Butter-weld Interface Microstructural Analysis Employing NCS and LAMS Sections

The formation of brittle microstructures around the fusion line in dissimilar welds has required a deeper microstructural analysis in this region. The study becomes more relevant when these welds are used in environments that facilitate hydrogen embrittlement. The present work aims to characterize the microstructure and hardness at the diluted zone interface in joints welded with dissimilar materials. Aiming for a better efficacy in the microstructural characterization of this zone, samples of both normal cross-section (NCS) and section with slope were used, according to the low-angle microsectioning (LAMS) technique, which allows a greater amplification of partially mixed zones (PMZs). The results indicated the diffusion of carbon from the heat-affected zone (HAZ) towards the fusion line which, in combination with other alloying elements, form highly brittle carbides. In turn, the hardness of the base metal and the HAZ was reduced after post weld heat treatment, whereas in the weld metal an opposite behavior was observed. The dissimilar interface was promising for applications in environments facilitating hydrogen embrittlement, especially regarding the characteristics of zone Φ.


Introduction
The application of dissimilar welded joints is present in the power generation, petrochemical and transformation industries [1][2][3][4][5] . In the oil and gas extraction system, mainly offshore, these joints are subjected to very unfavorable working conditions, both in terms of oxidation and embrittlement and high pressures [6][7][8][9] . These conditions have demanded the adoption of materials and manufactoring processes that allow better mechanical properties and a lower sensitivity to the presence of hydrogen 10,11 . Among these materials Nibased superalloys stand out for their good performance in terms of mechanical and corrosion resistance 12 . Among the components of the offshore system that are constituted by dissimilar welding, there are components such as Manifolds, Flowlines and Risers 10,13 . These have used high-strength low-alloy (HSLA) steels, for example 8630 and F22, which receive buttering weld multipasses with Ni-based weld metal (e.g. alloy 625 and 725) 14,15,2 . In view of the need to meet the hardness criteria of 22HRC or 250HV10 specified by NACE MR0175 / ISO 151567 16 for the heat-affected zone (HAZ), the welded material is subjected to a post weld heat treatment (PWHT).
The heat generated by passing the welding torch on the metal surface creates a complex microstructure in the HAZ that may contain mainly fresh martensite in the base metal 17 . The thermal cycle in arc welding consists of rapid heating (hundreds of degrees per second), followed by relatively rapid cooling (on the order of tens to hundreds of degrees per second) 2 . The microstructural change in the HAZ is dependent on the heating and cooling rates which, in turn, are determined by the welding heat, the thickness of the workpiece to be welded, the geometry and interpass temperature 18 . Subsequent microstructural changes directly affect mechanical properties, especially in HAZ, which are directly interconnected to the hardness of the material 2 . Thus, a microstructural characterization process that allows for a more expanded microstructural survey is of fundamental importance. In this sense, the low-angle microsectioning LAMS technique stands out for its ability to enlarge partially diluted zones (PMZs), due to the sectioning of the samples with angle less than 90º, thus ensuring a much more precise microstructural characterization of these zones, thus allowing a characterization microstructural efficiency of these zones for the welding and PWHT conditions employed. This way, one can perform execution of punctual indentations that specifically cover each zone in isolation. Another important factor in adopting the LAMS technique is that dissimilar welding is considerably more complex than welding similar materials, being characterized by large composition gradients and microstructural changes around the melting line 19 .
Even given the hardness criteria specified above, a number of failures in dissimilar underwater welds have occurred. The cause is attributed to hydrogen embrittlement resulting from the cathodic protection process which, in turn, is directly associated with the microstructure of the material, especially the presence of the PMZs around the fusion line 20 . The most notable case was that of the Thunder Horse platform operated by BP in the Gulf of Mexico in 2006 10 . Among the materials cited in the literature, the joints between 8630M / 625 are mentioned in the history of failures 13 . The F22 / 625 joint has shown promise due to the lower carbon content in its composition. The occurrence of hydrogen embrittlement, among other factors, is due to the microstructure at the dissimilar interface, mainly due to the precipitation of carbides 21,22 . The microstructure of the interface is a function of the chemical composition of the materials, the welding process and the PWHT. The latter has generated a metallurgical dilemma since, as the hardness of the HAZ is reduced by the PWHT, the carbon of the base metal diffuses towards the fusion line 23 . According to the PWHT parameters, the carbon can reach the planar growth zone (Φ), increasing its hardness, and consequently making it more susceptible to hydrogen embrittlement, due to the presence of M 7 C 3 carbide 24 .
The motivation of the present study is the achievement of a microstructural analysis of the weld with base metal, forged steel ASTM A182 F22, buttered with Ni-base alloy, Inconel 625. In this analysis, the techniques of normal cross-section (NCS) and low-angle microsectioning (LAMS) were used, the latter allowing an expansion of the dissimilar interface, thus guaranteeing more reliable punctual microhardness results for partially mixed zones (PMZs), such as example Φ and M, which are usually quite narrow 25,19 . Considering the results obtained in the literature for the forged steel ASTM A182 F22, which aimed to reach an optimal point for PWHT 24 , a PWHT of 6 hours at 677ºC was carried out in this work, in order to compare its effectiveness in relation to other conditions already studied. The results were very satisfactory both in terms of cost / time and in meeting the hardness requirements established in the NACE MR0175 16 standard for subsea applications.

Materials
In the dissimilar buttering layer, forged ASTM A182 F22 steel was used as the base metal (BM) and as the weld metal (WM) the Ni-base alloy, Inconel 625 (ERNiCrMo-3). Table 1 shows the chemical composition of both materials.

Welding process and PWHT
In the buttering process, the Gas Metal Arc Welding (GMAW) method was used, where the main parameters are represented in Table 2. The protection of the arc and the region of the buttering was made by the gas mixture composed of gases Ar and He, in the proportions of 75% and 25%, respectively. In the buttering, a total of 16 weld beads were distributed in four layers and each layer was composed of four beads. This overlap of beads was sufficient to ensure that after the machining the addition metal was 9.5mm thick enough to prevent ASTM A182 F22 steel from undergoing severe thermal input after the application of the joint.
After the buttering process the part was submitted to a PWHT for 6 hours at 677 ± 10ºC. In the definition of these PWHT conditions, the feasibility of the process was prioritized from the practical point of view, as well as the condition that presented the parameter Hollomon-Jaffe (HJP) between the range of 19,500 and 20,000, since the authors Dai and Lippold 25 verified, in this range, good results in reducing the HAZ hardness level of the ASTM A182 F22 steel. The parameter HJP is defined by Equation 1 and considers the temperature (T) in Kelvin and time (t) in hours 26 . In the PWHT, a heating rate of 20ºC / min was used, and the material was cooled in the still air.

HJP = T * (20 + log t)
(1)   The expansion of the transition region by the LAMS technique allows the analysis of microstructural characteristics more accurately, especially in terms of Vickers hardness, since it allows the adoption of loads up to 100gf in the planar growth zone (Φ), in the grain outline and in the "swirls" and "islands". While in normal cross-sectional samples, Figure 1(b), the indentations with the mentioned load transcend the PMZ, such as Φ zone and a 'island' region. Thus, the LAMS technique, Figure 1(c), is therefore very important in characterizing the microstructure and hardness of each zone individually. All samples were sanded with SiC-based abrasive material, with granulation of up to #1200 and 3 and 1/4μm diamond paste were used for polishing. Between sanding and polishing the samples were cleaned with acetone on ultrasound. The etchants, to reveal the microstructure of the F22 steel, were performed by immersion in 2% nital solution for 20s. This etch was followed by electrolytic etching with chromic acid at 10% at 5V voltage and duration of 30s with the aim of visualizing alloy 625.

Microstructural analysis
All analyzes were performed around the fusion line (FL) of the buttering using samples in the as-welded and after PWHT conditions. In the microstructural analysis we used an Olympus BX41M -LED microscope with an image acquisition system, as well as a scanning electron microscope TESCAN model VEGA 3. By means of the dispersive energy detector (EDS) the chemical composition of the PMZs of the dissimilar interface was raised.

Hardness and microhardness tests
In the hardness and microhardness tests the samples as-welded and after PWHT were also considered. These were performed according to the recommendations of NACE Standard MR0175 16 and DNV Standard Offshore OS-F101 28 . In the hardness tests, normal Rockwell C scale was used through a Mitutoyo model HR-320MS, while the microhardness tests were performed on Shimadzu model HMV-2, with load of 100gf (HV 0,1 ) for 15s.
The microindentations were done in a punctual way (in the PMZs) and uniformly distributed along the weld metal (WM), HAZ and BM. In the first situation, LAMS samples ( Figure 1 (c)) were used, due to the high area magnification that this technique allows. In the evenly distributed assays, NCS samples were used, which becomes efficient in the microstructural evaluation of the WM, HAZ and base metal (BM) regions. Figure 2, shows the demonstration scheme of the test procedure, represented by 9 columns of indentations grouped from 03 to 03. In each group 62 impressions were made that totaled 186 indentations. The distance between the impressions of a group was 0.5 mm, as shown in Figure 2. In addition, it should be noted that, from the five indentations highlighted in Figure 2, the mean value corresponding to one point of the curve of the hardness profile curve was taken. In total, three curves of the hardness profile were obtained, one being for a group of columns, resulting in the hardness profile curve presented in section 3.2.

Dissimilar interface microstructure in the aswelded and after PWHT conditions
In the images of Figure 3, the microstructure of the buttering weld interface for NCS is shown. In the BM region the zone Δ (coarse grains) is characterized by the presence of a more evident decarburization and with larger grains of ferrite and / or retained austenite, Figure 3 (a). Comparing the images of Figure 3, it is verified that this region is larger after the PWHT, indicating that the treatment favored decarburization of the zone Δ. The width of this region varies along the NCS, having an average size of approximately 40 and 80 μm, in both conditions as-welded and after PWHT. Figure 3 (b) shows the predominance of ferrite and / or retained austenite microstructure in the BM, corroborating the effect of carbon diffusivity in the vicinity of the fusion line. Dodge et al. 22 observed that high values of carbon activity are present in ASTM A182 F22 steel when compared to the addition metal, with the carbon likely to diffuse in the direction of its thermodynamic activity gradient. Alexandrov et al. 19 observed that after PWHT carbon tends to migrate from BM to austenitic WM. However, at typical PWHT temperatures the carbon activity in the weld metal remains comparatively low. This is attributed to the diffusivity in the austenite being considerably smaller than in the ferrite and the solubility of the carbon is higher 22 .
In the as-welded condition (Figure 3 (a)), the carbides were more elongated, suggestive of martensitic formation. While after PWHT (Figure 3 (b)), the microstructure presented a tempered morphology. This situation has been associated, in addition to the tempered martensite reaction, to several carbides, of which we can highlight M 6 C 2 , M 7 C 3 25 and M 23 C6 2 . Figure 4 shows the carbide formation curves related to ASTM A182 F22 steel in quenched and tempered condition 29 . Considering the PWHT of 6 hours at 677ºC, represented in Figure 4 by the yellow point, there is a favoring in the formation of Fe 3 C, Cr 7 C 3 and Mo 2 C. Among these carbides mentioned, Fe 3 C and Cr 7 C 3 commonly found in the interface of dissimilar welded joints, are particularly sensitive to hydrogen embrittlement. These carbides may act as hydrogen trapping sites and may be present at the dissimilar interface of the ARBL-Inconel 625 23 , providing a low energy fracture path mainly along the zone M 22,30,31 .
Following the WM in Figure 3 (a), the zone Φ is delimited by dashed lines between the Π and Δ zones, or by the discontinuous formations, such as the "beach" type (red arrow). The zone Φ was continuous, with no contour inside and with microstructural shade suggestive of the Body-centred cubic(BCC) matrix of alloy 625 23,21,19 . The formation of this zone is due to the low solidification rate and the high temperature gradient between the liquid weld metal and the solid base metal 27 . The thickness of this zone varied and, in general, had a dimension of approximately 10μm. Dodge et al. 22 found a planar zone with a thickness of 32 μm, applying a lower welding energy. A positive factor in reducing the thickness of zone Φ is the inhibition of formation of Cr 7 C 3 -type carbides in this zone, which may arise mainly after prolonged PWHT 22 . Considering that the time of PWHT employed was 6 hours, as well as the fact that the authors Dodge et al. 22 treated the F22-alloy 625 joint for 10 hours and did not observe the formation of this carbide, the microhardness results presented suggesting an inhibition of this carbide in zone Φ. Both the reduction of thickness and the inhibition of carbides are positive for applications in environments susceptible to hydrogen embrittlement.
Also related to Figure 3 (a), we highlight the cell and columnar dendritic zones (blue arrow) that make up the microstructure of the weld metal. Figure 3 (a) shows the cellular dendritic zone (Π), located above the zone Φ. The cell dendritic zone is formed due to a change in the solidification rate and temperature gradient 27 . The columnar dendritic region is characterized by the absence of dilution of the base metal as well as by the strongly oriented granulation according to the welding direction. The presence of precipitates of Nb, Mo and Cr in the interdendritic and grain boundaries of alloy 625 is mentioned in the literature 22,32 .
The dilution at the dissimilar interface of buttered welds as-welded and after PWHT was raised via EDS to define the partially mixed zones (PMZs).
In Figure 5, in the section from 13 to 43 μm, it was verified that the increase of Fe presented a milder gradient, being accompanied by reductions of Ni, whereas Cr and Mo showed practically no alterations. When the amplified SE image is observed and shown below the graph, it is verified that the behavior of Fe in this section comprises the entire zone Φ and part of zone Δ. In relation to the zone Φ, this presence of Fe was already expected, considering that it is frequently  quoted in the literature in works employing the GMAW welding process for low alloy steel-Alloy 625. Dodge et al. 22 associate the presence of Fe in the zone Φ with the fact that the greatest composition changes occur in regions of planar solidification compared to the cellular dendritic areas (Π). With respect to the 43 to 49 μm stretch of Figure 5, a steep increase of Fe is observed, whereas Ni and Cr behave in opposite ways. Mo, on the other hand, presents a very discrete reduction. Correlating the graph with the SE image of the magnification of the mapping line, two important pieces of information are verified: the first is the fact that the cited stretch is also associated with the zone Δ of the HAZ of the base metal, in this way it is observed that the dilution between BM and WM occurs before the melting line. Soysal et al. 33 associates the composition gradient at the dissimilar interface with the partial mixture between the liquid base metal and the melt pool, which, among other mechanisms, may be associated with the convection phenomenon in this mixture. The second information is that the welding process promoted a high content of Cr and Ni in the zone Δ, supporting the previous discussion regarding the presence of Cr 7 C 3 carbide in ASTM A182 F22 steel. The increase in Ni content favors the stabilization of austenite in the zone Δ, as well as reducing the temperatures A 1 and A 3 in the "swirls" 19 .
Finally, the stretches from 0 to 13μm and from 49 to 80μm correspond respectively to the regions of WM and BM whose compositions did not suffer significant partial mixtures, prevailing the original composition.
With respect to the EDS result of the butter welding in the condition after PWHT, Figure 6, for the 15 to 28 μm stretch, gradients of compositions similar to that of the material as welded were verified, proving the occurrence of dilution in the Δ and Φ zones. In the 7 to 15 μm stretch, a soft composition gradient is observed in the cellular dendritic zone (Π). As mentioned previously, some authors such as Beaugrand, Smith and Gittos 23 mention that zones Φ and Π constitute PMZs. Also with respect to Figure 6, similar to the material as-welded, the presence of a higher Cr and Ni content in the zone Δ was also verified after PWHT. Considering that during this treatment the diffusion of carbon is favored, this result reinforces the presence of Cr 7 C 3 carbide in ASTM A182 F22 steel.
The following are the optical microscopy images of the buttering weld of LAMS samples as-welded or after PWHT. Initially, it is important to note that the martensitic microstructure was not observed in buttering weld aswelded. In Figure 7 (a) formations of the type "swirls" and "islands", were presented with a microstructure similar to the one of the ferritic matrix. However, the microhardness values of these formations were close to 300 HV 0.1 , according to examples shown in Figure 7 (a).
Thus, for joint F22-alloy 625 in as-welded condition, the results suggest the presence of retained austenite (RA) in the "swirls" and "islands". Note the point at 43 μm in the EDS of the buttering welded as-welded, Figure 5 shows that the partially mixed zone has a nickel content close to that of the weld metal without dilution (0 to 13 μm). Probably, the higher nickel content generated a dilution in the region of these formations which, together with the cooling rate, favored the stabilization of the retained austenite at room temperature. Figure 7 (b) shows the existence of macrosegregation, evidenced by dark regions in the base metal, known as zones M. These zones are characterized by the microstructural similarity with the base metal, having a very significant presence of martensite. Among the forms of presentation of the zone M, Figures 3 (b) and 7 (b), a predominance of the types "beaches" and "swirls", were quite defined. The authors Dodge et al. 22 and Fenske et. al. 21 mention that this type of formation is independent of the PWHT, being due to the welding parameters. Alexandrov et al. 19 , when studying weld 8630/625, found that the dilution between WM and BM may favor during the PWHT the partial or complete reversal of austenite in the "swirls".  As for the martensitic formation, verified after the PWHT of 6 hours at 677ºC, it may have been due to a saturation of carbon in the retained austenite (RA), promoting martensitic formation with air cooling. Likewise, authors, Fenske et al. 21 mention that the high content of Ni can reduce the temperature A C1 , making it lower than the temperature of PWHT, favoring the reactivation in the discontinuous PMZs with microstructure of the base metal, consequently generating martensite after cooling.
Finally, the results of EDS presented indicate that the PMZs is composed of the zones Δ, Φ, Π and M. With the exception of zone Δ, the other three zones mentioned are in accordance with the definition adopted by Beaugrand, Smith & Gittos 23 . It is important to note that compositional changes within these zones have been considered independent of the duration of PWHT, indicating that it occurs during the welding process 21 .
Another observed formation in the welded joint studied was the "islands" shown in Figure 8, which, unlike those specified in Figure 7, showed WM microstructure being surrounded by BM. The observed formation suggests the presence of mechanism in which the liquid temperature of the melt pool is greater than the liquid temperature of the base metal. The presence of this mechanism together with the convection of the fusion pool may favor the presence of this formation.
In the image of Figure 8 (b), we can see formations that have been called "fingers", and correspond to the WM penetration in BM. Several authors, among others, Alexandrov et al. 19 characterized the microstructure of this formation as austenitic, similar to the planar zone. Although the formations are present in the material after PWHT, Fenske et al. 21 attribute the presence of these formations to the welding process and not to the PWHT. These authors observed, during the solidification, very steep temperature gradients in the planar growth zone (Φ). Thus, during solidification, the liquid which may have a temperature lower than the solid phase, together with the convection of the melt pool, can promote penetration and solidification of the "fingers".

Hardness and microhardness in the as-welded and after PWHT conditions
The hardness and microhardness tests were performed on the buttering welds as-welded and after PWHT. Regarding the weld beads, the hardness tests were performed in the transverse (ST) and longitudinal (SL) sections. In Figure 9, the average values of Rockwell C hardness with their respective standard deviations can be verified for ST and SL. For the analyzed sections indentations were performed in four regions, base metal (BM), HAZ and weld metal (WM -1st and 2nd beads), in accordance with NACE MR0175 16 . Analyzing the results presented in Figure 9, it was observed that in the as-welded condition, the BM and HAZ of the buttering weld, in both sections SL (green) and ST (light blue) presented average values between 26 and 28 HRC. These results were already expected due to the use of ASTM A182 F22 in the forged state, as well as the fact that the welding thermal input and the subsequent cooling favor the formation of microstructures with high levels of residual tension and hardness in the HAZ. In relation to the 1st and 2nd weld beads, sections SL (green) and ST (light blue), there was a hardness increase of the 2nd layer of filler metal in relation to the 1st layer, for both sections. This behavior may be related to the precipitation hardening coming from the thermal supply of the multiple beads of the buttering weld.
From the dark blue (SL -after PWHT) and yellow (ST -after PWHT) columns of Figure 9, it is observed that the mean values of hardness together with the standard deviation values are close to 18HRC for the BM and HAZ regions. This result shows that the HJP of 19,742 allowed the reduction, which was expected, of the HAZ hardness level. The materials applied in environments containing H 2 S in the production of oil and gas must meet, among other criteria, the hardness levels established by NACE MR0175 16 , in order to reduce hydrogen embrittlement. This standard states that after the PWHT the maximum hardness of the BM and HAZ should not exceed 22HRC. In the case of weld beads, dark blue (SL -after PWHT) and yellow (ST -after PWHT) columns of Figure 9, a hardness increase is observed for both the 1st and 2nd weld beads, suggesting that the PWHT also promoted precipitation hardening in the multipass cords of the buttering weld. Figure 10 shows the microhardness profiles, with 95% reliability, for the samples extracted along the NCS of the buttering weld as-welded and after PWHT. These profiles were obtained from the arithmetic mean of the three profiles that were raised according to the detail of Figure 3.
In the as-welded condition, red curve, the microhardness results of the weld metal were lower than the HAZ and the base metal. In the three analyzed regions a behavior of non-uniform hardness was verified, being this fact more accentuated in the region of the HAZ. Dai & Lippold 25 found similar behavior in this region, which was associated with the tempering effect of the multibead overlapping process.
In the stretch between 1 and 2 mm, Figure 10 shows peaks of hardness (minimum value of 340HV 0.1 ) that may be associated with the presence of a refinement of the HAZ structure in this region. Differently from the 0 to 1mm and 2 to 4,5mm stretches corresponding respectively to the regions near the fusion line (FL) (Figure 6.3) and transition (HAZ -BM) that presented ferrite with coarse granulation. Fenske 34 cites the presence of a microstructure, in the HAZ, composed of regions of coarse grains, refined and recrystallized.
Similar to the as-welded condition, the microhardness results of the buttering weld after PWHT, black curve, were obtained. The obtained hardness profiles behaved in the opposite way, that is, while the hardness decreased in the HAZ and BM, an increase in the weld metal was observed. The heterogeneity mainly in HAZ was maintained after PWHT, however a significant reduction was observed in the peaks of hardness previously mentioned, whose maximum value was 255HV 0,1 . When the margin of error of 5% is considered, it is observed that the hardness results of the HAZ were close to the value of 250HV specified by NACE MR 0175 16 .
From the results presented in Figure 10, the mean values and standard deviations for the WM, HAZ and BM regions were raised, the results of which are shown in Figure 11. With respect to the WM of this Figure, a 17% increase in the average value of hardness was observed, suggesting that PWHT promoted precipitation hardening. For the HAZ region (Figure 11), it can be observed that, in terms of mean values, the PWHT allowed a reduction of the hardness by 25% where, despite the peaks of hardness verified in Figure  10, the mean values were below 250HV, therefore, within the scope of the recommendations of the NACE MR0175 16 standard. Finally, the mean values for the BM region ( Figure  11) behaved in a manner similar to those of the HAZ.
In the graph of Figure 12 the mean values of punctual microhardness along with the standard deviation for the areas Δ, Φ, Π, RA and M are shown in the as-welded and after PWHT conditions. Complementing the punctual microhardness values shown in Figure 7(a) for retained    Figure 13 for Δ, Φ and M zones.
With respect to zone Δ the data of the graph of Figure  12 demonstrate that after PWHT this zone presented a mean hardness of 240HV 0,1 according to NACE MR0175 16 standard. However, it is worth noting that, when considering the standard deviation, values higher than 250HV 0,1 of the aforementioned norm are considered. Thus, in contrast to the results of HRC hardness and uniformly distributed microhardness, which showed that HAZ met the standard even considering the standard deviation, the punctual microhardness confirms the presence of harder regions in this zone after PWHT.
Considering the hardness results of zone Φ, Figure 12, it is verified that the hardness level of this zone remained practically unchanged after PWHT. This behavior is very promising for the application of the joint in environments facilitating hydrogen embrittlement, since they demonstrate the non-favoring of carbides in zone Φ, which have been closely related to the failures of these joints. It is important to note that this area had an average hardness of 260HV 0.1 , according to Dai & Lippold 25 who observed values above 250 HV 0.1 for this zone. They mention that this zone admits higher hardness values after the PWHT, since it is narrow when compared to the region of coarse grains of the HAZ, which causes the diffusivity of the hydrogen in the Φ austenitic zone to be smaller than in the region of coarse grains of the HAZ 35 . Furthermore, Dodge et al. 22 cite that the precipitation of carbides in the weld metal can affect the mechanical performance of the dissimilar joints.
For the zone Π the results of Figure 12 show an expected increase of the microhardness after PWHT, fact that was also verified in the other tests of hardness raised in the weld metal. Possibly this fact is associated with precipitation hardening 27,25 .
In the last two columns presented on the right side of the graph of Figure 12, the results for RA and martensite, respectively, as-welded and after PWHT are obtained. As can be seen, the mean hardness level of 300 ± 48.3 HV 0.1 is consistent for the retained austenite, as well as 400 ± 38.6 HV 0.1 , consistent with martensite. These results suggest that the PWHT favored the formation of martensite and, corroborate with the microstructure presented in the images of Figure 13(b).

Conclusions
In this work, the influence of the welding process and PWHT on the dissimilar interface of ASTM A182 F22 steel with alloy 625 was investigated. Thus, based on the research developed, the following conclusions were reached: The welding process favored the dilution of Ni in the zone Δ, contributing to the presence of retained austenite (RA) at the dissimilar interface. In turn, after PWHT, zone M presented with characteristics of fresh martensite.
The low-angle microsectioning (LAMS) technique allowed the use of the load level (HV 0,1 ) in the PMZs.
It was observed that the PMZs consisted of Δ, Φ, Π and M zones. It was also observed formations such as "swirls," "beaches", "fingers" and "islands".
The buttering of ASTM A182 F22 steel -alloy 625 met the hardness criteria recommended by NACE MR0175 for HAZ.
With the LAMS technique it was possible to verify that the zone M presented with hardness above 400HV 0,1 , proving the carbon diffusion in the base metal.
From these results it can be concluded that the LAMS technique is very important in the hardness survey around the melting line.