Abstract
The reversion of deformation-induced α′-martensite in tension-deformed 1.4301 (EN) stainless steel was investigated using positron annihilation spectroscopy. The Doppler broadening of the annihilation line and positron lifetime spectroscopy were applied to study defect structure and its annealing behavior in samples with a similar deformation level but varying in α′-martensite amount. The difference in α′-martensite was obtained by applying different deformation temperatures, i.e., liquid nitrogen temperature, room temperature, and 200 °C. The cumulative annealing of the tension-deformed samples and measurement of the positron annihilation characteristics show the gradual annealing of defects in the temperature range between 200 and 400 °C due to the recovery and recrystallization. However, in the temperature range between 450 and 650 °C, the generation of vacancy clusters which trap positrons is revealed. This temperature range coincides with the temperature range of α′-martensite reversion which is confirmed by microhardness and magnetization measurements. The detected large vacancy clusters consisting of 6–9 vacancies can occur at the interface between austenite and α′-martensite phases due to the volume contraction accompanying bcc/fcc change.
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Introduction
Martensitic transformation induced by plastic deformation of metastable austenitic stainless steel (SS) is a well-known phenomenon [1, 2] depending on steel composition and deformation conditions, e.g., temperature, strain rate, and state. Deformation-induced martensite (DIM) changes important properties of steel, e.g., the strain-hardening coefficient and formability. During plastic deformation (briefly, deformation) of metastable austenitic SS, ε-martensite with hexagonal close-packed crystal structure and α′-martensite with body-centered cubic crystal structure can be formed. Whereas austenite (γ phase) and ε-martensite are paramagnetic, α′-martensite is ferromagnetic. Then changes in magnetic properties of SS due to the formation of α′-martensite can be used for its detection [3–5]. It was found that in a low deformation range more ε-martensite than the α′-martensite is formed [6]. The amount of α′-martensite significantly grows with deformation and following transformation sequences γ → ε → α′ and γ → α′ have been reported [7, 8]. The former is typical for steels with low stacking fault energy (SFE), the latter for steels for somewhat higher SFE [9]. In addition to the plastic strain, strain rate and the SFE of material related to the material chemistry and temperature, the DIM amount also depends on grain size and orientation [10–13].
Metastable austenitic SS is strengthened by dislocation structure and DIM formation during cold working [14]. In some cases, DIM can also have unfavorable effects such as the delayed cracking phenomenon of deep-drawn austenitic SS components [15]. Also the change of magnetic properties related to martensitic transformation is not acceptable for some applications [16]. Therefore, martensitic transformation in metastable austenitic SSs has been extensively studied mainly for practical reasons [17–19]. On the other hand, details of the DIM transformations during aging of the deformed metastable austenitic SS are less known. The aging can lead to additional formation of α′-martensite [20] and to reverse transformation of DIM, i.e., α′ → γ. The reversion of ε and α′-martensite occurs in temperature ranges 150–400 and 400–850 °C, respectively [4, 21–23]. However, there have been reports that reversion α′ → γ occurs at 500–600 °C and at about 570–850 °C [9]. A crystallographic and kinetic basis for the thermal reversibility of the martensitic transformations comes from the thermoelastic behavior of martensites described by Kurdyumov and Khandros [24]. The reverse transformation results in formation of austenite with high dislocation density [25], micro-twins, and stacking faults [26, 27]. Inducing martensitic transformation in metastable martensitic SS and then reverting the martensite to austenite through aging has been found to be a workable option for grain refinement in order to increase yield strength without impairing ductility of the material [28, 29].
A variety of experimental methods have been applied to study both martensitic transformation and DIM reversion in SSs, e.g., microscopic methods, X-ray diffraction, magnetic or mechanical properties measurements. Positron annihilation spectroscopy (PAS) is used for SS studies as well; however, no studies of DIM reversion have been performed. The PAS techniques are well-known experimental methods used for the study of defects in crystalline matter [30]. Positrons (antimatter particles) implanted into a metallic system annihilate with electrons emitting gamma ray photons. These photons contain useful information on the electron momentum distribution in the sites where the annihilation takes place. As the distribution is different for perfect crystal lattice and lattice defects this is reflected in the Doppler broadening (DB) of the positron annihilation line characterized by the line shape parameters such as the S-parameter. The positron lifetime, i.e., the time between emission of positrons from a radioactive source and detection of annihilation photons depends on electron density. It is higher for positrons trapped in open volume defects i.e., vacancies, vacancy agglomerates and dislocations than for positrons in a perfect crystal lattice. PAS can be used for identification and tracking of changes of crystal lattice defects, i.e., their generation during deformation or their annealing. These techniques have been successfully used for non-destructive evaluation of fatigue damage in SSs [31–33] and detection of the subsurface zone defects created by sliding, cutting [34, 35], or shot peening [36]. PAS was applied to determine vacancy migration energy in SS [37, 38]. Sensitivity of PAS is sufficient for investigation of the phase transformations in different materials [39, 40], and this technique has been profitably applied in microstructural characterization of steels which are candidates for structural materials in nuclear facilities [41, 42].
Our preliminary experiments have shown that reverse transformation of DIM in metastable austenitic SSs can be investigated using DB of the annihilation line. PAS measurements have revealed two processes which take place during annealing of deformed SS containing DIM, i.e., migration and sinking of vacancies and creation of additional lattice defects accompanying α′-martensite reversion to austenite [43, 44]. The aim of the study was application of this technique to investigation of annealing behavior of SS 1.4301 (EN) deformed in tension at different temperatures. Different deformation temperatures allowed us to obtain different amount of α′-martensite for the samples with similar level of deformation. Samples were also investigated using XRD, and their microhardness and magnetic properties were measured.
Experimental details
Sample preparation
The steel studied was Polish commercial SS 1.4307 (EN) which is equivalent to AISI Grade 304 SS. The specimens of dimensions 15 × 3 × 100 mm3 were cut from a flat bar and subjected to solution annealing at 1100 °C for 30 min followed by quenching in air. After heat treatment, surface of the samples was etched using hydrochloric acid and nitric acid water solution. The chemical composition of the steel was determined using a glow discharge atomic emission spectrometer LECO GDS 850A. Carbon content was measured by an infrared absorption after combustion in an induction furnace using LECO CS600 analyzer, and nitrogen content was determined using LECO TCH 660 analyzer. Table 1 shows the chemical composition of the steel studied.
The plastic deformation was performed in uniaxial tension using the MTS-810 testing machine at three different temperatures, i.e., liquid nitrogen (LN2) temperature, room temperature (RT), and 200 °C to obtain three samples with similar level of strain i.e., A (ε = 5 %), B (ε = 6 %), and C (ε = 9 %) and different amounts of deformation-induced α′-martensite. For comparison, the forth sample was deformed to much higher strain D (ε = 32 %) at RT. The deformation conditions are given in Table 2. Three specimens of length of 15 mm were cut from adjacent places of the deformed samples (the gage length was 80 mm). Two of them were used for positron annihilation measurements, i.e., DB of the annihilation line and the positron lifetime. The third was used for measurements of microhardness and the relative change in magnetization. The samples were subjected to cumulative isochronal annealing in the flow of N2 gas for 1 h at temperatures range from 50 to 800 °C with temperature step of 25 °C. After 1 h-annealing at a given temperature, the samples were etched in order to remove the oxidized surface layer, and the positron annihilation, magnetization change, and microhardness were measured.
Magnetic properties measurements
Magnetic properties of the samples were characterized by two methods. Response of the deformed samples to magnetic field was determined using the MPMS SQUID magnetometer. Magnetization curves up to 10 kOe were measured at room temperature for additional samples of dimensions ca. 2 × 2 × 3 mm3 cut using the low speed diamond wheel saw and etched to remove the layer deformed by cutting. The volume fraction of α′-martensite f α′ induced by plastic deformation was calculated by the formula proposed by Mangonon and Thomas: f α′ = σ s/160.4, where σ s is specific saturation magnetization per unit mass [2]. Relative changes in magnetization induced by annealing of the deformed samples were determined by other measurements according to the method described by Davis [45, 46]. The magnetization measured by the magnetic balance is given in arbitrary units. The amount of the α′-martensite is related to its amount initially present in the as-deformed samples. In these measurements, the maximum magnetic induction used was equal to 20 mT.
XRD and microhardness measurements
The X-ray diffraction measurements were carried out using a Philips X-Pert diffractometer using CuK α radiation. The microhardness was measured with the Vickers indenter under 100 gram (HV0.1) using a Zeiss-Neophot 30 microscope.
PAS measurements
For the positron annihilation measurements, the 22Na isotope positron source enveloped in a 7-μm-thick kapton foil was used. The applied Doppler broadening (DB) spectrometer with a coaxial high purity germanium (HPGe) detector (produced in Institute of Nuclear Physics PAN) had the energy resolution equal to 1.4 keV—the full width at half maximum (FWHM) interpolated at 511 keV. Other components of the spectrometer were produced by ORTEC. As a result, the dependence of the so-called S-parameter defined as the ratio of the area under the fixed central part of the annihilation line to the area under the whole annihilation line was determined. The S-parameter is sensitive to annihilation of positrons with low momentum electrons which are present in open volume defects. The positron lifetime spectra of more than 1.5 × 106 counts were measured using a fast–fast spectrometer with BaF2 scintillators, Photonis XP2020Q photomultipliers, and other electronic components made by ORTEC. The time resolution of the spectrometer was equal to 280 ps (FWHM). All the obtained spectra were analyzed using the LT-code after subtracting contribution of the positron source and background [47]. Doppler broadening of the annihilation line was measured after each annealing. The positron lifetime measurements were performed for the as-deformed samples and the samples annealed at selected temperatures.
Results
XRD measurements
X-ray diffraction patterns for the sample after solution annealing and the as-deformed samples are depicted in Fig. 1. For all the samples, the peaks of γ and α′ phases are present. It is visible that the solution annealing and quenching in air did not produce fully austenitic microstructure. Change in relative intensity of picks for both phases clearly shows that amount of α′-martensite significantly decreases with increasing deformation temperature for the low deformation range (sample sequence A, B, C). For the sample A (ε = 5 %) deformed at LN2 temperature α′-martensite phase dominates. This confirms the results obtained by Herrera et al. who found that amount of the α′-martensite in 304L SS increases both with deformation level and the temperature lowering from 200 °C to RT and to −196 °C, and martensite is not detected in the steel deformed in tension at 200 °C [13]. Significantly lower ratio of α′ (110) to γ (111) reflection intensities for the specimen D (ε = 32 %) deformed at RT in comparison to that for the specimen A (ε = 5 %) deformed at LN2 temperature can be related to the crystallographic texture. Differences in texture can be evaluated by comparing intensity ratios of the austenite reflections. For the sample D (ε = 32 %), the ratio of γ (111) to γ (200) reflection intensities is equal to 3.3, while for the remaining deformed samples, it is equal to 2.9–3. For the material without texture it is ca. 2. It is known that crystallographic texture can falsify results of the X-ray phase analysis [48, 49]. Therefore, the magnetic measurements were preformed to obtain the α′-martensite amount.
Magnetization measurements
Figure 2 shows the room temperature magnetization curves, and Table 2 presents values of the specific saturation magnetization per unit mass σ s and volume fraction of α′-martensite f α′ for the as-deformed samples. The highest amount of α′-martensite, i.e., 0.25 was obtained for the sample A (ε = 5 %) deformed at LN2 temperature.
Figure 3 presents the summary of the results obtained using different measurement methods. The relative changes of magnetization as a function of annealing temperature are shown in Fig. 3a. The right axis shows the corresponding values of volume fraction of α′-martensite f α′. The values of magnetization are normalized to the initial magnetization for the as-deformed sample A (ε = 5 %). Up to c.a. 400 °C, the magnetization does not change significantly with temperature. Then. it decreases, which results from the reversion of deformation-induced α′-martensite and for the samples deformed at RT or at 200 °C, i.e., B (ε = 6 %), C (ε = 9 %), and D (ε = 32 %), it reaches the value close to zero at 700 °C. For the sample A (ε = 5 %), the magnetization remains higher than for other samples even after annealing at 800 °C, indicating that the reversion is not complete in this case. From Fig. 3a, it is possible to determine the 50 % reversion temperature T50%RM. For the samples A (ε = 5 %) and D (ε = 32 %), it is close to 590 ± 10 °C. The changes of the α′-martensite amount will be connected to the results obtained using other measurement methods.
Vickers microhardness measurement
The results of Vickers microhardness measurements as a function of annealing temperature are shown in Fig. 3b. The initial value of microhardness is the highest (i.e., 370 HV) for the sample D (ε = 32 %). For the sample A (ε = 5 %), it is slightly lower (i.e., 290 HV). For the samples B (ε = 6 %) and C (ε = 9 %), the initial microhardness values are very close (i.e., 225 HV and 215 HV) as are the magnetization values. The microhardness values do not change significantly up to the annealing temperature of 450 °C. They start decreasing at 500 °C and for the samples with the low level of deformation they reach the value c.a. 150 HV independently of the initial α′-martensite fraction. The sample D (ε = 32 %) has higher final value of the Vickers microhardness (i.e., 190 HV), but the α′-martensite amount after annealing for this sample is close to zero as it is for the samples B (ε = 6 %) and C (ε = 9 %). Softening of the material coincides with the α′-martensite reversion in particular for samples with higher amount of α′-martensite. Further softening may be connected with recovery and recrystallization of the γ-phase retained regions. Recrystallization of the austenitic SSs occurs at temperatures about 100 °C higher than the martensite reversion temperature [22]. The microhardness dependence correlates with magnetization changes shown in Fig. 3a.
Doppler broadening and positron lifetime measurements
Figure 3c presents the results of DB measurements for isochronal annealing of the samples, i.e., the S-parameter dependence on the annealing temperature. The highest initial value of the S-parameter for the sample D (ε = 32 %) indicates the highest defect concentration, and the lowest value of the S-parameter for the sample A (ε = 5 %) indicates the lowest defect concentration. Thus, for these two samples the S-parameter behavior differs from the microhardness behavior, which indicates that the two measurement methods provide information on different microstructure-related properties. The values of the S-parameter for the samples B (ε = 6 %) and C (ε = 9 %) do not differ within the experimental accuracy. Annealing up to 175 °C does not change the S-parameter values or causes only small decrease as it is for the sample D (ε = 32 %). Decrease of the S-parameter with temperature starting at 200 °C indicates decrease of concentration of positron trapping defects. This type of behavior may be described, for example, by vacancy migration model, in which annealing of the deformed sample causes diffusion of vacancies to grain boundaries or other sinks where they annihilate [37]. The smooth solid lines in Fig. 3c are fitted to the experimental points using this model. They follow the experimental points up to the annealing temperature of 375 °C. Above this temperature, the S-parameter values are higher than those indicated by the model even for the samples with the low initial α′-martensite fraction, i.e., B (ε = 6 %) and C (ε = 9 %). For these samples, the S-parameter decrease becomes less steep. For the samples A (ε = 5 %) deformed at LN2 temperature and D (ε = 32 %) deformed at RT with the α′-martensite volume fractions 0.25 and 0.19, behavior of the S-parameter is different. The S-parameter increases and exhibits distinctly higher values in the temperature range between 450 and 650 °C. For higher annealing temperatures, the S-parameter decreases and follows the values obtained for two other samples. The values of the vacancy migration energies obtained from the model for four samples studied, i.e., 0.51–0.54 eV, are relatively low in comparison to, e.g., 0.9 eV obtained by Holzwarth et al. for 316L SS for which deformation did not induce α′-martensite [38]. This confirms that the vacancy migration model does not describe well the S-parameter dependencies obtained for austenitic SS containing DIM because new defects are created during martensite reversion. Comparison of Fig. 3a, c shows that the region of elevated values of the S-parameter for the samples A (ε = 5 %) and D (ε = 32 %) coincides with the region of the magnetization decrease. This confirms that the increase of the S-parameter for the samples with higher amount of α′-martensite is caused by generation of crystal lattice open volume defects accompanying DIM reversion. The dashed line in Fig. 3c indicates the value of the S-parameter for the sample after the solution annealing. This value is higher than those for the samples at the end of the annealing procedure because the applied solution annealing and cooling in air did not remove all crystal lattice defects which localize positrons.
In order to specify the types of defects, the positron lifetime spectra were measured for the as-deformed samples and after annealing in a few selected temperatures. Only single positron lifetime was resolved in the spectra and it is treated as the mean positron lifetime. The mean positron lifetime versus annealing temperature is depicted in the insert in Fig. 3c. Difficulties in separation of lifetime components may be caused by competitive trapping of positrons in a family of defects giving lifetimes to close be isolated. For the as-deformed samples, the mean positron lifetimes are significantly higher than the bulk positron lifetime for α-Fe, i.e., 108 ps [34]. However, they are lower than the lifetime of positron trapped in vacancies in α-Fe, i.e., 175 ps [50]. It is worth noticing that monovacancies induced in iron, for example, by electron irradiation migrate already at temperatures as low as 200 K [50]. The theoretical calculations of positron lifetimes for the fcc structure of Fe atoms give the values lower than that observed for α-Fe, i.e., 99 ps for positron lifetime in bulk and 167 ps for monovacancy [51]. But the presence of carbon atoms in the vicinity of monovacancy causes increase of the positron lifetime [51]. The obtained positron lifetimes can be compared to those observed in deformed iron and assigned to annihilation of positrons in dislocation-associated defects. They were found being close to 150 ps [52], though the values of 142 and 165 ps were also reported [53]. It is commonly accepted that dislocation lines are shallow traps for positron. However, a positron diffusing along a dislocation core may be localized in deeper traps associated with the dislocation like jogs or vacancies bound in the strain field of the dislocation. Annihilation of positrons localized in such traps gives the lifetime lower than that characteristic for monovacancy. The presence of the alloying elements in steel may also influence positron lifetimes. The lifetimes calculated for vacancy-solute complexes for steel alloying elements (e.g., V–Cr or V–Cu), i.e., 152–154 ps are also lower than that for monovacancy in α Fe [54].
The values of the mean positron lifetime higher than those for dislocation-associated defects may suggest that there is some contribution from positron annihilation in small vacancy clusters. For the samples after annealing at 350 °C, the mean positron lifetime decreases, which is caused by annealing of defects. For the samples A (ε = 5 %) and D (ε = 32 %) after annealing at 575 °C, the mean positron lifetime increases as does the S-parameter. As expected, the changes of the mean positron lifetime follow the changes of the S-parameter, and the values of the mean positron lifetime after completing of the annealing procedure are close to the bulk value for α-Fe.
For the sample A (ε = 5 %) deformed at LN2 temperature, two components in the positron lifetime spectra measured after annealing at 575 °C and additionally at 625 °C can be resolved. For the temperature of 575 °C they are as follows: τ 1 = (128 ± 3) ps with intensity I 1 = (93 ± 1) % and τ 2 = (319 ± 26) ps with intensity I 2 = (7 ± 1) %; and for the temperature of 625 °C they are: τ 1 = (123 ± 3) ps with intensity I 1 = (91 ± 2) % and τ 2 = (275 ± 24) ps with intensity I 2 = (9 ± 2) %. Such values of positron lifetime in α-Fe can be assigned to positrons annihilating in clusters of 6–9 vacancies according to calculations performed by Puska and Nieminen [55]. Further annealing causes disappearance of these vacancy clusters.
Discussion
Mechanical properties of deformed austenitic SS depend strongly on the amount of DIM. Mangomon and Thomas found that yield strength of 304 SS after different mechanical and thermo-mechanical treatment is linearly proportional to the amount of α′-martensite [56]. Takanishi and Shitani showed that the hardness of cold rolled 304 SS is proportional to α′-martensite amount [57]. They also found that the dislocation density in the α′ phase is close to saturated value even for low strain and increases only scarcely with strain whereas the dislocation density in austenite increases significantly with increasing strain and then saturates. Taking into account only the α′-martensite amount, the microhardness for the as-deformed sample A (ε = 5 %) should be higher than that for the sample D (ε = 32 %) by virtue of the higher amount of α′-martensite. This indicates that for the sample D (ε = 32 %), the significant contribution to microhardness comes from dislocation density in austenite grains, which is confirmed by the higher values of the S-parameter and the mean positron lifetime caused mainly by annihilation of positron trapped in dislocation-associated defects.
Mechanisms of reversion from deformation-induced martensite to austenite depend on the chemical composition of steel and annealing conditions. According to Tomimura et al. who studied the reversion mechanisms in cold rolled 304 steel, in order to obtain the critical driving force for martensitic shear reversion in 18Cr–9Ni steel, the steel should be heated to a temperature above 750 °C [58]. However, the diffusional reversion can easily occur at lower temperatures. Diffusional reversion mechanism is characterized by random nucleation of the austenite grains inside the martensite laths and equiaxed growth. The grain growth leads to increase in the austenite amount, and most of the grains are bounded by large angle boundaries. If the reversion is not complete, remained tempered martensite grains are present within austenite grains. Since the annealing of our samples started at low temperatures, the diffusional mechanism of martensite reversion should be taken into account. Then, the vacancy clusters which were detected by positron lifetime measurements can be the result of volume contraction accompanying bcc/fcc change, and they can form at martensite–austenite interfaces in the course of the transformation. The value of the first lifetime component higher than the bulk value for α-Fe indicates that other defects such as dislocations and dislocation-associated defects are also present in the sample.
There is a difference in the behavior of the samples A (ε = 5 %) and D (ε = 32 %). The lifetime component coming from annihilation in vacancy clusters is distinctive for the sample A (ε = 5 %) deformed at LN2 temperature with initial f α′ = 0.25. In spite of a similar behavior of the S-parameter in the temperature range between 450 and 650 °C, the mean positron lifetime measured at 575 °C for the sample D (ε = 32 %) deformed at RT with initial f α′ = 0.19 is slightly lower than that for the sample A (ε = 5 %). The analysis of this positron lifetime spectrum with the value of the second component fixed at 300 ps gives its intensity lower than 3 %. Then, the vacancy clusters if present in the sample D (ε = 32 %) are smaller and/or have lower concentration than for the sample A (ε = 5 %). This may be caused by a lower initial fraction of martensite or the influence of higher initial concentration of dislocations on vacancy cluster formation.
There should be considered also another phenomenon in SSs which can cause an increase of the S-parameter or mean positron lifetime, i.e., precipitation of carbides [37]. Several studies reported the increase of the S-parameter or mean positron lifetime values in ferritic/martensitic steels which could be attributed to the nucleation and growth of metal carbide precipitates mainly M23C6 at temperatures above 500 °C. In that case, the positron trapping sites were expected to be precipitate matrix interfaces [42]. The subsequent decrease of these parameters with a minimum at 800 °C was explained as caused by coarsening of the precipitates and decrease of positron trapping. Other authors studied cold worked Ti-modified D9 (15Ni–15Cr) austenitic SS and observed increase of the S-parameter or mean positron lifetime for the temperatures higher than 530 °C which they attributed to positron trapping at precipitate–matrix interfaces of TiC precipitates in austenitic matrix [59–61]. The increase was not observed for the Ti-free FeCrNi model alloy. However, DIM was not considered in those studies.
Chromium carbide precipitation in 304 stainless steels is governed by the thermodynamics of carbon concentration and kinetics of chromium diffusion. The increasing carbon content decreases the sensitization time. This phenomenon involves development of carbide precipitates (Cr23C6) in the grain boundary region in the temperature range from 480 to 850 °C resulting in chromium depletion near the grain boundary; as a result, grain boundary region is prone to preferential intergranular corrosion [62–64]. The SS studied in our case has relatively low content of carbon, i.e., 0.023 wt% and the total annealing time for temperatures between 450 and 650 °C was 11 h. For 304 SS with similar carbon content aged for 50 h at 670 °C, Trillo and Murr found that a few small carbides precipitations were nucleated on high-angle grain boundaries [65]. However, not only carbon content but also factors connected to chromium diffusion such as strain and strain state influence chromium carbide precipitation [66]. It is known that cold working promotes the formation of both the carbides and intermetallic phases and deformation reduces the time required for sensitization [66–68]. The effect is more pronounced in the α′-martensite containing 304 SS than in the type 316 SS, especially at temperatures below 600 °C [62].
In the light of all this, the influence of chromium carbon precipitates on the observed increase of the S-parameter in our experiment for the samples A (ε = 5 %) and D (ε = 32 %) with higher amount of α′-martensite cannot be entirely excluded. Nonetheless, our additional X-ray diffraction measurement using CoK α radiation for the samples after annealing procedure did not reveal significant differences which could be ascribed to different amounts of chromium carbide precipitates. The increase of microhardness accompanying the increase of the S-parameter indicating carbides precipitation was not observed.
Conclusions
PAS studies were carried out on austenitic SS 1.4301 (EN) deformed in tension at different temperatures to investigate the microstructural changes as a function of heat treatment. The temperature dependence of the annihilation line shape parameter, i.e., the S-parameter shows the gradual annealing of the defects induced by deformation. However, the increase of the S-parameter in the temperature range between 450 and 650 °C for two samples with higher volume fraction of deformation-induced α′-martensite, i.e., 0.19 and 0.25, indicates generation of new lattice defects, which trap positrons. This temperature range coincides with the temperature range of α′-martensite reversion which was confirmed by magnetic properties measurements and indicated by Vickers microhardness decrease.
Positron lifetime measurements for the sample deformed to 5 % at LN2 temperature with the initial α′-martensite fraction f α′ = 0.25 revealed the presence of large vacancy clusters comprising 6–9 vacancies in this temperature range. Their presence can be caused by volume contraction accompanying bcc/fcc change. Volume excess may contribute to the vacancy cluster formation at martensite–austenite interfaces in the course of the transformation. However, the analysis of the positron lifetime spectrum measured for the sample deformed to 32 % at RT with initial f α′ = 0.19 indicates that vacancy clusters if present have a significantly lower concentration. This may be caused by the lower initial fraction of martensite or the influence of higher initial concentration of dislocations resulting from higher deformation level. In spite of the low carbon content in the SS investigated, the influence of chromium carbide precipitation on grain boundaries on the S-parameter increase cannot be excluded which is connected to the fact that cold working and α′-martensite presence promote formation of carbides.
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Dryzek, E., Sarnek, M. & Wróbel, M. Reverse transformation of deformation-induced martensite in austenitic stainless steel studied by positron annihilation. J Mater Sci 49, 8449–8458 (2014). https://doi.org/10.1007/s10853-014-8555-y
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DOI: https://doi.org/10.1007/s10853-014-8555-y