Abstract
The paper demonstrates the prospects of spark plasma sintering (SPS) for the high-speed diffusion bonding of the high-strength ultrafine-grained (UFG) near-α Ti–5Al–2V alloy. The effect of increased diffusion bonding intensity in the UFG Ti alloys is discussed also. The bonding areas of the UFG near-α Ti–5Al–2V alloy obtained by SPS are featured by high density, strength, and corrosion resistance. The rate of bonding in the UFG alloys has been shown to depend on the heating rate non-monotonously (with a pronounced maximum). At the stage of continuous heating and isothermic holding, the bonding kinetics was found to be determined by the exponential creep rate, the intensity of which in the coarse-grained alloys is limited by the diffusion rate in the crystal lattice α-Ti. In the UFG alloy, the exponential creep processes associated with gliding and climb of dislocations, the activation energy of which corresponds to the diffusion activation energy in the lattice dislocation nuclei, may take place simultaneously with the grain boundary sliding and Coble creep, the activation energy of which corresponds to the grain boundary diffusion activation energy.
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Introduction
Structural α- and near-α Ti alloys are used extensively in the production of the heat exchange equipment and other construction units for modern nuclear power plants (NPP) [1,2,3,4,5,6]. Besides, α- and near-α Ti alloys are used widely in petrochemistry, shipbuilding, in production of engineering structures operated at low temperatures, etc. [3,4,5,6,7,8,9,10], the requirements to the reliability and resources for which are getting stricter continuously. Therefore, the requirements to the mechanical and operational properties of the α- and near-α Ti alloys are growing.
To improve the strength of modern Ti alloys, the technologies based on the optimization of their composition and different types of thermo-mechanical processing modes are applied widely at present [3, 5, 6]. One of the most promising ways to improve the mechanical properties of the Ti alloys is to form an ultrafine-grained (UFG) structure in these ones using different methods of severe plastic deformation (SPD), including the technology known as equal channel angular pressing (ECAP) [11,12,13,14], high-pressure torsion [15,16,17,18], multiaxial forging [19, 20], rotary swaging [21, 22], etc. This approach ensures a unique combination of high strength, ductility, corrosion resistance, superplasticity, etc. This, in turn, opens the prospects to ensure a high performance and lifetime of the NPP heat exchange equipment.
One of the key challenges obstructing an extensive application of the UFG Ti alloys is the problem of welding. Traditional argon-arc welding [23, 24] or electron-beam welding [25, 26] accompanied by metal melting fails to preserve the UFG structure with high mechanical properties in the weld. Such solid-phase technologies as conventional diffusion bonding [27, 28], friction stir bonding [29,30,31], or superplastic forming [32, 33] require high temperatures and long holding times that lead to the growth of grains. Thus, all the unique properties of the UFG materials are lost. Note also that in the case of α- and near-α Ti alloys, the weld performance is impossible to improve through additional local heat treatment, which ensures the hardening of the weld as a result of the precipitation of the β-phase particles. In this case, the welds in the UFG α- and near-α Ti alloys have much poorer properties and therefore worsen the service life and safe operation of the entire steelwork.
Spark plasma sintering (SPS) offers better opportunities to obtain the high-strength joints since the idea underlying this innovative technology involves rapid heating in vacuum or in an inert ambient. This effect is achieved by sending the high-power millisecond direct current (DC) pulses through the specimen along with applying a uniaxial pressure [34,35,36,37,38]. This technology produces the high-density structures in the UFG materials at lower optimal sintering temperatures [39,40,41]. High heating rates and faster diffusion at lower heating temperatures are crucial for restricting the grain growth and preserving the UFG structure in the material [34,35,36,37,38,39,40,41].
Note that obtaining a high-density weld as strong as the base metal is a scientific challenge. The high-density structure requires longer holding times at elevated temperatures, while the UFG structure can be preserved through restricting the grain growth by reducing the process time only. This problem can be solved by the diffusion mass transfer mechanism associated with the non-equilibrium grain boundaries during the rapid heating of the UFG metals.
This paper aims to explore the potential of SPS for the diffusion bonding of the high-strength corrosion-resistant UFG α-Ti alloys used in nuclear engineering.
Materials and methods
The study was focused on the Ti–4.73wt.%Al–1.88wt.%V alloy used in the production of the heat exchange equipment for modern NPPs. The chemical composition of the alloy is presented in Table 1. This alloy is one of the near-α Ti alloys, for which the volume fraction of the β-phase does not exceed 5%. General chemical analysis of the alloy was carried out using FOUNDRY®-Master™ spectrum analyzer. The concentrations of oxygen, nitrogen, carbon, and hydrogen were measured by reductive melting using ELTRA® ON-900 (O2, C, N2) and ELTRA® OH-900 (H2) analyzers.
The UFG structure in the alloy was formed by ECAP in the Bc pressing mode (the number of the ECAP cycles N = 4, the ECAP temperature was 450 °C, and the ECAP rate was 0.2 to 0.4 mm/s). ECAP was performed using Ficep® HF400L hydraulic press. Before pressing, the specimens of 14 × 14 × 140 mm in size were held in the operating channel of the ECAP setup for 10 min. The accuracy of temperature control during ECAP was ± 10 °C.
The diffusion bonding of the specimens of 7 × 7×3.5 mm in size was performed using Dr. Sinter® SPS-625 setup (Fig. 1). Dr. Sinter SPS-625 setup allows heating the specimens in the automatic (controlled) regime with the maximum rate up to 700 °C/min; in the manual regime, heating can be performed with the rate up to 2500 °C/min.
The specimens for investigations were obtained by spark cutting into pieces of 14 × 14 × 140 mm in size. The difference in height between the bonded specimens did not exceed 0.02 mm. The surface roughness Rz in the specimens was 40–60 µm. The scatter Rz in the values of the surface roughness originated from the polishing with diamond polishing wax with different diamond grain dispersions. The decrease in the surface roughness leads to a slight decrease in the shrinkage L without any significant change in the slope of the dependence of the shrinkage on the heating temperature T L(T) (Fig. 2). In further analysis of the experimental data, the effect of roughness was accounted for as an error when determining the diffusion bonding activation energy (see "Discussion" section).
The heating rate Vh varied from 10 to 350 °C/min, the bonding temperature T ranged from 600 to 1140 °C, and the applied pressure P changed from 50 to 100 MPa. The temperature was measured by infrared pyrometer Chino IR-AH focused onto the bonded specimen surface. The degree of shrinkage Leff and shrinkage rate Seff was monitored by a dilatometer integrated into Dr. Sinter® SPS-625 setup. The accuracy of temperature control was ± 10 °C, and the uncertainty of the shrinkage measurements was ± 0.01 mm. Bonding was performed in vacuum (6 Pa).
To account for the contribution of the thermal expansion of the Dr. Sinter® SPS-625 sintering setup itself into the measured shrinkage Leff, the measurements of the background shrinkage (without a specimen) L0 were performed. Afterward, the corrected temperature dependence of the shrinkage was calculated using the formula L(T) = Leff (T) − L0(T) (Fig. 2). This procedure helped to avoid the artifact of “negative shrinkage” (expansion) of the specimens, which was observed in the temperature dependencies of the shrinkage during continuous heating often [42].
The structure investigations were carried out using Jeol® JSM-6490 scanning electron microscope (SEM) with Oxford Instruments® INCA 350 energy dispersion spectroscopy (EDS) X-ray microanalyzer and Jeol® JEM-2100 transmission electron microscope (TEM) with JED-2300 EDS microanalyzer. The electron backscatter diffraction (EBSD) analysis was carried out using Tescan® Vega™ 2 SEM with Nordlys™ 2 analyzer. To identify the alloy microstructure with the use of SEM, electrolytic etching was performed at room temperature in a solution of 75% H2SO4 + 15% HNO3 + 10% HF. The thermal stability of the UFG structure of the Ti alloy was studied by analyzing the structure after 30-min annealing, as well as by step-by-step heating of the specimen in situ from 300 °C up to the temperature Tann = 900 °C. The temperature increment was 50 °C, and the pause between the heating steps was 30 min.
The microhardness Hv measurements were carried out using Duramin® Struers™ 5 with the load of 2 kg. In order to study the mechanical properties, the relaxation tests were performed to determine the values of the macroelastic limit σ0 and the yield strength σy (see Appendix A in [43]). The rectangular specimens of 3 × 3 mm in cross section and 6 mm in height were used in these measurements. The uncertainties of the σo and σy measurements were ± 30 MPa. The loading rate was 0.13%/s, the loading time was 0.3 s, and the relaxation time was 60 s. The tensile tests of the double blade-shaped flat specimens with the working part dimensions of 2 × 2×3 mm were performed using Tinius Olsen® H25 K-S stress machine at the deformation rates ranging from 3.3 × 10−3 s−1.
The electrochemical studies were carried out in the aqueous solution of 10%HNO3 + 0.2%HF using R-8 potentiostat. Based on the analysis of the Tafel slope in the potentiodynamic dependencies [the potential E vs the current density i in the semilogarithmic axes E − ln(i)], the corrosion current density icor and the corrosion potential Ecor were determined. Prior to the electrochemical tests, the specimen surfaces were covered by the corrosion-resistant coating except a 4.5 mm2 open area located in the center of the specimen cross sections in the joint area. Before starting the electrochemical tests, the specimens were kept in the electrochemical cell in the aqueous solution of 0.2%HF + 10%HNO3 until a stationary potential value was reached (the holding time was not less than 2 h). Afterward, the E(i) dependencies were measured at the potential scanning rate of 0.5 mV/s.
Experimental results
The Ti alloy in the initial state was featured by an irregular grain size distribution. The average grain size varied from 10–20 μm to 50–100 μm (Fig. 3a). The structure of the coarse-grained (CG) alloy included the equiaxed α-phase grains and the elongated α′-phase grains (Fig. 3a, b). The TEM studies of the CG alloy structure revealed a random distribution of the dislocations inside fine α-Ti grains. Some dislocations form the low-angle boundaries. The TEM studies have shown the grain boundaries in the CG alloy to contain the β-phase particles with increased concentration of Fe and V (Fig. 3c–f). The SEM studies have shown the β-phase particles to be located along the α’-phase platy grain boundaries mainly. The z-contrast (the atomic number contrast) analysis has shown the β-phase particles along the grain boundaries to have a different contrast as compared to the one of the α-Ti alloy crystal lattices (Fig. 3b). This observation proved also the β-phase particles to have an increased concentration of the doping elements.
The average grain size after N = 4 ECAP cycles was 0.2–0.5 μm (Fig. 4). The EDS analysis proved the variations in the local concentration of Al and V along different grain boundaries were insufficient. No precipitation of the β-phase particles along the grain boundaries was found in the UFG alloy.
The in situ TEM studies performed during the step-by-step heating demonstrated the recrystallization (the onset of the grain growth) during the annealing of the UFG alloy at 500 °C and above. Along with the onset of grain growth, the TiC nanoparticles with the average size of 5–15 nm were observed in the UFG alloy. Figure 5 shows the precipitation of the TiC particles marked by arrows.Footnote 1 After heating up to 700–800 °C, the average size of the TiC particles reached 30–50 nm and the average grain size in the UFG alloy was 7–9 µm (Fig. 6). The analysis of the results of the titanium alloy structure by in situ transmission electron microscopy has shown no significant differences in the average sizes and in the volume fractions of the TiC particles in the CG and UFG alloys.
The investigations of the mechanical properties proved the formation of the UFG structure in the Ti alloy by ECAP to improve the macroelastic limit σ0 from 400–420 MPa up to 730–750 MPa, the yield stress σy from 600–620 MPa to 1020–1050 MPa, and the microhardness limit Hv from 2.0–2.1 GPa up to 3.1–3.2 GPa, respectively. The investigations of the thermal stability of the mechanical properties demonstrated the softening of the UFG alloy to start after the heating up to 500–550 °C (Fig. 7) that corresponded to the recrystallization temperature. A slight increase in the macroelastic limit and yield stress of the Ti alloy at lower temperatures (T ≤ 450–500 °C) results from the precipitation of the TiC nanoparticles apparently.
The stress (σ)–strain (ε) dependencies for the CG and UFG alloys are presented in Fig. 8a, b, respectively. Figure 8c shows the dependencies of the flow stress σs and of the ultimate elongation to failure δ on the deformation temperature. The comparative analysis of the tensile mechanical tests at the elevated temperatures has shown the UFG alloy to be featured by a higher plasticity and lower flow stress at high temperatures. At the deformation temperatures increasing from 600 °C up to 800 °C, the flow stress in the CG alloy decreased from 355–360 MPa down to 125–130 MPa, while the plasticity δ increased from 230% up to 360% (at T = 700 °C). The results of testing the UFG alloy specimens in similar conditions demonstrated σs to decrease from 165 MPa down to 70 MPa, while δ increased from 190% up to 470–475% with increasing the deformation temperatures from 600 °C up to 800 °C (Fig. 8c).
Figure 9a shows the dependencies of the shrinkage on the heating time t L(t) for the CG and UFG alloys. Also, Fig. 9a shows the temperature curve during heating. Figure 9b presents the dependencies L(T) and S(T) while continuous heating of the CG and UFG alloys. The analysis of the L(T) dependencies revealed a monotonous increase in L during continuous heating, while the S(T) dependencies exhibited two stages with a maximum that is typical for the S(T) dependencies observed during sintering the UFG materials [44, 45]. One can see the shrinkage (the diffusion bonding) of the UFG specimens to start at lower temperatures than the one of the CG specimens in similar heating conditions. The degree of shrinkage for the UFG alloy was higher visibly than the one for the CG alloy.Footnote 2
The general results of the structural analysis support the observed effect of faster bondability in the UFG alloys. As shown in Fig. 10, there was practically no joint visible in the UFG-bonded specimens. The EBSD analysis helped to locate the joint correctly and to measure the joint width in the bonded specimens from the CG alloy. The TEM studies demonstrated the average size and the volume fraction of the pores to be much smaller in the UFG specimens than in the CG ones (Fig. 11). Note that SPS provides very thin joints (Fig. 11b) that ensure much higher operational reliability of the bonded structures. The analysis of the histograms in Fig. 11c, d showing the pore size distributions (corresponding to Fig. 11a, b) revealed the CG metal joint to have bigger pores with an average size of ≈ 1.5 µm, while the UFG one had the pores with the average size of 0.25–0.5 µm.
The studies of the mechanical properties demonstrated the hardness of the joints obtained by SPS at the temperatures below the recrystallization threshold to correspond to the hardness of the base metal measured on the base metal out of the joint at the distances of not less than three joint widths from the seam edge (Fig. 12).
Let us analyze the impact of the key factors (the temperature T, the pressure P, the heating rate Vh, and the holding time t) on the microstructure parameters of the bonded joints obtained by SPS during the high-speed bonding of the specimens made from the UFG Ti alloy. The dependencies of L, the shrinkage L and the shrinkage rate S, on the above parameters are shown in Fig. 13. Figure 13a shows the L(T) and S(T) dependencies (the latter can be also interpreted as the temperature dependence of the bonding rate) for the specimens made from the CG and UFG alloys. As one can see in Fig. 13a, within the range of T below the α ↔ β phase transition temperature, the maximum shrinkage Lmax and maximum shrinkage rate Smax in the UFG alloy were several times higher than Lmax and Smax in the specimens made from the CG alloy. Within the temperature range above 1000 °C (exceeding the temperature of α ↔ β phase transition), there was no visible difference between the values of Lmax and Smax for the CG and UFG alloys. Thus, one can conclude that at low T the bonding intensity in the UFG alloy was much higher than the one in the CG alloy. This was accompanied by a decrease in the typical scale of the diffusion mass transfer x, which is proportional to the grain size in the UFG metals: x = d/2, and therefore, by a decrease in the standard time of the diffusion mass transfer τdiff = δDb/x3 where δ is the grain boundary width and Db is the grain boundary diffusion coefficient. A small grain size in the UFG Ti alloy reduces τdiff and, hence, the time required for the diffusion-controlled dissolution of the pores located near the non-equilibrium grain boundaries drastically [44].
Figure 13b shows the Lmax(P) and Smax(P) dependencies. As one can see in Fig. 13b, the increase in P from 50 MPa up to 100 MPa resulted in the increase in Smax from 1.5 × 10−3 mm/s up to 5.8 × 10−3 mm/s for the CG alloy and from 1.6 × 10−3 mm/s up to 23 × 10−3 mm/s for the UFG alloy. We suppose the results of this study to evidence a significant role of the plastic deformation processes in the diffusion bonding of the CG and UFG Ti alloys (for more details, see "Discussion" section). This conclusion was supported also by a significant shrinkage of the specimens (Lmax = 1–8 mm) exceeding the surface roughness of the specimens after their mechanical polishing (< 40–60 µm).
The analysis of the Smax(Vh) and Lmax(Vh) dependencies presented in Fig. 13c has shown these dependencies for the CG alloy to be descending monotonously; Lmax decreased from 0.80 mm down to 0.01 mm, while Smax decreased from 4.0 × 10−2 mm/s down to 1.5 × 10−2 mm/s with increasing Vh from 10 °C/min up to 350 °C/min. This effect can be attributed obviously to the decrease in τdiff, within which the diffusion bonding of the specimens takes place, and consequently, to the decrease in the time required for the diffusion-controlled dissolution of pores in the joint.
The Smax(V) and Lmax(V) dependencies for the UFG alloy were more complex. As one can see in Fig. 13c, Lmax decreased from 2.14 mm down to 1.23 mm with increasing Vh from 10 °C/min up to 350 °C/min, while Smax changed with increasing Vh non-monotonously. When Vh increases from 10 up to 100 °C/min, Smax increased from 3 × 10−3 up to 1.6 × 10−2 mm/s. With further increase in Vh up to 350 °C/min, Smax decreased down to 8 × 10−3 mm/s. We suppose that this result can be explained as follows. When Vh grows, the size of the recrystallized grains d decreases, leading to the decrease in typical scale of the diffusion mass transfer x and, consequently, to the decrease in the time required to complete the metal sealing and the dissolution of pores in the joint. With further increase in Vh, the factor of reduced bonding time becomes crucial again and the sealing rate decreases. This conclusion was supported by the results of studying the porosity of the joints in the UFG alloys obtained using diffusion bonding at various temperatures and heating rates (Figs. 14, 15).
As it has been shown above (Fig. 12), during the high-rate low-temperature diffusion bonding of the UFG alloy, the joint hardness was rather high (3.2–3.3 GPa) and approached the joint hardness of the UFG alloy after ECAP (3.5–3.6 GPa). Besides, it exceeded the joint hardness achieved by the argon-arc bonding (2.35–2.40 GPa) or by electric fusion bonding (2.40–2.45 GPa). The microhardness of the bonded joints in the CG specimens was 2.4–2.6 GPa and was almost independent of the diffusion bonding modes.
It is noteworthy that the joint microhardness during bonding of the UFG alloy specimens at low temperatures (600–700 °C) was less than the one of the base metal away from the joint by 0.4–0.6 GPa. Thus, after the diffusion bonding of the UFG alloy at 600 °C (Vh = 100 °C/min, P = 50 MPa, t = 10 min), the joint microhardness was 2.7 GPa, while the microhardness of the base metal away from the joint was 3.0–3.1 GPa. Note also that with increasing T up to 800 °C, the joint microhardness decreased down to 2.5 GPa, while the metal microhardness away from the joint decreased down to 2.6–2.7 GPa. Thus, one can conclude the bonded metal obtained after bonding the UFG alloy to be featured by a lower hardness than the base metal away from the joint.
Similar results were obtained while studying the impact of Vh and P on Hv in the UFG alloy. The analysis of these results has shown Hv to increase slightly from 2.4 up to 2.6 GPa with increasing Vh from 50 to 350 °C/min (P = 50 MPa, t = 10 min), while Hv of the base metal away from the joint increased from 2.7–2.75 up to 2.9 GPa. The increase in P from 50 to 100 MPa (Vh = 100 °C/min, t = 10 min) resulted in a slight increase in Hv from 2.4 up to 2.5 GPa and to an increase in Hv in the metal away from the joint from 2.7–2.8 up to 3.0–3.1 GPa.
The values of Hv on the joints in the CG specimens were equal to the ones of the metal away from the joint at T ≤ 700 °C and S ≤ 50 °C/min, which was higher than the ones of the metal away from the joint by 0.1–0.15 GPa. We attribute the increased Hv of the joint in the CG alloy to the plastic deformation in the surface layers of the CG alloy and, consequently, the strain-induced hardening (work hardening) of this one. Since the defect structure recovery rate in the CG alloy during the high-rate heating is rather low, the hardened layer can survive during the low-temperature sintering.Footnote 3
The analysis of the joint grain structure parameters has shown the average grain size d in the bonded joint to be affected mostly by the bonding temperature T and by the heating rate Vh. As one can see in Fig. 16, the increase in T from 600 °C up to 800 °C (P = 50 MPa, Vh = 100 °C/min, t = 10 min) resulted in the increase in d in the UFG alloy joint from 3–3.8 µm (Fig. 16a) up to 5.9–6.9 µm (Fig. 16b). The increase in Vh from 10 °C/min up to 350 °C/min (P = 50 MPa, T = 700 °C, t = 10 min) resulted in the reduction in d in the UFG alloy joint from 6.8–7.0 µm down to ≈ 3.8 µm (Fig. 16c, d). The values of d in the bonded joints of the CG specimens corresponded to the ones in the CG alloy within the measurement uncertainty.
We have compared the d(T) dependencies (t = 10 min) to the ones for the CG and UFG alloys during the 30-min annealing [14] and found that during the diffusion bonding, the grain growth started at lower temperatures, while the intensity of the grain resizing during the diffusion bonding at the elevated temperatures appeared to be much lower (Fig. 17). At high T, this allows obtaining the homogeneous fine-grained structure with smaller grain size unlike ordinary annealing (Fig. 17). Note also that the same effect was observed in both CG and UFG alloys.
We suppose the obtained result to prove the recrystallization (the grain growth) mechanisms during the diffusion bonding to differ from the recrystallization mechanisms during annealing of the UFG alloy. The preserved equiaxial grain structure and weak grain growth may indicate that the recrystallization process during the diffusion bonding of the CG and UFG alloys, in the first approximation, can be presented as a competition of two processes:
-
1.
the formation of the submicron fragments (“recrystallization nuclei”) during the high-temperature plastic deformation, and
-
2.
fast migration of the fragment boundaries.
Let us analyze the corrosion resistance in the bonded joints obtained.
When comparing the potentiodynamic dependencies (Fig. 18) for the CG and UFG alloys after the diffusion bonding, we noted the values of icor for the joints from the UFG alloy to be lower than the one in the CG alloy joints obtained at similar values of T and Vh (Table 2). Note that at higher T, the differences in the corrosion resistances between the CG and UFG alloy joints increased. After bonding at 600, 700, and 800 °C, the values of the ratio of the icor values for the UFG alloy joints and the CG ones were 1.17, 1.84, and 1.97, respectively. Note that the icor(T) dependencies were manifested differently in the CG and UFG alloys (Table 2). The non-monotonous icor(T) dependence with the maximum at T ≈ 700 °C has been observed during bonding of the CG alloy specimens in the α-phase temperature range (Table 2). For the UFG alloy, icor decreased monotonously with increasing T in the α-phase temperature range. The corrosion potential for the UFG alloy was more negative (by 10–15 mV) as compared to the one for the CG one. Diffusion bonding in the β-phase area resulted in the formation of the martensite structure (Fig. 19) and reduced the corrosion resistance of the joints (Table 2).
The analysis of the potentiodynamic dependencies has shown the higher heating rates to result in a bigger corrosion resistance of the joints. The values of icor in the UFG alloy joints obtained at Vh = 50 °C/min were 1.32 mA/cm2, while at V = 350 °C/min icor ≈ 0.18 mA/cm2. The values of icor for the CG alloy joints obtained at Vh = 50 and 350 °C/min were 1.51 and 0.99 mA/cm2, respectively. Note that the icor(Vh) dependencies (bonding at T = 700 °C) were non-monotonous with the maxima at Vh ≈ 100 °C/min for the CG alloy and Vh ≈ 50 °C/min for the UFG ones.
The analysis of the dependence of the corrosion potential on the holding time t (Fig. 18b, see also Tables 2 and 3) has shown the steady potential for the UFG alloy joints to be somewhat less than the one for the CG ones that also confirms the increased corrosion resistance of the UFG alloy joints.
Thus, one can conclude the corrosion resistance of the UFG alloy joints to be higher than the one of the CG alloy joints.
Figure 20a and b shows the images of the surfaces of the CG and UFG alloy specimens, respectively, after the corrosion electrochemical investigations. As one can see in Fig. 20, rather active corrosion decay occurred in the joint during the electrochemical investigation. Also, it is evident from Fig. 20 that etching (corrosion decay) was observed during the testing at the grain boundaries of the Ti alloys. This suggests any changes observed in the corrosion properties to be primarily due to the processes occurring at the grain boundaries during the high-rate diffusion bonding.
We ascribe the increased corrosion resistance of the UFG alloy to the changes in the structural phase composition of the grain boundaries in the Ti alloy during ECAP (Fig. 4). As it has been mentioned above, ECAP performed at elevated temperatures (450–475 °C) resulted in reduced concentrations of the detrimental corrosive element (V) along the grain boundaries and in reduced differences in the concentrations of V (ΔCV) and Al (ΔCAl) in the crystal lattice Cv and at the grain boundaries Cb: ΔCV = Cv(V) − Cb(V), ΔCAl = Cv(Al) − Cb(Al). The differences in the concentrations of Al and V between the crystal lattice and at the grain boundaries in the CG Ti–5Al–2V alloy may reach ΔCAl = 5.6 at.% and ΔCV = 12.9 at.%, respectively. The studies of the grain boundary composition in the UFG alloy after ECAP revealed ΔCAl and ΔCV to be 0.35–0.40 at.% that exceeds slightly the range of the experimental uncertainty of determining the Al and V concentrations by EDS (± 0.2–0.3 at.% [14]).
While heating the UFG alloy to the temperatures exceeding the recrystallization threshold, fast migrating grain boundaries capture the atoms of the doping elements (Al and V) distributed in the crystal lattice uniformly that leads to the increase in ΔCAl and ΔCV again. In this case, the concentration of doping elements at the grain boundaries will obviously be proportionate to the typical distance over which the grain boundaries move and, consequently, to the size of the recrystallized grains. Thus, a decrease in the migration rate of the grain boundaries due to the increased S or decreased T was expected to boost the corrosion resistance of the Ti alloys. This effect was observed in the experiment indeed (see Table 3).
Discussion
Let us analyze the joint sealing parameters during the high-speed diffusion bonding of the CG and UFG Ti alloys. As mentioned above, L(T) and S(T) dependencies for the CG alloys are featured by two stages usually, while the L(T) and S(T) dependencies for the UFG alloys have more complex multistage character (Fig. 9b).
First, it is noteworthy that the temperature range T = 600–800 °C (that makes (0.44–0.56)Tm, where Tm = 1933 K is the α-Ti melting point) and the stress range (50–100 MPa that makes (1.1–2.3) × 10−3G, where G = 43.6 GPa is the shear modulus of α-Ti) of the diffusion bonding in the M.F. Ashby deformation mechanism maps [48] correspond to the exponential creep range (Stage III in the deformation mechanism maps). According to [48], the dependence of the strain rate (\( \dot{\varepsilon } \)) on applied pressure (σs) and the test temperature for Stage III can be described by the following equation: \( \dot{\varepsilon }_{1} = A_{\text{s}} D_{\text{eff}} \left( {Gb/kT} \right)\left( {\sigma_{\text{s}} /G} \right)^{n} \), where As is a numerical coefficient, Deff is the effective diffusion coefficient, b is the Burgers vector, and k is the Boltzmann constant. Based on mass empirical generalization, M.F. Ashby had shown [48] the exponential creep activation energy may correspond to the grain boundary diffusion activation energy Qb = 97 kJ/mol, Deff = δDb or to the bulk diffusion activation energy Qv = 242 kJ/mol, Deff = Dv subject to the grain sizes.
To identify the creep mechanism during the diffusion bonding of the Ti alloy specimens, the dependencies of the shrinkage L on the isothermic time t at 700 °C under different stresses (50, 70, and 100 MPa) were analyzed.Footnote 4 These L(t) dependencies for the CG and UFG specimens are presented in Fig. 21a, b. As one can see from these data, the stage of steady flow was observed in the L(t) dependencies for all alloys. Based on the assumption that at this stage the shrinkage is proportional to the deformation of the specimen, the usual procedure of plotting the lg(σs) − lg(\( \dot{L} \)) dependence can be used to estimate the index n, while the creep activation energy Qcr can be determined by the slope of the ln(\( \dot{L} \)) − Tm/T dependence.
This procedure revealed the index n determined from the slope of the lg(σs) − lg(\( \dot{L} \)) dependence for the CG alloy at 700 °C (approximately 0.51Tm) to be 5.6 ± 0.8 (Fig. 22a). This value exceeds the tabular value n = 4.3 published for α-Ti [46] slightly that can be related to the impact of the β-phase particles on the creep rate in the Ti alloy leading to significant increase in n [49, 50]. The analysis of the L(t) dependencies for different temperatures (600 °C, 700 °C, and 800 °C) under a constant pressure (P = 50 MPa) revealed the value of Qcr for the CG Ti alloy to be ≈ 14.9 kTm (≈ 240 kJ/mol, Fig. 22b) that appears to be close to the activation energy of the exponential creep, the rate of which is limited by the α-Ti lattice diffusion intensity [48].
Similar analysis of the L(t) dependencies under different stresses (50, 70, and 100 MPa) at different temperatures (600, 700, and 800 °C) has shown the values of Qcr in the UFG alloy during the isothermic holding to be ≈ 6.2 kTm (≈ 100 kJ/mol, Fig. 22b). This value of Qcr is close to the grain boundary diffusion activation energy Qb and to the lattice dislocation nuclei activation energy Qc in α-Ti (Qb = Qc = 97 kJ/mol [48]). The index n determined from the slope of the lg(σs) − lg(\( \dot{L} \)) dependence for the UFG alloy was 2.1 − 2.7 (Fig. 22a). The values of Qcr are in good agreement with the literature data on the creep flow in the UFG Ti and Ti alloys [51, 52]. On the other hand, the values of n and Qcr obtained for the UFG Ti alloy are in good agreement with the values for the exponential creep, the rate of which is limited by gliding and climb (creep) of dislocations [48].
When studying the thermal stability of the UFG alloy, the nanoparticles of the second phase (presumably TiC) were found to precipitate. These ones were expected to hinder the movement of the lattice dislocations and to increase the index n in the exponential creep equation. According to the results of the above analysis, the values of the index n in the UFG alloy appear to be lower than the theoretical value nth = 3 for the exponential creep mechanism [48], below n = 4.3 typical for the CG Ti [48], and much below the values of n observed in the UFG Ti [53, 54].
Note that some authors [53, 54] attributed the low values of the n observed in the UFG metals and low values of Qcr comparable to the grain boundary diffusion activation energy Qb to the superposition of several mechanisms of plastic deformation with low and high values of n during the creep tests. In the case of the plastic deformation of the UFG alloys at relatively low temperatures, the Coble creep (\( \dot{\varepsilon }_{2} = B_{\text{s}} \left( {\delta D_{\text{b}} /d^{3} } \right)\left( {_{\text{s}} b^{3} /kT} \right) \) [55]) or the grain boundary sliding (\( \dot{\varepsilon }_{3} = A_{\text{b}} \left( {\delta D_{\text{b}} /kT} \right)\left( {b/d} \right)^{2} \left( {/G} \right)^{2} \) [56, 57], where Bs and Ab are the numerical coefficients, δ = 2b may occur.
The analysis of the results of the mechanical tensile tests performed at elevated temperatures allows determining the strain rate sensitivity coefficient m from the slope of the dependencies of the flow stress σs on the deformation rate \( \dot{\varepsilon } \) in the logarithmic axes m = ∂ln(σ*)/∂ln(\( \dot{\varepsilon } \)). The analysis of the σs (\( \dot{\varepsilon } \)) dependencies presented in Fig. 23 has shown m in the CG titanium alloy at T = 700 °C to be 0.24–0.28, while in the UFG alloy m = 0.50–0.56. High values of m in the UFG alloy evidence a significant contribution of the grain boundary sliding mechanism into the total elongation of the UFG alloy specimens during the deformation at elevated temperatures.
Thus, one can assume two simultaneous processes to take place during the isothermic joint sealing in the UFG Ti alloy:
-
1.
the exponential creep associated with the gliding and climb of dislocations, the activation energy of which corresponds to the diffusion activation energy in the lattice dislocation nuclei, and
-
2.
the grain boundary sliding or Coble creep, the activation energy of which corresponds to the grain boundary diffusion activation energy.
Let us analyze the joint sealing patterns in the CG and UFG alloys during continuous heating.
The analysis of the dominant diffusion mechanisms observed at early sintering stages during continuous heating can be carried out using the Young–Cutler model [58] for the non-isothermic sintering modes. According to this model, the effective sintering activation energy in the continuous heating conditions mQs where m is a numerical coefficient (m = 1.2 in the case of the diffusion in the bulk crystal lattice and m = 1/3 in the case of the grain boundary diffusion) [58,59,60] can be determined from the slope of the ln(Tdε/dT) − Tm/T dependence [58], where ε = L/L0.
Figure 24 shows the L(T) dependencies for the CG and UFG alloys in the ln(Tdε/dT) − Tm/T axes. The analysis of the obtained results has shown that the above dependencies can be approximated by a straight line with a reasonable degree of accuracy. The values of mQs for the CG joint sealing did not depend on S within the experimental uncertainty and equals to (8.2–9.3)kTm. If m = 1/2, the CG alloy sealing activation energy during the continuous heating makes (16.4–18.6)kTm (265–298 kJ/mol), which is rather close to the exponential creep activation energy in α-Ti limited by gliding and climb of dislocations (Qcr = 242 kJ/mol [48]).
The values of mQs in the UFG Ti alloy appeared to depend on S: mQs decreased from (4.1 ± 0.3)kTm down to (2.2 ± 0.5)kTm with increasing S from 10 to 100 °C/min. Further increase in S up to 350 °C/min resulted in a slight increase in mQs up to (3.2 ± 0.4)kTm. If m = 1/3, the values of Qs (6.6–12.3)kTm = 106–197 kJ/mol are close to the ones for the grain boundary diffusion in pure α-Ti (Qb = 97 kJ/mol) and to the recrystallization activation energy in the UFG alloy ≈ 6.7kTm ≈ 108 kJ/mol [61]. Higher activation energy values (106–197 kJ/mol) in the UFG alloy Ti–5Al–2V were ascribed to the impact of the doping elements on the diffusion permeability of the grain boundaries in the UFG Ti alloy. As has been shown above (Fig. 4c), the grain boundaries in the UFG Ti alloy contain an enhanced concentration of Al and V (see also [14, 61]).
Note that the non-monotonous character of the dependence of the joint sealing activation energy in the UFG alloy corresponds to the non-monotonous S(Vh) dependence. This fact can be considered as an indirect proof of the analytical method chosen to be correct.
Thus, one can conclude that the high rates of the diffusion bonding of the UFG Ti alloy result from the small grain sizes that reduces typical scale of the diffusion mass transfer significantly as well as from the change in the diffusion mechanism: The diffusion in the crystal lattice is replaced by the diffusion along the grain boundaries, the latter being much more intensive than the former. This allows using the SPS technology for making the high-density fine-grained structure in the joint featured by high density and corrosion resistance.
Conclusions
-
1.
SPS is shown to allow efficient high-speed diffusion bonding of α-Ti alloys and, at the same time, to preserve the UFG structure, high hardness, and corrosion resistance in the joint. The pores in the UFG alloy joints were found to diffuse faster due to highly intensive diffusion processes taking place along the non-equilibrium grain boundaries and the small-scale diffusion mass transfer, typical scale of which is proportional to the grain size.
-
2.
The dependence of the joint sealing rate (bonding rate) on the heating rate was shown to be different for the CG and UFG alloys. An increase in the heating rate in the CG alloys leads to a monotonous decrease in the sealing rate caused by the reduced bonding time at high heating rates. The joint sealing rate in the UFG alloys depended on the heating rate non-monotonously (with a maximum) that was attributed to the decrease in the recrystallized grain size with increasing heating rate leading to the decrease in the typical scale of diffusion mass transfer and, consequently, to the decrease in the standard time required to complete the metal sealing and to the dissolution of the pores in the joint. The factor of the reducing the bonding time becomes crucial again with increasing heating rate, and the sealing rate decreases.
-
3.
At the stage of the continuous heating, the kinetics of the joint sealing in the CG and UFG Ti–5Al–2V alloys can be described by the Young–Cutler model. The joint sealing activation energy in the CG Ti alloy during the continuous heating was close to the exponential creep activation energy in α-Ti limited by gliding and climb of dislocations. The joint sealing activation energy during the diffusion bonding of the UFG alloy was close to the grain boundary diffusion activation energy.
-
4.
At the stage of isothermic holding, the kinetics of the joint sealing in the Ti alloys is limited by the exponential creep processes, the rate of which in the CG Ti alloy is determined by the intensity of diffusion in α-Ti crystal lattice. In the UFG alloy, the exponential creep processes associated with gliding and climb of dislocations, the activation energy of which corresponds to the diffusion activation energy in the lattice dislocation nuclei, may take place simultaneously with the grain boundary sliding and Coble creep, the activation energy of which corresponds to the grain boundary diffusion activation energy.
Notes
In our opinion, the origin of the forming of the TiC nanoparticles is the presence of carbon in the titanium alloy (see Table 1), the concentration of which does not exceed the permissible value but appears to be enough for forming the TiC particles.
The differences in the initial shrinkage level result from the ≈ 0.02 mm difference in the specimen heights.
Since the average grain size in the weld in the UFG alloys was almost the same to the one of the metals outside the weld (Fig. 14), the origin of the reduced weld microhardness in the UFG alloys is still unclear. We think the reduced weld microhardness in the UFG alloys to be related most probably to the grain boundary recovery leading to the reduced density of defects in the UFG alloy grain boundaries. The second probable origin of the increased microhardness of the weld-affected zone in the CG alloys may be the creep (as discussed in more detail below), which is known to be accompanied by the formation of the dislocation substructures and low-angle boundaries [46, 47]. This hypothesis was confirmed by the results of EBSD analysis of the welds for the CG materials (Fig. 10a), in which the low-angle boundaries with the grain boundary angle of less than 2° were observed outside the weld predominantly (Fig. 10b).
The weld specimen was heated at the same rate (100 °С/min) up to 700 °С and then was held at this temperature for 10 min under different values of the uniaxial pressure σs = 50, 70, and 100 MPa (Fig. 21).
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Acknowledgements
This study was performed with the support of the Russian Science Foundation (Grant No. 16-13-00066). The authors thank A.V. Piskunov and N.V. Sakharov (Lobachevsky Univ.) for developing the methods of EBSD analysis of the titanium alloy joints. The authors thank E.A. Lantsev (Lobachevsky Univ.) for conducting the tests in order to measure the temperature–shrinkage dependencies L0(T) without a specimen using Dr. Sinter® SPS-625 setup in different heating modes. The authors thank Afrikantov OKB Mechanical Engineering JSC for performing the argon-arc and electron-beam welding of the UFG alloy specimens.
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Chuvil’deev, V.N., Nokhrin, A.V., Kopylov, V.I. et al. Spark plasma sintering for high-speed diffusion bonding of the ultrafine-grained near-α Ti–5Al–2V alloy with high strength and corrosion resistance for nuclear engineering. J Mater Sci 54, 14926–14949 (2019). https://doi.org/10.1007/s10853-019-03926-6
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DOI: https://doi.org/10.1007/s10853-019-03926-6