Experimental Characterization of Hydrogen Trapping on API 5CT P110 Steel. Part. I: Effect on Hydrogen Embrittlement Susceptibility

Hydrogen permeation tests and tensile mechanical tests were performed at room temperature on API 5CT P110 steel to characterize hydrogen trapping and to evaluate their hydrogen embrittlement susceptibility. The hydrogen trap density was calculated from two consecutive hydrogen permeation transients plotted using an electrochemical cell. Slow strain rate tensile tests on hydrogen-charged samples through cathodic polarization at different potentials were performed to evaluate the hydrogen embrittlement susceptibility. Thereby it was established the lowest potential that characterizes the onset of the cathodic overprotection for studied steel. After mechanical tests was observed a decrease in ductility as the protection potential became more negative and that the fracture mode was changed from ductile microvoid coalescence on the as-received steel to extended quasi-cleavage on the hydrogen-charged steel. The results showed that API 5CT P110 steel has high susceptibility to hydrogen embrittlement conditioned by a predominance of reversible traps in microstructure and by high hydrogen solubility.


Introduction
Corrosion control is of great importance in the offshore oil and gas industry.Cathodic protection is commonly used in subsea pipelines, but its intensive use can lead to so-called cathodic overprotection where large amounts of hydrogen are produced at the coating defects.This hydrogen can be absorbed into the steel and cause hydrogen embrittlement, a degradation process that induces loss of ductility and reduces the fracture resistance of the material 1 .The susceptibility of steels to hydrogen embrittlement depends on the diffusivity, solubility, trapping and other hydrogen transport characteristics in the lattice 2 .In turn, trapping depends on microstructural features as grain boundaries, voids, second phase particles and other microstructural heterogeneities, known as hydrogen traps 3 .Hydrogen traps are classified as reversible and irreversible depending on intensity of their trapping energy 4 .Traps are considered reversible when they possess low trapping energy; as the hydrogen in these traps can be easily released it is considered mobile hydrogen.Traps are considered irreversible when a larger amount of energy must be applied for the hydrogen to be released 5 .When hydrogen is trapped in traps, the diffusion process is altered because the residence time in traps is greater than the residence time in normal interstitial lattice sites; therefore, the main effect of trapping is the reduction of the hydrogen transport rate through the material 6,7 .At present, it is well established that hydrogen trapping is a very important part of hydrogen embrittlement 8 and that the hydrogen embrittlement susceptibility of steel is closely correlated with trapping 9 .
In last years, cracking and failure in subsea and onshore pipelines were partially attributed to embrittlement caused by hydrogen produced from the intensive use of cathodic protection 10,11 .Although the steels used in pipes for oil and gas transfer and to export petroleum products are characterized by their high mechanical strength and good fracture toughness, these materials are susceptible to some hydrogen damage 2,[12][13][14][15][16][17] .For this reason, recommended practices 18,19 and standards 20 were prepared for the design of cathodic protection systems in subsea pipelines, taking into account the effects of hydrogen generated in these systems, in order to avoid hydrogen embrittlement processes.
Therefore, the guarantee of the integrity of structures that have cathodic protection systems is necessary in order to sustain the project load capacity.In offshore structures, load capacity is highly important and the constant challenges of the high depths motivate the use of new steel grades, and steels currently used in other applications, in structures with cathodic protection systems.For example, API 5CT P110 steel, which is used in the manufacturing of casing pipes and couplings for oil wells, recently started to be used for the production of tubing and casing for risers, in view of its excellent combination of good fracture toughness and high mechanical strength 21 .
A preliminary step to evaluate the mechanical response of steels is the study of hydrogen behavior in these materials, in order to obtain the electrochemical parameters required to perform appropriate mechanical tests, or to employ them in mathematical models that allow for numerical simulations with more realistic results, and consequently, with increased accuracy in prediction of failures associated with hydrogen damage 22 .Trap density also can be obtained experimentally through permeation curves or through mathematical models, either complex or simplified 23 , that depend on parameters such as the apparent diffusivity, the effective diffusivity and the subsurface hydrogen concentration.The amount of hydrogen available in the work environment of structures is important information, because this amount will (or will not) enable a sufficient quantity of hydrogen atoms to be absorbed and transported within the lattice to initiate embrittlement processes.In cathodic protection systems, the concentration of hydrogen atoms on the surface of a metal may be orders of magnitude higher than the hydrogen atom concentration created by exposure to hydrogen gas 24 .In these systems, atomic hydrogen is generated electrochemically in reduction reactions that become more and more dominant as the protection potential takes on more negative values.Therefore, hydrogen availability is strongly associated with the protection potential employed when a cathodic overprotection condition is characterized.According to DNVGL-RPB401 19 the term overprotection is only applicable to protection potentials more negative than -1050 mV, although this is a recommendation of general use.The ISO 15589-2 20 standard indicates that for pipeline systems fabricated from steels with σ Y < 550 MPa, -1100 mV is an adequate negative potential limit.However, for high-strength steels (σ Y ≥ 550 MPa), the most negative potential that can be tolerated without causing hydrogen embrittlement is yet to be determined.
This work studies the hydrogen permeation parameters and hydrogen trapping in API 5CT P110 steel under cathodic overprotection conditions, as well as the resulting changes on its mechanical response to loads and the effect of hydrogen.

Method and Experimental Procedures
This study was performed using high strength and low alloy (HSLA) API 5CT P110 steel from a seamless pipe gutter, with intended use in oil well casing, with 330 mm outer diameter and 14 mm wall thickness, provided by CENPES/PETROBRAS.
In order to determine the hydrogen kinetic parameters in the studied steel, potentiodynamic polarization tests were performed to establish the minimum potential for hydrogen generation in the choice electrolyte.With these data, hydrogen permeation tests were performed using Devanathan and Stachurski's 25 electrochemical permeation technique.In the permeation tests, first the cathodic protection potential stated by ISO 15589-2 was adopted, then a more negative potential was used in order to ensure cathodic overprotection condition.The saturation times of specimens used in mechanical tensile tests were obtained through the results of permeation tests.
In order to determine variations in ductility and to establish the hydrogen embrittlement susceptibility of studied steel, tensile tests using samples of as-received material and samples of hydrogenated material were performed.
The results of tensile tests were used also to determine the specific range of cathodic protection potentials for the API 5CT P110 steel.
The specimens for all tests were extracted from a pipe wall.The metallic membranes for the electrochemical tests were manufactured with a 3.14 cm 2 area and 1.0 mm thickness, with their axial direction parallel to rolling direction, according to ASTM G148-97 26 .The round tensile samples for the mechanical tests were machined in the rolling direction, in accordance to ASTM E8/E8M-09 27 , with dimensions shown in the schematic of Figure 1.
The Figure 2 shows the Devanathan and Stachurski type electrochemical double-cell 25 used in this work for following purposes: (a) obtaining the potentiodynamic curve for choosing the hydrogen production current and (b) testing hydrogen diffusion through the metallic membrane.In the first case, it was only necessary to use one of the cells, forming a classic three-electrode cell.In the second case, the two cells arranged symmetrically were used.The production cell aims to produce hydrogen galvanostatically (or potenciostatically) on the sample surface from the current (or potential) established in the potentiodynamic polarization test.In the detection cell the sample surface is anodically polarized against the potential of the calomel reference electrode (SCE) with the purpose of oxidizing the diffused hydrogen.This oxidation current is recorded continuously to obtain the permeation curve.
The potentiodynamic polarization tests were performed at room temperature (26±1ºC) using the left cell of electrochemical double-cell filled with a NaCl solution, by applying a linear ramp of measured potential against the Ag/AgCl reference electrode at a sweep rate of 0.8 mV/s.A platinum electrode with area of 1 cm 2 was used as counter electrode in each cell.The concentration and pH of NaCl solution was similar to synthetic seawater solution (24g/l and 8.2 respectively) 28 .The pH was adjusted with a NaOH solution (0.1N) before starting the tests.The permeation tests were conducted at room temperature (26±1ºC) using metallic membranes placed between the production and detection cells.The galvanostatic method was used to produce hydrogen in the production cell.The choice of the cathodic protection potential followed criteria established by the ISO 15589-2 standard 20 .The choice of hydrogen production current adopted in each permeation tests were related to the chosen cathodic protection potential and determined from the obtained polarogram in the potentiodynamic test.The production cell was filled with a 24 g/l NaCl solution to avoid the salt deposition or formation of calcareous encrustations that occurs when synthetic seawater is used, since which operate as a barrier to the entry of hydrogen into the material 29 .The presence of calcareous encrustations decreases the hydrogen flux, making the time for the steady state to be reached during permeation tests longer, but does not affect the diffusivity 29,30 .For this reason, sodium chloride solutions are very used to replace synthetic seawater in this type of laboratory tests [31][32][33] .The detection cell was filled with a NaOH solution (0.1N), following the ASTM G148-97 26 recommendations.Both solutions were deoxygenated by bubbling N 2 .In the first test, metallic membranes were hydrogen-charged in the production cell through application of a constant reduction current of -3.1 mA, that corresponds to potential of -1100 mV Ag/AgCl according to potentiodynamic polarization curve.This potential was chosen to simulate a cathodic protection condition, although it is suspected that this potential may not be a protection potential for the steel tested.Afterwards, a second test was performed, this time, through application of a constant current of -21 mA, that corresponds to potential of -1300 mV Ag/AgCl according to the same curve, to simulate a cathodic overprotection condition.The detection cell was kept at a constant oxidation potential of +300 mVsce, and the permeated hydrogen was measured by chronoamperometry technique using EC-LAB software (v.10.02)controlled by a Biologic VMP3 multichannel potentiostat.This procedure was repeated two times for each metallic membrane in order to obtain two consecutive hydrogen permeation curves 34 .Were performed three tests for each condition in order to ensure experimental repeatability.
According to this technique, after the first permeation transient, hydrogen production is interrupted to allow a complete outgassing and a second transient is then obtained after applying a new charge.During the first charge, all traps are filled, and when discharging is performed, only the reversible traps are emptied, for this reason, the second transient should be faster.The difference between the relative positions of transients should reveal the presence and the extent of irreversible trapping.
The steady state hydrogen permeation flux is given by 26 : where J ∞ is the steady state hydrogen permeation current density and F is Faraday's constant.The coefficient of diffusion, D, can be calculated based on the elapsed time (t lag ) at J(t)/J ss = 0.63 and the breakthrough time (t b ) through the following equations 26 : where L is the membrane thickness.D represents the apparent diffusivity, D app , using the first transients, and the effective diffusivity, D eff , using the second transients.The permeability is given by 26 : The subsurface hydrogen concentration (solubility) is given by 26 : (D L is the diffusivity coefficient of pure iron), the trapping density in galvanostatic charging conditions is given by 35 : where N A is the Avogadro's number.
In tensile mechanical tests several specimens were tested in the as-received condition, and others were tested after being hydrogen-charged.For this reason, before starting mechanical tests one part of round tensile samples of as-received steel was hydrogen-charged in a cathodic protection cell, with schematic shown in Figure 3, filled with synthetic seawater 28 without application of mechanical loads.A titanium grid (known as Fischer electrode) surrounding the specimen was used as counter electrode, in order to guarantee the hydrogen flux in all directions.
The hydrogen was produced galvanostatically, and at the same time its cathodic protection potential monitored, during a time enough to get the material to be completely saturated with hydrogen.Characterizing the saturation time is very important, as it may happen that samples charged for very long periods, such as weeks or months, undergo cracking without the application of any external load, giving rise another degradation process.Therefore, saturation times different from those strictly necessary, may mischaracterize the tests.The selected potentials for the hydrogen-charging procedures were: -1300 mV Ag/AgCl , -1100 mV Ag/AgCl , -950 mV Ag/AgCl and -900 mV Ag/AgCl .The saturation times for the potentials of -1300 mV Ag/AgCl and -1100 mV Ag/AgCl were established from results of the first permeation transients, assuming that complete saturation of the material occurs when the steady state is reached.The saturation times for potentials of -950 mV Ag/AgCl and -900 mV Ag/AgCl were estimated since the permeation tests for these potentials were not performed.In this estimation the time calculated for the potential of -1100 mV Ag/AgCl was used as a reference value, understanding that a shorter time than this would be sufficient to saturate a specimen of the same dimensions, with a much lower potential.
The mechanical tensile tests were performed in an INSTRON 5582 universal testing machine.The tensile samples were loaded until fracture at room temperature at a strain rate of 2.5•10 -5 s -1 , according to ASTM G129-00 36 .For the tensile tests on the hydrogenated steel, the hydrogen-charged samples were transferred to testing machine immediately after the completion of the saturation time in the electrochemical cell.The tests were accomplished with a cathodic protection cell coupled to the testing machine, shown in Figure 4, to prevent hydrogen desorption.The potential of -1300 mV Ag/AgCl , considered an overprotection potential 19,20 , was employed in the first test.In the subsequent tests, the "less negative" potentials were employed, until a value was found for which the effect of hydrogen on the mechanical properties of the steel was practically null.The material susceptibility to hydrogen embrittlement was evaluated by determining the embrittlement index, I HE , which compares the ductility of hydrogenated samples (brittle samples) with the ductility of as-received steel samples.Values of this index close to 1 indicate that the material is resistant to hydrogen embrittlement, while lower values indicate a decrease in this resistance and, therefore, an increase in its susceptibility to the degradation process.Very low values indicate that the material is highly susceptible to hydrogen embrittlement.This index is given by 36 : where ε H is the failure strain of the hydrogenated samples and ε f is the failure strain of the hydrogen-free samples.
Finally, SEM analysis of fracture surface was conducted in order to determine variations in the fracture mode of steel, both without hydrogen and under the effect of hydrogen.

Results and Discussion
Figure 5 shows the image of API 5CT P110 steel in the as-received condition captured by an optical microscope.
The microstructural analysis exposes a microstructure composed of fine tempered martensite, typical of quenched and tempered steels, and dispersed carbides.This heat-treatment is required by the API 5CT standard 37 for this type of steel.Their chemical composition is shown in Table 1.

Electrochemical test
The potentiodynamic polarization curve for API 5CT P110 steel in 24g/l NaCl solution is shown in Figure 6.
The permeation tests were performed under two sets of conditions.In the first test, metallic membranes of as-received steel were hydrogen-charged through application of a constant current of -3.1 mA, that corresponds to potential of -1100 mV Ag/AgCl according to potentiodynamic polarization curve, to simulate a cathodic protection condition 20 .Afterwards, in a second test was applied a constant current of -21 mA, that corresponds to potential of -1300 mV Ag/AgCl according to potentiodynamic polarization curve, to simulate a cathodic overprotection condition.The hydrogen permeation curves of the as-received steel are shown in Figure 7 and Figure 8.The diffusivity, permeability, and solubility obtained from these curves and the application of Equations 1 to 5, are shown in Table 2.
Table 2 shows that the changes in hydrogen availability related to the two reduction currents, -3.1 mA and -21 mA (which correspond to -1100 mV Ag/AgCl , or cathodic protection condition, and to -1300 mV Ag/AgCl , or cathodic overprotection condition, respectively), affects the hydrogen permeation parameters of steel.This is especially reflected in the decrease of the apparent diffusion coefficient, D app , by a factor of 0.5, and an increase in hydrogen solubility, C 0 , by a factor of 4.8.As the potential becomes more negative, there is a decrease in diffusivity and an increase in solubility, consequently, a greater amount of hydrogen becomes available to migrate towards more attractive regions in lattice.These results show the influence of hydrogen trapping on hydrogen permeation parameters: irreversible traps are quickly saturated with diffusible hydrogen before it is available to fill up the reversible traps and before it continues to diffuse to other locations 38 .The observed difference in the slopes of the 1 st and 2 nd transients in Figure 7 and Figure 8 is also a result of hydrogen trapping because it affects the hydrogen elapsed time.According to Van den Eeckhout et al. 39 reversible trapping has an important influence in the slope of transients.The greater the reversible trapping, the lower the slope of the curve.
In order to evaluate hydrogen trapping, both transients of each condition must be compared.In Figure 7 and Figure 8, it can be observed that the hydrogen flux in the second transient is smaller, which complicates the evaluation.To overcome this difficulty, curves must be compared in terms of the normalized flux J/J ss and dimensionless time τ (     This procedure assumes that no surface evolution occurs during the entirety of the experimental tests and a steady state is reached.In order to help to better control of the surface phenomena, it is recommended that the exit side of the metallic membrane be covered with a thin palladium layer 40 .
In the case of the steel tested in this work, the permeation measurements were conducted without a palladium deposit on the membranes, given that the steady state had been reached in tests.The extent of reversible trapping is determined by the τ value to which the first transient is displaced.Depending on the reversible trapping density, the second transient is shifted to values closer or further from the first transient; the greater the proximity, the greater the effect of reversible trapping.Therefore, the relative distance between the first and second transients also indicates the irreversible trapping magnitude.
The normalized permeation transients for reductions currents of -3.1 mA and -21 mA (that corresponds to potentials of -1100mV Ag/AgCl and -1300 mV Ag/AgCl , respectively) are shown in Figure 9 and Figure 10.The proximity between the first and the second transients plotted in each of the applied potentials suggest that the extent of irreversible trapping is low for both conditions.For the reduction current of -3.1 mA, the proximity between the two transients and the decrease in the hydrogen breakthrough time indicates that reversible and irreversible trapping both share importance in global trapping.For the reduction current of -21 mA, the proximity between the two transients and the increase in the hydrogen breakthrough time indicates that reversible trapping is the main influence in the overall global trapping.These considerations are closely correlated with the mechanical response of the material to hydrogen effects, which will be discussed later.The global trap density,   , the reversible trap density,   , and the irreversible trap density,   , characterized for each potential obtained from data of these curves, are shown in Table 3.
Table 3 demonstrates that the changes in hydrogen availability related to the two reduction currents, -3.1 mA and -21 mA, affect the hydrogen trapping density of the studied steel.Although alteration in the quantity of reversible and/or irreversible trap sites is not expected, since there are no microstructural changes caused by use of cathodic protection, there is a change in the coverage of these sites due to the greater amount of atomic hydrogen that is solubilized when the current of -3.1 mA (potential of -1100 mV Ag/AgCl ) is applied.As solubility increases when the potential for hydrogen generation is more negative, more traps sites are filled.This is reflected by increases in the reversible trapping density, N r , and to the irreversible trapping density, N i , by factors of 8.4 and 1.9, respectively.This indicates that most of the "additional" hydrogen solubilized during the application of the current of -21 mA (potential of -1300 mV Ag/AgCl ) is weakly retained in the reversible traps of the microstructure.This fact has important implications in the mechanical response of API 5CT P110 steel under the effect of hydrogen, which will be described below.
The effects of hydrogen on metallic materials have been extensively researched and many works related to the hydrogen trapping have been published [41][42][43] .It is now well established that the characteristics of hydrogen traps affect the mechanical behavior of the hydrogenated material, and that the hydrogen susceptibility of steels is closely related to trapping 44 .The hydrogen in irreversible traps has no obvious effect on the fracture behavior of steels 45 .Although some studies show the "beneficial" effect of irreversible trapping 9,46,47 , others highlight the potential of deep irreversible traps to start cracking when they are saturated with hydrogen 4,47-49 .On the other hand, hydrogen in reversible traps is more harmful because it is able to migrate more easily to the high stress concentration sites, like the crack tips, becoming a fundamental factor for failure to occur 46,[50][51][52] .Therefore, identifying the dominant trapping type of a steel is crucial for determining its susceptibility to hydrogen embrittlement.
In the case of API 5CT P110 was verified that reversible trapping is predominant and, as the hydrogen availability increases, more and more reversible traps are filled.Among other heterogeneities present in the microstructure of studied steel, there are grain boundaries, dislocations (considered reversible traps), Fe 3 C and TiC (considered irreversible traps), with activation energy of 20 KJ/mol, 26 KJ/mol, 84 KJ/mol and 95 KJ/mol, respectively 22,48 .

Mechanical tests
The tensile mechanical tests were performed on samples of as-received and hydrogen-charged steel, completely saturated.The currents for the selected potentials were obtained through the potentiodynamic polarization curve.The saturation times for the selected cathodic polarization potentials, obtained using the permeation tests results, are shown in Table 4.
The strain-stress curves for samples of the studied steel, without and with hydrogen, are shown in Figure 11.An important loss of ductility can be observed as the applied potential is more negative and the hydrogen production increases.As a large amount of available hydrogen atoms are weakly trapped in the reversible traps and can easily diffuse to stress concentration sites when a mechanical load is applied, hydrogen embrittlement processes can be initiated.
The tensile properties obtained from these curves are shown in Table 5.The embrittlement indices obtained for each test condition show that, in the case of the potential of -900 mV Ag/AgCl , the effect of hydrogen was practically negligible.At the other potentials, this effect becomes increasingly intense as the potentials become more negative.
The main factors that determine the hydrogen embrittlement susceptibility of API 5CT P110 steel are hydrogen solubility and hydrogen trapping ability, conditioned by a predominance of reversible traps in microstructure.Therefore, from the results found here, it can be stated that: a) API 5CT P110 steel is very susceptible to hydrogen embrittlement; b) the cathodic protection potentials in synthetic seawater, for API 5CT P110 steel, are in the range of -850 mV Ag/AgCl to -900 mV Ag/AgCl and that more negative potentials can be considered overprotective.
In Table 5 σ Y is the yield strength, σ UTS is the ultimate tensile strength and ε f is the failure strain.The examination of fracture surfaces provides useful information about the role and contribution of hydrogen, generated at different protection potentials, to changes in fracture behavior as well as to the strength and ductility of the steel.In Figure 12(a) dimples (red arrows) can be observed throughout the extent of the fracture surface as result of the microvoids coalescence.This explains the ductile behavior of the metal in as-received conditions.

SEM analysis of fracture surface
The causes of the small loss of ductility of hydrogenated steel at the potential of -900 mV Ag/AgCl can be identified in Figure 12(b).Microcracks already formed (red arrows) or in a coalescence process for larger cracks (green arrows) can be observed.These cracks are a sign that the steel has undergone localized embrittlement processes, with direct effects on the mechanical response registered by tests.In Figure 12(c The changes observed in the fracture surfaces, from ductile microvoid coalescence on the free hydrogen steel to extended quasi-cleavage on the hydrogen-charged steel at potential of -1300 mV Ag/AgCl , explain the decrease in ductility when protection potential becomes more negative.As quasi-cleavage fracture morphology is characteristic of hydrogen embrittlement processes [53][54][55] , the increase in the extension of regions showing this fracture mechanism as protection potential becomes more negative indicates that the material is increasingly more brittle as hydrogen generation increases.
The role of hydrogen trapping in the obtained results is crucial.As greater quantity of hydrogen atoms generated at the more negative potentials are weakly trapped in reversible traps, they are able to diffuse to high stress concentration sites, proving the direct relationship between trapping characteristics of API 5CT P110 steel and its high susceptibility to hydrogen embrittlement.

Conclusions
In this work the hydrogen trapping in API 5CT P110 steel was characterized experimentally, as well as their hydrogen embrittlement susceptibility was evaluated.The following findings can be drawn from permeation experimental results and from results of tensile mechanical tests: i.The API 5CT P110 steel is highly susceptible to hydrogen embrittlement.ii.The susceptibility to hydrogen embrittlement of API 5CT P110 steel is strongly associated with the trapping characterized in this research, that is mainly reversible.iii.Was observed a decrease in ductility as the protection potential became more negative.The change on fracture mode, from ductile microvoid coalescence on the as-received steel to quasi-cleavage on the hydrogen-charged steel, explain this comportment.The extension of quasi-cleavage regions is related with degree of material embrittlement.iv.The loss of ductility was important for slightly more negative potentials of -950 mV Ag/AgCl and critical to potentials more negative of -1100 mV Ag/AgCl .This information should be taken into account in structural integrity assessments of structures made from API 5CT P110 steel that have cathodic protection systems.Finally, it was established the lowest potential that characterizes the onset of the cathodic overprotection for studied steel, information that can certainly be used for designing cathodic protection systems for underwater structures made of API 5CTP110 steel.

Figure 1 .
Figure 1.Schematic of round tension test specimen used in tensile tests.

Figure 2 .
Figure 2. Schematic of electrochemical double-cell used in potentiodynamic polarization and permeation tests25.

Figure 4 .
Figure 4. Tensile testing machine with coupled cathodic protection cell.
to the procedure proposed by Pressouyre and Bernstein34 .

Figure 9 .
Figure 9. Normalized hydrogen permeation transients of API 5CT P110 steel in NaCl solution (24 g/l) at reduction current of -3.1 mA.

Figure 10 .
Figure 10.Normalized hydrogen permeation transients of API 5CT P110 steel in NaCl solution (24 g/l) at reduction current of -21 mA.

Figure 12
Figure 12 display SEM images of the fracture surface of the API 5CT P110 steel samples without hydrogen and hydrogen-charged at potentials of -900 mV Ag/AgCl , -950 mV Ag/AgCl and -1300 mV Ag/AgCl , after the tensile tests.

Figure 11 .
Figure 11.Stress-strain curves of API 5CT P110 steel, without and with hydrogen.
), microcracks, dimple rupture and incipient quasi-cleavage regions (green arrows) are observed across the fracture surface.The quasi-cleavage regions and the large number of microcracks explain the more fragile behavior of steel at potential of -950 mV Ag/AgCl than at the potential of -900 mV Ag/AgCl .The fracture surface shown in Figure 11(d) displays large quasi-cleavage regions (red arrows) surrounded by dimple rupture regions.The extension of the quasi-cleavage regions explains the increased steel embrittlement under the potential of -1300 mV Ag/AgCl .
Experimental Characterization of Hydrogen Trapping API 5CT P110 Steel.Part.I: Effect on Hydrogen Embrittlement Susceptibility

Table 4 .
Saturation times for tensile specimens under different cathodic polarization potentials.

Table 5 .
Tensile properties of API 5CT P110 steel, without and with hydrogen.