1989)
437
446
437
SHORT COMMUNICATION
FACTORS
IN HYDROGEN
EMBRITTLEMENT
E. QUADRINI CIRM - Dipartimento 60131 Ancona Received
OF HIGH STRENGTH
Universitci
di Meccanica,
STEELS
di Ancona,
Via
Brecce
Bianche,
(Italy)
September
12, 1988; accepted
October
17, 1988
ABSTRACT The effect of pH and current 39NiCrMo3
steel was studied
The hydrogen in
a
was introduced
sulphuric
acid
density
using
on a hydrogen
the delayed
into the material
solution
at
different
failure
induced
by means of cathodic pH
on UN1
fracture
test at a constant
values.
The
load.
polarization
current
density
impos d on the samples during the embrittlement test ranged from 5 to 20 !? mA/cm . The results obtained showed a noticeable influence of the pH and current density on threshold load values and crack incubation times. This behaviour was attributed to the effect of the pH and current density on rate at which atomic
hydrogen
adsorbs
on the material
surface.
INTRGDUCTXON The susceptibility hydrogen
embrittlement
environment-sensitive Despite
the
have been proposed 'These theories proposed the
mechanical
0254-0584/89/$3.50
the
of
to explain basically
theory,
fall
work
three
proposes
present
into molecular
that
steels, examples
to of
modified
embrittlement after
this
argument
Several
theories
phenomena.
groups.
in the material
on
an enigma.
embrittlement
[5] and most recently
which
documented
performed
still remain
into
strength
of metals.
research
the hydrogen
high
often
most
behaviour
of this phenomenon
in the microvoids
atomic hydrogen
of
amount
by Zapffe and Sims
pressure
pressure
one
is
enormous
11-41, many aspects
in particular
of iron alloys,
The
first
of
by Tetelman results
these, [8], is
from
the transformation
high of
hydrogen.
0 Elsevier Sequoia/Printed
in The Netherlands
438 The second theory, proposed by Troiano and his co-workers 17-101 is the 'decohesion theory', which Proposes that hydrogen diffuses under the influence of a stress gradient to regions where plastic deformation is greater, reducing the interatomic cohesion forces. The third model, proposed by Petch and Stables cl11 is the 'Surface energy theory'.This theory proposes that fracture stress is lowered by a reduction in the surface energy of the material at the internal surfaces of the microcrack. Another model attributed a material's loss of ductility to the temporary or permanent interaction of
hydrogen with
the
dislocations, inclusions and
microcavities, point faults and grain joints [12-131. Since none of these theories can explain on its own the complex phenomena which determine the behaviour of a material toward the embrittling action of hydrogen, it is logical to think of a simultaneous action of the various mechanisms. However, a generally recognized common feature of all theories is that some critical concentration of hydrogen must be reached at potential crack sites for failure to initiate. The critical concentration is influenced by complex environmental and
metallurgical interactions such as
potential crack site, the mechanical resistence of
the
the
nature of
the
i-342 I
the
steel
microstructure [15-161, the state of the stress at the site, etc. The purpose of this work is to determine the effect of pH and current density on delayed failure tests carried out on the sample of UN1 39NiCrMo3 steel. Hydrogen charging was affected by means of cathodic polarization. Indeed, since, is it has
been
observed [17], by means of electrochemical
investigation, that atomic hydrogen formation is influenced by hydrogen ion concentration and current density imposed on the sample during failure tests, it is possible that a variation in these parameters causes more or less marked embrittlement effects.
EXPERIMENTAL Specimens for this investigation were UN1 4ONiCrMo7 steel, the chemical composition of which is reported in Table I. Sample geometry and discussions as regards length and the gage length were similar to those previously used [15].
439
Table I. Chemical c
After
composition
of steel used.
(wt%). Mn = 0.75
= 0.40
cu = 0.17
Ni = 1.74
Si = 0.26
Sn = 0.022
Cr = 0.81
P
= 0.019
Al = 0.028
MO = 0.23
s
= 0.015
mechanical
the
finishing,
specimens
were
austenitized
for
one
hour
at
870°C and oil quenched. The
heat
constant
treatment
a special
quenching
oven
also
specimen
enabled
in
a
tubular
us to achieve
releasing
structure
in Fig. 1. The homogeneity the samples
to Rockwell
other mechanical
failure
out
oven
provided
with
a
device
extremely
allowed
the
drastic
specimen
quenching, to
reach
a
bath very rapidly.
The metallographic
The
carried
supply of argon.
The vertical since
was
influence
of the sample
of the heat treatment
C hardness
characteristics of
after heat treatment
surface
tests:
the values
are reported finishing
tests was found in a recent work
was checked
on
obtained
in Table the
is reported
by subjecting together
with the
II.
results
obtained
in
delayed
[la].
100 pm
1000 MESH
Fig. 1. Metallographic
aspect
of
the steel after oil quenched.
all
Fig. 2. Roughness
profile.
440 Table II. Mechanical
properties
Heat Treatment
of steel used.
Hardness
Yeld Strength
HRC
(MPa)
Ultimate Tensile
Strength
(MPa) oil quenched
55
1650
2050
Tempered
44
1100
1250
at 500°C
In order to reduce made of the sample by
Perther.
In
measurements The
surface
Fig.
polarization
This
the
was
of which
sample
which
was
the
carried
from 10
of
out
profile
obtained
the
pH
to 10
l-l), varying
-1
a check
was
machine
made
from
these
gionl
of
current
the current
quantity
studied
thermostatically
of
cathodic
regulated
glass
circulated.
was
by
Inside
assembled,
imposing
on
the hydrogen
to
the
cylinder the
while
a
in the
cylinder
the
platinum
coil
the
samples
an
ion concentration
electrode
that ranged
. density
was
the
studied
at
a constant
pH
-1 (10
g
ion
from 5 to 15 mA/cm'.
conditions
of oxygen,
means
with the atmosphere.
liquid
cathode
density
In the galvanostatic
by
of 2 cm acted as a counterelectrode.
was
-1
material
in a double-walled
of 1300 mV SSE and varying
The effect
small
the
solution,
thermostatic
constituted
effect
-4
into
acid
round it at distance
potential
type C5D electronic
roughness
of 22O + l°C, and in contact
operation
The
average
introduced
in a sulphuric
cavity
wrapped
2
using a Perthometer
therefore,
is reported.
hydrogen
temperature
this effect as much as possible,
only
indicated, possible
apart
from
process
the
is the
reduction
reduction
of of
a
the
hydrogen. The measurement was applied
of failure
time began at the moment
in which
the whole load
to the sample.
The tests which
did
not
since this is a sufficiently
reach
failure
long period
in 150-200
hours
were
of time for ascertaining
interrupted the treshold
load. Immediately scanning
electron
after
fracture,
microscope.
the
specimens
were
examined
by
means
of
a
441 RESULTS The
AND DISCUSSION effect
of
pH
and
the
current
density
are
results
of
sustained
load
tests and are shown in Figs. 3 and 4. Figure charged
3 refers
varying
tests performed
to results
the pH value, at different
obtained while
current
in the tests
Fig.
4 refers
density
in which
the hydrogen
to results
obtained
in
was the
values. o pH=
d(MPa)
1,2
A p H=2,2 n
pH=
l
pHz4.2
3.2
I
lo-'
10"
10'
10'
10'
10' TIMElmin)
Fig.
3.
Effect
of the applied
stress on time to failure
for different
l
d (MPal
n
pH value.
5 (mAcrf?)
10
020
II
I/
II
11
500
400
300
l
200
0
I(I-’
.
^
10’
10
9
10'
_^1
10' _”
1lJTIMEt
Fig. 4. Effect of the applied density.
stress
on time
to failure
mln
for different
) current
442 It
is
apparent
considerably imposed
effected
current
The
trend
material
from
these
results
by hydrogen
that
hydrogen
ion concentration
induced
fracture
in the electrolyte
is
and by
density. of
the
to hydrogen
curve
shows
a greater
embrittlement
sensitivity
at low pH values
on
and
the
high
part
current
of
the
density
values. The results
may be interpreted
which the atomic hydrogen internal
structure.
the metal during
taking
adsorbed
consideration
on the surface
The elementary
the cathodic
into
reactions
polarization
of metal
the mechanisms penetrates
that take place
can be expressed
by
into its
on the surface
of
as:
(1)
H+ + eads K_
-1
K H
+H ads
H
+H
&H ads
+
K
-2
+e-2
H
ads
K
were H
is
(3)
2
-3
hydrogen
adsorbed
on
the
surface
of
the
metal.
The
hydrogen
ads
adsorbed,
given
structure
of
microcavites These traps
(2)
2
its
a
present
for these
atoms.
atoms
hydrogen
accumulates
reaching
a critical
dimensions divides
(1.04
itself
present During
into the and
zones
damages
their
the
triaxal
mechanical
the
spreading dislocations
lattice,
deformation
of greater
concentration,
the
and in the interstitial
in the crystal
plastic
while
A),
between
on the grain boundaries
always
faults,
the hydrogen
modest
material,
plastic
the
and
the
positions.
constitute
excellent
dislocations
transport
stress.
In these
characteristics
zone
into
fractures
zones
until,
on
and
the
cycle
hydrogen
to
reach
environmental
and
continues. It critical
has
been
concentration
metallurgical hydrogen
the hydrogen
materials
interstitial
that
prior
to
the
time
depends,
characteristics,
in the material
Indeed, the
noted
but
necessary
not
only
also
at the moment
upon
upon the
the the
presence
or
otherwise
of
of stress application.
diffusion
mechanism
testing.
The
jumps, dislocation
for
depends
hydrogen
atmospheres
may
upon move
the initial in
the
or along short circuit
state
lattice paths.
of by
443 In
our
material the
provided
tests,
is simultaneous
surface
interaction
will
the
contact
between
the
major
role
the dislocations
the
hydrogen
the dislocations
with the load application,
have
between
that
in
hydrogen
and the
hydrogen
was
the
present The
transport. atoms
and
on
energy
estimated
at
about 0.3 eV at room temperature. At equal levels equal,
and therefore
upon hydrogen From
the curves
critical
value
of dislocations of
in movement
concentration
depends
is also
exclusively
on the surface.
as the equilibrium
the
concentration
the number
1, it can be seen
reaction
conditions,
the
adsorbed
low pH values,
time
that
the hydrogen
reaction
necessary
value and nucleate
for
shifts
the
adsorbed
towards
hydrogen
the fracture
to
is shorter
is greater
at
the right.
In these
reach
critical
the
(leftward
movement
of
in Fig. 3). from
Furthermore,
[20] that hydrogen upon
of stress,
current
concentration
the electrochemical
permeability
density
values.
is reached
investigation,
does not depend
Also
upon
in this second
more quickly
(leftward
it has
been
the electrolyte
case,
the
movement
observed used,
critical
but
hydrogen
of the curves
in Fig.
4). While
these
propagation,
stress.
to explain
Creep phenomena
of very modest
and in particular
micronotches
on the surface,
deformations
stress relaxation
During
there
where
reaches
the critical In this
is an increase
both
in the
of
the
in points stress
consider
the
when
occur
it
is greater.
phenomena
and
which
is subjected
in the material
corresponding
are induced
nucleation
load values.
moment
proportions
cavitation
tip.
Some
at
phenomena
at the crack
subcritical
in fracture
to already
As a consequence
into the crack
to
during
existing of the
tip with
a
in time.
these deformations
local stress
delays
we must
this behaviour, of a material
rate decreasing
the
the lower threshold
the behaviour
load application,
tension
justify
they do not explain
In order determine
considerations
phenomena
occur
value and consequently way,
at
microvoid
every
in the sites there
moment
population
of and
in which
is a release
load
of
application,
in the
sites
with
stress values. these
cause cavitation.
sites
have
a value
very
close
to
the
stress
necessary
to
444
Some authors suppose (19-201 that during the initial relaxation phenomenon the number of subcritically stressed sites decreases with time, and this reduction is greater in the initial phase of the relaxation phenomenon. In our tests, since for the reasons explained above, hydrogen diffusion is helped at low pH values and at high current density values it will be in these conditions that hydrogen will interact with a greater number of subcritically stressed microvoids. In this way, these microvoids will reach the critical stress necessary for growth as a result of
the reduction in cohesion strength caused by
the
hydrogen. The growth of the microvoids, as well as facilitating hydrogen diffusion in the zones in front of the apex of the crack, will weaken the mechanical resistance of this area and therefore the stress necessary to propagate the fracture will be less (upward movement of the curves in Figs. 3 and 4). From
examination of
the
fractographs of
Fig.
5,
a
predominantly
intergranular type failure can be seen with limited areas of quasi-cleavage. This morphology, which is typical of the fragile fracture induced by hydrogen, does not seem to be modified by test conditions.
Fig. 5. SEM fractography with predominant‘intergranufarfracture.
445 CONCLUSIONS On the basis of the experimental and current
density
substantially incubation
the values
obtained
during
of both
we can affirm
the hydrogen
the threshold
that the pH
embrittlement load
and
of
tests failure
time.
embrittlement
it was
is greater
behaviour
rate of atomic
was
observed
that
the
at low pH values
attributed
hydrogen
Fractographic fracture
imposed on a sample
influence
In particular
This
results
to
adsorption
examination
the
and at high
influence
of
by the surface
highlighted
which was not modified
materials
resistence current
these
to hydrogen
density
parameters
values. upon
the
of the material.
a predominantly
intergranular
type of
by test conditions.
REFERENCES 1 M-1. Podobaev
and G.G. Klimov,
2 R. Padmanabhan
Prot. Met,, _i
and W.E. Wood, Metall.
Trans.,
-14A (1983) 2347.
3 Y.B. Wang, W.Y. Chu and C.M. Hsiao, corrosion, 4 T.A. Parthasarathy,
(1983) 345.
41
H.F. Lopez and P.G. Shewmon,
(1985) 427. Metall.
Trans.,
-16A (1985)
1164. 5 C. Zapffe 6 A.S.
Tetelman,
446-464, 7 R.P.
and C. Sims, AIME Trans., Fundamental
National
Frohmberg,
145 (1941) 225-237. -
Aspects
of
Assoc. of Corrosion W.J.
Barnett
and
Stress
Corrosion
Engineers, A.R.
Cracking
(1969)
ASM,
47
(1955)
212 -
(1958)
Houston.
Troiano,
Trans.
892-925. 8 H.H.
Johnson,
J.G.
Morlet
and
A.R.
Troiano,
Trans.
TMS-AIME,
528-536. 9 E.A.
Steigerwald,
F.W.
Scholler
and
A.R.
Troiano,
Trans.
TMS-AIME,
215 -
Hochmann,
R.D.
(1959) 1048-1052. 10 A.R. Troiano,
Trans.
ASM, 52 (1960) 54-80.
11 N.O. Petch and P. Stables, 12 G.E.
Kerns,
McCnight
and
embrittlement
M.T.
Wang
J.E. of
and R.W.
Slater
iron
Assoc. of Corrosion
Nature, --
base
Stabhle,
teds.) alloys,
Engineers,
169 (1952) 842-843. in R.W.
stress
Stachle,
corrosion
Unicux-Firminy
1977, p. 700
J.
cracking 1973,
and
hydrogen
Houston,
National
446 13 G.M.
Pressouyre,
connaissances Memoires
J.
et Etudes
and
Dollet,
concernant
B.
Vieillard-Baron,
fraqilisation
la
Scientifiques
des
de la Revue
'Evolution
aciers
de Metallurgic
Par 2
des
l'hydrogene, (41) (1982).
p. 161 and 79 (5) 1982, p. 227. 14 E. Quadrini,
J. Mater.
15 E. Quadrini,
Mater.
16 M.D. Tumuluru, 17 A. Kawashima, 18 E. Quadrini,
Sci. (in press).
Chem. Phys., 15 (1986) 155.
Corrosion, K. Hashimoto
R. Fratesi
41 (1985) 406. and S. Shimodaira,
and G. Roventi,
Corrosion,
Mater. -
32 (1976) 321.
Sci. Enqng., 96
19 R.A. Oriani
and P.H. Josephic,
Acta Metall.,
5,
997-1005.
20 R.A. Oriani
and P.H. Josephic,
Acta Metall.,
29, 660-74
(1981).
(1987) 51.