Like most heat treatable aluminum alloys, localized corrosion and stress corrosion of Al-Li-Cu alloys is strongly dependent on the nature and distribution of second phase particles. To develop a mechanistic understanding of the role of localized corrosion in the stress corrosion process, bulk samples of T(sub 1) (Al2CuLi) and a range of Al-Cu-Fe impurity phases were prepared for electrochemical experiments. Potentiodynamic polarization and galvanic couple experiments were performed in standard 0.6 M NaCl and in simulated crevice solutions to assess corrosion behavior of these particles with respect to the alpha-Al matrix. A comparison of time to failure versus applied potential using a constant load, smooth bar SCC test technique in Cl(-), Cl(-)/CrO4(2-), and Cl(-)/CO3(2-) environments shows that rapid failures are to be expected when applied potentials are more positive than the breakaway potential (E sub br) of T(sub 1) (crack tip) but less than E(sub br) of alpha-Al (crack walls). It is shown that this criterion is not satisfied in aerated Cl(-) solutions. Accordingly, SCC resistance is good. This criterion is satisfied, however, in an alkaline isolated fissure exposed to a CO2 containing atmosphere. Rapid failure induced by these fissures was recently termed preexposure embrittlement. Anodic polarization shows that the corrosion behavior of T(sub 1) is relatively unaffected in alkaline CO3(2-) environments but the alpha-Al phase is rapidly passivated. X ray diffraction of crevice walls from artificial crevices suggests that passivation of alpha-Al occurs as hydrotalcite-type compound (LiAl2(OH)6)2(+) - CO3(2-) - nH2O

Buchheit, Rudolph G., Jr.

Stoner, Glenn E.

English

NASA Technical Reports Server

Program 4
N90-22656
Measurements and Mechanisms of Localized Aqueous Corrosion in
Aluminum-Lithium Alloys
Rudolph G. Buchheit, Jr. and Glenn E. Stoner
Ob_iectives
The objective of this research is to characterize the localized corrosion and stress
corrosion crack initiation behavior of AI-Li-Cu alloy 2090, and to gain an understanding
of the role of local corrosion and occluded cell environments in the mechanisms of pitting
and initiation and early-stage propagation of stress corrosion cracks.
33
https://ntrs.nasa.gov/search.jsp?R=19900013340 2020-03-19T23:11:05+00:00Z
Stress Corrosion in 2090: The Role of Localized Corrosion
in the Subgrain Boundary Region
R. G. Buchheit
G. E. Stoner
Department of Materials Science
Like most heat treatable aluminum alloys, localized corrosion and stress corrosion
of A1-Li-Cu alloys is strongly dependent on the nature and distribution of second phase
particles. To develop a mechanistic understanding of the role of localized corrosion in the
stress corrosion process, bulk samples of T l (A12CuLi) and a range of AI-Cu-Fe impurity
phases were prepared for electrochemical experiments. Potentiodynamic polarization and
galvanic couple experiments were performed in standard 0.6 M NaC1 and in simulated
crevice solutions to assess corrosion behavior of these particles with respect to the r,-A1
matrix.
A comparison of time to failure versus applied potential using a constant load,
smooth bar SCC test technique in CI, C1-/CrO42- and C1-/CO32- environments shows that
rapid failures are to be expected when applied potentials are more positive than the
breakaway potential (Ebr) of T_ (crack tip) but less than Ebr of a-A1 (crack walls). It is
shown that this criterion is not satisfied in aerated C1- solutions. Accordingly, SCC
resistance is good. This criterion is satisfied, however, in an alkaline isolated fissure
exposed to a CO 2 containing atmosphere. Rapid failure induced by these fissures has
recently been termed "preexposure embrittlement."
Anodic polarization shows that the corrosion behavior of T ! is relatively unaffected
in alkaline CO32- environments but the ct-A1 phase is rapidly passivated. X-ray diffraction
of crevice walls from artificial crevices suggests that passivation of a-A1 occurs as
Bayerite (AI(OH)3) imbibes solvated lithium and carbonate ions to form a
hydrotalcite-type compound [LiA12(OH)6]2 ÷ • CO32- • nil20.
34
Stress Corrosion of 2090:
The Role of Localized Corrosion
in the Subgrain Boundary Region
R.G. Buchheit
G.E. Stoner
Department of Materials Science
University of Virginia
Charlottesville, Virginia 22901
Sponsored by NASA, Langley Research Center, Hampton, Virginia
Outline
* Microstructural Heterogeneity and Localized Corrosion
* Time to Failure vs. Applied Potential in CI" and CI "/CrO_4"
* SCC in CO 2- Environments, "Pre-Exposure Embrittlement"
Centered dark field transmission electron micrograph of the subgrain
boundary region showing the precipitation of T1 on boundaries and in
subgrains.
OF POOR p,_p,_-v
Corrosion Behavior in Aerated 0.6 M NaCI
Phase
G(- Ai
AI-14Cu
Ai18-Cu-5Fe
AI-24Cu-5Fe
T 1
PA 2090
Model
Material
SHT 2090
as cast
as cast
as cast
AI-26Cu-21 Li
AI-3Cu-2Li
Corrosion Potential
(mVsc e )
-720
-620
-670
-675
-1100
-720
Galvanic Couple
Current Density
(ua/cm 2 )
-0.5
-7.0
-3.0
+5OO
A. Optical micrograph of pitting associated with AI-Fe-Cu impurity
particles.
B. Optical micrograph of discontinuous subgrain boundary pitting
associated with T1 precipitated on subgrain boundaries.
ORIGINAL PAGE IS
OF POOR QUALITY
0.I
-0.!
-0.3
A
-0._
"-' -0.7
0
-0.9
-1.1
-L3
Aerated 0.! M NaCI +
0.) }l NatCrO.
2O9O
I0-e I0-e 10-7 i0-e 10-5 I0_ I0-s i0-p- 10-I
Logi(A/:_2)
Anodic polarization in Cl -/Cr042-
overflow and
air out
connection to air
pump
extensor bar
?
1
platinum mesh
electrode
(counter electrode
external connection
to platinum electrode
bubbler device
to provide
aeration
reference
electrode
sample
(working electrode)
external connection
to sample
Schematic of the cell used for constant load TTF
experiments.
_,j
L.
0 0['--' =
Ei
S-,
150
IO0
75
50
25
i IAerated 0.1 u NaC1/O.1 1/NslCr04(
m
]_ for T1
A A A A
(< 150 days)
-0.35 -0.40 -0.45 -0.50 -0.55 -0.80 -0.85 -0.70 -0.75
Applied Potential
Time to failure versus applied potential in CI -/CrO 2"
A. Scanning electron micrograph of the fracture surface of a 2090
tensile specimen subjected to a time to failure experiment at 55 %
ofthe S-T yield strength in 0.1 M NaCI + 0.1 M Na 2CRO4 at an
applied potential greater than EbrOf T 1.
B. Scanning electron micrograph from the rim of the failure initiating
pit.
C. Scanning electron micrograph of the SCC propagation region 200
micrometers below the base of the pit.
D. Scanning electron micrograph of the tensile overload region.
-0.?
-0.8
= _ -0.9
Q3
-1.0
-1.1 -
-1.2
I0-9
Anodic polarization in 0.6 M NaCI solution
Time to Failure vs. Applied Potential
in Aerated 0.6 M NaCI
Applied Potential
(mVsc e )
-720 (Ecorr)
Time to Failure
(days)
3@ >75
5@ >30
-715
-1150
2@ >45
2@ >45
A. Scanning electron micrograph of the fracture surface of a 2090
specimen loaded to 55% of the S-Tyield and immersed in 0.6 M
NaCIsolution under free corrosion conditions for 7 days then
removed from solution and pulled to fracture in air.
B. Scanning electron micrograph of the failure initiating pit.
C. Scanning electron micrograph of the overload region directly below
the base of the pit.
Necessary Conditions for Rapid SCC Failure
Appear to be:
* _ - AI passive
* T1 transpassive
(below Ebr)
(above Ebr)
Pre-Exposure Embrittlement
h
Load Specimen to |
55% of S-T yield J
l
Remove to lab air:
Failure in <24 h
I immerse in aerated 0.6 M
NaCI for 7 days under
free corrosion conditions
Remove to CO2-free air:
No failures
* Alloy 8090, Holroyd, et al. (1987)
* Alloy 2090, Moran (1989)
Holroyd, et al. Moran
Aerated 0.6 M NaCI too
aggressive towards _Continuous SGB_
subgrain boundaries _on in pits.j
Remove from i-
......................... solution.......... _;
("Fissures become alkaline)
l
rAbsorption of CO2" ]
pH falls |
LiAIO 2 precipitates_
CC initiates and_
ropagates_
rLem_ovai+ and CO2-upon 1I
i2CO3 precipitates _
pH 10 /0 -1: /
•144 M reqd._
CC initiates and 1gates
Corrosion Behavior in CI - and CI -/CO 2-
0.6 M NaCI
pH = 7-8
0.6 M NaCI +
0.1 M Li 2CO 3
pH = 10
phase
,_-AI
I"1
_,-A1
ipass
(ua/cm 2 )
1.0
200
0.75
55O
Ebr
(mVsc e)
-690
-720
-59O
-720
> Rapid Failure
Window
-590 mV > -720 mV
150
125
100
,--.4
o ,...4
75
0 0
_ 50
25
Aerated 0.8 M NaQ/O. 1 11 Li_CO 3 pH 11.2
@
Ebr for T1
l
- I
I
0 , i , _ .L , ,,. , .,.. [ , J , , I ,
-0.650 -0.675 -0.700
Applied PoLential
(V.,oe)
!
-0.725
Time to failure versus applied potential in CI -/CO 2
-0.6
-0.7
• ,...-i
•._ -0.8
q)
.,,..a
o -0.9
"_--_-_ -1.0
-N -1.1
-1.2
-1.3
-1.4
-1.5
Slit 2090
0.6 u' NaCI + 0.1 u Li_C0s
0 2000 4000 6000 8000
Time
(seconds)
Open circuit potential versus time in Cl-/CO;_-
A. Scanning electron micrograph of the film that forms in the SCC
region of a 2090 tensile specimen where the specimen is immersed
in aerated 0.6 M NaCI for 7 days then removed to CO 2 -free air.
B. Scanning electron micrograph of the film that forms in the SCC region
of a 2090 tensile specimen that is immersed in aerated 0.6 M NaCI
for 7 days then removed to laboratory air.
ORIGINAL PAGE IS
OF POOR QUALITY
cPs
,ooo ,;.9 .t, 9 "l" ,,o o'80.0 I
90.0 |_090
70.0 80
60.0 70
50,0 80
40.0 50
$0.0 40
90.0 30
10.0 90
o .o 2o
1oo. o 18 94
90. o [=oo
90.0 I 80
70.0 aO
8 . " 7
50.0 80
40. o - 80
30.0 - 40
90.0 30
10.0 90
0.0 t0
9 14 18 94 0
ALUMINUM HYDROXIDE / BAYERITE. SYN
20- tl i 1
AL (OH)3
LITHIUM ALUMINUM CARBONATE HYDROXIDE HYDRATE
37- 7281
LI2AL, (c oa) 'C'0H)'12 . all2
* hydrotalcite -type compound [LiAI 2 (OH)6 ]_. C(_'. nH 2 0
* derived from bayerite AI(OH)3
Hydrotalcites
* Alumina Gels + Lithium Salts
-----_ (UXx)y. 2(AIOH)3. nH20
* Several anions produce isomorphous compounds
OH- CI-
* Passivating effects associated with its presence (Perrota, 1990)
* Insoluble in alkaline solutions
o
x
100
8O
60
40-
20-
0
8
o
9 10 11 12 13
pH
Ammended Pre-Exposure Embrittlement
Mechanism
Constituent Particle Pitting-_
H + consumption in crevice increases pH
[Li + ] increases due to T1 dissolution
CO 2 is absorbed dissociates to CC_"
pH favors Bayerite formation
imbibes 2Li + CO 2" salt
is active
Rapid Failure
Summary
* In order of increasing nobility:
T1 < ,_-AI < AI-Cu-Fe
* RapidSCC ensues when:
EbrT1 > Eapplied > Bar4: - AI
* In 0.6 M NaCl, EbrT 1 = Ebr,_ - AI
rapid SCC criterion is not satified
* In isolated fissures, rapid SCC criterion is
satisfied
* _' - AI is passivated by a hydrotalcite-type
compound
The following pages are from a presentation
given at the CORROSION/90 Meeting, April
23-27, Las Vegas, Nevada
The Role of Hydrolysis in Crevice Corrosion
of Aluminum-Lithium-Copper Alloys
R.G. Buchheit
J.P. Moran
G.E. Stoner
Center for Electrochemical Sciences and Engineering
Department of Materials Science
University of Virginia
Charlottesville, VA 22903
Sponsored by NASA, Langley Research Center, Hampton, VA under
Contract No. NAG-745-2, D.L. Dicus Contract Monitor.
Overview
" Background
" Objectives
* Approach
* Results
* Summa_,
Background
Crevice coupled to Bulk Solution
]]i ' '
pH
9L
i
7k
6L
4
3
2090
2024 (Al-Cu-Li)
(kl-Cu-Mg) \
1
1
J
I
J
I
0 500 1000
Time (rain)
dissolution in the crevice
reduction reactions outside the crevice
, J
1500 2000
Aft-
Metal
Isolated Crevice
1ok
/
9 - /
/
pH 7
6
i
5
3 _
0
/.I
500
T
2090
2024
dissolution in the crevice
I
1000
Time (min)
1500
reduction reactions inside crevice
i
I
r
!
1
r
i
2000
Metal
Objectives
Separate and identify the roles of:
• AI3+
• Li+
• Cu2+
hydrolysis
* an external cathode
Approach
Simulated crevice technique
* in situ measurement
* avoid the size constraint associated
with real crevices
Measure pH versus Time for:
50 pm
T
1.50 cm
cm
Materials Environments
99.99 AI
SHT AI-3Li
SHT A1-3Cu
SHT A1-3Cu-2Li
Aerated Bulk Solution
Isolated Crevice
Approach
Interpret steady state pH using Distribution Diagrams for
monomerlc hydrolysis products and knowledge of where electrochemical
reduction reactions are occurring.
Monomeric Hydrolysis
xMZ+ + YH20 '_ Mx(OH)y(XZ'Y) + + yH +
* Rapid 105 < k < 1010 moles-lsec-1
* Reversible
* An equilibrium treatment is applicable
Reactions Considered
Aluminum
AI 3+ + H20 ,_
A13+ + 2H,_O
AIOH 2+ + H +
AI(OH) 2 + + 2H +
AI 3+ + 3H20 _ AI(OH)3 + 3H +
AI 3 + + 4H20 .,.* AI(OH)4- + 4H +
Lithium
Li + + H20 _ LiOH+ H +
Copper
Cu 2+ + H20 '_, CuOH + + H +
Cu 2+ + 2H20 ,,. Cu(OH)2 + 2H +
Cu 2+ + 3H20 ._.
Cu 2+ + 4H20 4+
Cu 2+ + H20
Cu(OH)3" + 3H +
Cu(OH)42- + 4H +
1/2Cu2(OH)22+ + H +
Electrochemical Reactions
M --* M n + + ne"
02+ 4H + + 4e" .... 2H20
2H + +2e" --* H 2
H20 + e" .-* H + OH"
-log Kxy
4.97
9.3
15.0
23.0
13.86
8.0
17.3
27.8
39.6
10.36
internal
external
internal
internal
Construction of Distribution Diagrams
Formation Quotients (Baes and Mesmer, 1986.)
logQxy = logKxy + aI1/2 + bI
(1 + I1/2)
I = x z i2[i]
2
Mass Action Expressions
Qll = [A1OH2+][ H+]
[A13+ ]
FA1OH 2 + = [A1OH 2 + ]
x [species]
ORIGINAL PAGE IS
OF POOR QUALITY
Hydrol3mtw Produet Content Hydrolytit Product Content
(percent) (percent) Hydrol_dl Product Content
o ° _ _ _ g g _ _ Ig 8 _ (percent)
i "1Nejm_O
m.
"1
___
::Or-
C_
I'- j-q
Results for Pure Aluminum
1o
!
5
1o
5
4 4
s
1ooo 200o $ooo 400(] 5ooo
T_e (minutes)
Electrochemical Reactions:
A1 _ A13+ + 3e"
02 + 4H + + 4e" ..., 2H20
internal
external
Hydrolysis Reaction:
AI3+ +H20 _ A1OH 2+ +H + internal
pH determined by [AI 3 + ]/[AIOH 2 + ]
m this range
lOO_
o 70-
.__ 80
m
oF,
2.0
\
I
2.5 3.0 3.5 4.0 4,.5 5.0 5.5 8.0
pH
ORIGINAL P,.SGFZ15
OF POOR QUALITY
Results for Aluminum
I0 !0
9
8
7
i
0 1000 2OO0 3OOO 40OO 5OOO
Time (minut.)
Electrochemical Reactions:
ALl -* A13 + + 3e"
3H + + 3e" _ 3/2H 2
dissolution of 1 ALl consumes 3 H +
internal
internal
Hydrolysis Reactions:
AI3+ + H20 _ AIOH 2+ +H +
Aj3+ + 2H20 "-* AI(OH) 2+ +2H +
AI 3+ + 3H20 _ AI(OH)3 + 3H +
AI 3+ + 4H20 ,-- AI(OH)4- + 4H +
100
9O
o 70
n
m 60
P
10
0
6.1111
L
_o_,,
_/- f/
•'(o_." "'-..]_ "(o_3," ""
II._ 0.50 11."/5 7.00 7,.25 7.50 ?."t_ ll.O0
pI-I
net loss of 2 H +
net loss of 1 H +
no net loss of H +
net gain of 1 H +
OF POOR QUALITY
Results for SHT AI-3Li
l0
10
Electrochemical Reactions;
AI -.* AI 3 + + 3e"
Li _ Li + + e"
internal
internal
02 + 4H + + 4e" _ 2H20 external
Hydrolysis Reactions:
AIOH 2 + + H +
AI(OH) 2 + + 2H +
AI(OH) 3 + 3H +
-...................., , .....
10-4 104 10-'_ 104 10..4 10-4 lO-S 10-a
log'(A/cm_)
Reduction kinetics are slowed at the external cathode.
UR|Gij_/_L PAC_ i_
OF POOR QUALITY
Results for SHT AI-3Li
10
, f-_ •
8
?
B
S
4
.'1"
e_
10
S
o
4
3 ' ' , , ] _ j i , I , j , , ] i , i j L__ _ 3
0 1000 2OOO _ 400_ 50_
lime (minutes)
_Electrochemical Reactions:
Li --* Li+ + e"
H + + e" _ 1/2H 2
H20 + e" --* H + OH"
internal
intema.I
internal
dissolution of 1 Li consumes 1 H +
Hydrolysis Reactions:
Li + +H20 _ LiOH+H +
"geol.._
et_
6
,'AI(OI_,-
i
i,l, ,I,I
? 8 I I0 11
pH
no net loss of H +
\ i
12 13 14 15 Ie
ORIGINAL PAGE IS
OF POOR QUALITY
Results for SHT AI-3Cu
10
g
$
?
0
5
4
$
0
• Ire'trod _ _lalut.lo=
L [ £ I L L
Time(minutes)
| i i
Aerated Bulk Solution
101'
8
6
5
- 4
I L A _ i S
Consistent with A13++ H20 _ A1OH2+ + H + equilibrium.
I_olated Crevice
Electrochemical Reactions:
Cu _ Cu 2 + + 2e" internal
2H + + 2e" -+ H 2 internal
dissolution of 1 Cu atom form the alloy consumes 2 H +.
Copper oxidation can not discharge H +.
In RRDE experiments with AI2Cu at potentials below
E R Cu/Cu 2+, copper deposits have been observed.
(Mazurkiewicz and Piotrowski, 1983).
[Cu 2 +] > 10-9 M not detected in these crevices.
"F
-d 8o'L
"d so
10
0
t
t
t
r
e
t e
t
/
•. _OH ÷
, --+l'"i l , 1
e ? 8
/],'/ "i
, 1 , 1 ,
II I0 11 12
pI-I
ORIGINAL Fi;,j= _ g_m,
OF POOR QUALI'IY
Results for SHT 2090
10
9
8
_a
5
4
0 1000 2000 3000
Time(minutes)
Aerated Bulk Solution
1oJ
• lirlt.ul _ Sohitl_l
6
?
0
5
4
3
4000 5000
Consistent with Al 3 + + H20 ._, A1OH 2 + + H + equilibrium.
Isolated Crevice
Li "-+ Li + + e"
H + + e" _ 1/2H 2
assisted by elemental Cu on walls
Li + +H20 _ LiOH+H +
replaces H + and inhibits further pH increase.
ORIGINAL PAGE f_
OF POOR QUALITY
Summary
* In aerated bulk solutions, crevice pH is consistent with:
A13+ + H20 o A1OH 2+ +H +
dependent on reduction kinetics at the external cathode.
* AI(OH)-, +/AI(OH)4- system point defines the
pH in pffre A1, isolated crevices.
*Li --* Li + +e"
H + +e" --. 1/2H 2 I
gives an alkaline crevice
Li + + H20 o LiOH+ H + replacesH +
" Elemental Cu on walls of crevices may assist in generating
alkaline crevice solutions.


Measurements and mechanisms of localized aqueous corrosion in aluminum-lithium alloys

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