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Article

The Effect of Aging on Precipitates, Mechanical and Magnetic Properties of Fe-21Cr-15Ni-6Mn-Nb Low Magnetic Stainless Steel

1
State Key Laboratory of Rolling and Automation, Northeastern University, Shenyang 110819, China
2
Panassonic Appliances Compressor (Dalian) Co., Ltd., Dalian 116033, China
*
Authors to whom correspondence should be addressed.
Submission received: 22 April 2021 / Revised: 10 May 2021 / Accepted: 11 May 2021 / Published: 18 May 2021

Abstract

:
The effect of aging on the precipitates, mechanical and magnetic properties of Fe-21Cr-15Ni-6Mn-Nb low magnetic stainless steel were investigated. The steel was aged at 550–750 °C for 2 h after solution heat treatment at 1100 °C for 1 h. During the aging treatment, the (Nb, V)(C, N) particles gradually precipitated in the grain, which were coherent or semi-coherent with the matrix. When the aging temperature was beyond 650 °C, the coarsening rate of (Nb, V)(C, N) particles increase rapidly and the coherent orientation between (Nb, V)(C, N) particles and the matrix was lost gradually. Meanwhile, coarse M23C6 was distributed at the grain boundary with chain shape, which was non-coherent with the matrix. The coarsening behavior of (Nb, V)(C, N) precipitates in the grain was analyzed, and the size of the particles precipitated after aging treatment at 650°C for different time was calculated and studied. After aging treatment at 650 °C for 2 h, the yield strength and tensile strength of the stainless steel was 705.6 MPa and 1002.3 MPa, the elongation and the relative magnetic permeability was 37.8% and 1.0035, respectively.

1. Introduction

Compared with ferritic and martensitic stainless steels, austenitic stainless steels (ASSs) have advantages in ductility, toughness, corrosion resistance and creep strength [1,2]. It has been extensively researched and widely used in the nuclear power, aviation and military industries [3,4]. In terms of the stable ASSs, it can avoid being magnetized in magnetic field due to the paramagnetic property of austenite, so called low-magnetic stainless steels [5]. Low-magnetic stainless steels have been applied on critical and serious area, such as components in electronic instruments, large-scale nuclear fusion equipment, naval submarines for providing protection against magnetic detection and undersea mines [6].
With regard to low magnetic stainless steels, the primary strategy to obtain low permeability is to ensure the stability of austenite during deformation or heat treatment; however, the strength of traditional ASSs is considerably low. For instance, the yield strength and tensile strength of SUS304 stainless steel are 200–400 MPa and 600–750 MPa, respectively [7]. For the strengthening of unstable ASSs, the inverse transformation of strain induced martensite through annealing procedure after cold or cryogenic rolling is widely adopted by many researchers [8,9]. However, due to the absence of phase transformation in low-magnetic stainless steels, strengthening mechanism is consisted with precipitation hardening of fine particles homogenously distributed throughout the matrix and solution strengthening with the addition of elements of Cr, Ni, Mo, Nb, V, etc. [10,11]. Precipitates play a crucial role in stabilizing the microstructure, inhibiting the grain growth and suppressing the recrystallization of low-magnetic stainless steels. As potential nanosized precipitates in stainless steels, carbides, nitrides, Cu-rich precipitates, nickel aluminide, oxides and many other types of precipitates have been investigated [12,13,14,15,16]. Long-term aging at elevated temperatures tend to facilitate elemental diffusion and thus cause precipitates coarsening, which consequently results in degradation in the microstructure and mechanical properties [17]. For instance, in 19Cr-0.4Nb ferrite stainless steels, coarsening of the Fe3Nb3C precipitates lead to the degradation in high temperature strength and thermal fatigue resistance during the long-term service at 1073–1173 K [18]. The main reason for the decrease at high temperature strength of 310S austenitic stainless steel is the coarsening of Laves phase during long time aging treatment [11]. Therefore, understanding of microstructure stability in aging treatment, particularly the thermal stability of all the precipitates, and its effects on mechanical properties is vital for applications of low-magnetic stainless steels. Furthermore, there are few studies on the effect of precipitation on the magnetic properties for low-magnetic stainless steels.
The specific orientation relationship and interface structure between the precipitates and the matrix can effectively hinder the movement of dislocations [19]. The coarsening behavior of the precipitates and mechanical behavior are affected by the orientation relationship [20]. It has been reported that the small block of M23C6 become spherical because the coherent relation between M23C6 and matrix is lost in Fe-Cr-Ni-Mn-Mo-V-Nb super alloy [21]. Trotter et al. reported a sufficient tensile ductility of an aged alumina-forming stainless austenitic steel and attributed this to a moderate misfit between the Laves phase and austenite matrix [22]. Due to the low interfacial energy of the semi-coherent relationship between the NbC and the matrix, the diffusion of Nb atoms is difficult, and the nano-NbC has stronger resistance to coarsening than M23C6 in 310S austenitic stainless steel [11]. Considering that the coarsening of precipitates is unavoidable at high temperatures, it is of great importance to study the change of orientation relationship with the coarsening of precipitates in low-magnetic stainless steels.
The precipitation, mechanical and magnetic properties of Fe-21Cr-15Ni-6Mn-Nb low magnetic stainless steel were investigated in this paper. The precipitates evolution through aging treatment for low magnetic stainless steel were investigated. The coherent or semi-coherent relationship of (Nb, V)(C, N) precipitates with the matrix in the aging treatment were researched. The coarsening behavior of intragranular (Nb, V)(C, N) particles during the aging process were analyzed by LSW theory. The relative magnetic permeability of experimental steel with different aging process was studied. These studies can promote the research and application of high strength low magnetic stainless steel.

2. Materials and Experiments

2.1. Fabrication of the Experimental Steel

The chemical composition of the experimental steel is shown in Table 1. The preparation process of the experimental steel is as follows: (1)The cylindrical steel ingot with diameter of Φ250 mm and weight of 75 kg was obtained by vacuum induction smelting; (2) the ingot is forged into a billet of 100 mm × 100 mm × 50 mm; (3) the billet of 100 mm × 100 mm × 50 mm is placed in a heating furnace(Boda Electric Furnace, Xi’an, China) for high temperature homogenizing treatment at 1200 °C for 2 h, followed by hot rolling in a Φ450 mm two-roll reversible hot mill, after 9 passes of hot rolling, a hot rolled sheet with a thickness of 4.5 mm was obtained, the starting temperature and finishing temperature of hot rolling are 1160 °C and 940 °C, respectively, after hot rolling the steel sheet was cooled by water; (4) solution treatment of experimental steel was performed at 1100 °C for 1 h; (5) after solution treatment, the experiment steel was aging treated at 550, 600, 650, 700 and 750 °C for 2 h.

2.2. Microstructural and Properties Characterisation

The phase analysis was carried out by XRD (Bruker D8, Leipzig, Germany). The measured diffraction angle ranged from 20 to 100°, the scanning speed was 2 °/min, the anode target was Cu and the sample was prepared by electrolytic polishing. Electrolytic polishing solution was made by mixing perchloric acid, acetic acid and ethanol solution. The specific ratio was V (perchloric acid):V (acetic acid):V (alcohol) = 2:1:7, polishing voltage is 25–30 V, polishing time is 25 to 32 s and electrolytic polishing temperature is ambient temperature. The morphology of the precipitates was observed by SEM (ZEISS ULTRA 55, Hallbergmoos, Germany). The steps of sample preparation and the corresponding parameters are as follows: Electrolytic corrosion of grinded and polished specimens was performed at ambient temperature, the etching solution was 60% aqueous nitric acid solution and the corrosion voltage was 25–35 V. The corrosion current is 1.5 to 1.8 A, and the corrosion time is 25 to 35 s. The precipitated particles were further observed by TEM (FEI Tecnai G2 F20, Hillsboro, OR, USA) with an acceleration voltage of 200 kV. The sample was first mechanically thinned to 50 μm and then subjected to electrolytic double spray thinning at 32 V and −30 °C by double spray thinner (Struers TenuPol-5, Copenhagen, Denmark) to form a film sample. The electrolyte was composed of 9% perchloric acid and 91% absolute ethanol.
The tensile tests were carried out on electronic universal tensile testing machine (CMT 5105, Kexin, Changchun, China) at a tensile speed of 3 mm/min, and three samples were tested for each process to take the average value. Magnetic properties of experimental steel were measured through vibrating sample magnetometer (VSM Lake Shore 7407, Changchun, China) with magnetic field strengths ranging from −5 kOe to +5 kOe.

3. Results

3.1. Thermodynamic Calculation of Precipitates

Figure 1 shows the relationship between the molar mass of precipitates and temperature in the equilibrium state of experimental steel calculated by Thermal-Calc thermodynamic software. As is shown in Figure 1a, the precipitates mainly include FCC_A1#2, Z phase, M23C6 and σ phase in the temperature range of 400–1600 °C. Figure 1b is the enlargement of Figure 1a. FCC_A1#2 is the preferred precipitate at 1145 °C with the decrease of temperature, followed by Z phase and M23C6. The dissolution temperature of these precipitates is about 1020 °C, which is higher than 660 °C of hard brittle σ phase. Over the entire calculated temperature range, the amount of FCC_A1#2 remained stable, while the precipitation of M23C6 decreased sharply with the increase of temperature. Due to the forming of stable carbonitrides with Nb and V preferentially combined with C and N, the C and N content in the matrix is reduced, and the precipitation of M23C6 as well as Z phase are inhibited. In addition, the content of σ phase decreases sharply with the increase of temperature.
Figure 1c shows the main element components of FCC_A1#2. The change trend of elements with temperature is very similar to the results of Han et al. [23]. It can be inferred that the precipitation phase is relatively complex carbonitride (Nb, V)(C, N). In the aging process, the types and morphology of precipitates will be further analyzed.

3.2. Microstructure after Solution Treatment

Figure 2 shows the scanning electron micrograph and EDS of the experimental steel after solution treatment. The microstructure was uniform austenite equiaxed grain. The average grain size was 13 (±2.6) μm in diameter via the Image Pro Plus image processing software. A small amount of granular precipitates existed at grain boundaries in the structure of experiment steel (indicated by the red circle in Figure 2a, and the sizes of granular precipitates were all below 0.1 μm. From the energy spectrum analysis of precipitates in Figure 2b, the Nb content in granular precipitates is highest.
Through TEM observation and diffraction spot calibration, the granular precipitate can be determined as Nb(C, N), which is a typical face-centered cubic structure with a lattice constant of 0.447 nm [24], as shown in Figure 3. These granular Nb carbonitrides were formed during the solidification and could not be completely dissolved during subsequent hot rolling experiments and solution treatment. If the residual Nb(C, N) particles are excessive after solution treatment, the content of Nb in the experimental steel will decrease, and the effect of precipitation strengthening in aging treatment will be greatly reduced. In the present study, since the diameter of Nb(C, N) precipitates at the grain boundary was less than 100 nm and the distance between them is more than 10 μm, the residual Nb(C, N) particles in solution treatment had no effect on the microstructure and properties of experimental steel with aging treatment [25].

3.3. Microstructure after Aging Treatment

The experiment steel was aging treated at 550, 600, 650, 700 and 750 °C for 2 h. The result of XRD phase analysis and SEM observation were shown in Figure 4. It can be seen from Figure 4a that the diffraction peak of the γ phase is the strongest in the curves. The second phase particles mainly consisted of MX-type particles and M23C6. With the temperature increases in the aging treatment, the diffraction peak of MX-type particles gradually increased. The strongest diffraction peak of MX-type particles existed at 650 °C. Further increasing the temperature, the diffraction peak of MX-type particles decreased gradually.
After aging treatment at different temperatures, the grain size of the steel remained stable. When the aging temperature was 550 °C, a small amount of spherical particles occurred in the grain (Figure 4b). When the aging temperature increased to 600 and 650 °C, the spherical particles were dispersed in the crystal. The size of the precipitates remained unchanged, and amount of the precipitates increased (Figure 4c,d). When the aging temperature was 700 °C, the grain boundaries began to coarsen, due to the aggregation of precipitates at grain boundaries. And the size of intragranular particles gradually increased (Figure 4e). When the aging temperature increased to 750 °C, the entire scanning area had been connected into a network structure. The coarse particles in the crystal existed in irregular shapes. And the width of the aggregation of precipitates at grain boundaries had been increased to about 2.5 μm (Figure 4f). This kind of microstructure will have a very adverse effect on the comprehensive properties of the steel.
Figure 5 shows the TEM and the energy spectrum analysis of the precipitated particles after aging treatment at 650 °C for 2 h. As shown in Figure 5a, the fine spherical precipitates were dispersed in the grain, with the average diameter of 28 nm. The TEM-EDS analysis of the precipitates were shown in the upper right of Figure 5a. The results of EDS show that the content of niobium in the precipitates was the highest, which was consistent with the thermodynamic calculation. Because of high Cr, Nb and N in the steel, it was easy to form Z-phase (NbCrN) particles in aging treatment at high temperature [23]. Therefore, it needs further observation and analysis to identify the precipitates. In terms of composition, the contents of Cr and N are usually higher in Z phase [26]. In addition, the precipitates in the grain were spherical or ellipsoidal (Figure 5a), while the Z phase is usually rod-shaped [27,28]. Combined with TEM diffraction spot calibration, it can be further determined that the precipitated particles are (Nb, V)(C, N) with face centered cubic (FCC) structure and have cubic-on-cubic orientation with austenite matrix, as shown in Figure 5b. In the isothermal process, Nb(C, N) nucleates preferentially, while V(C, N) shows a characteristic of epitaxial precipitation. Once Nb(C, N) is formed, V(C, N) begins to nucleate in shell or cluster around it, but the structure remains unchanged [27,28]. The mismatch between (Nb, V)(C, N) and austenite matrix was calculated to be 17.6%, which indicates that (Nb, V)(C, N) are always semi-coherent with the austenite matrix after aging treatment at 650 °C for 2 h. It can be observed in the Figure 5a,b that it is the dislocation cutting mechanism when the precipitates are small and coherent with the matrix. The schematic diagram of dislocation cutting mechanism is as shown in Figure 5c. Due to the different crystal constants between the precipitates and the matrix, a part of dislocation energy exists. After the dislocation cuts through the precipitated phase, the interfacial energy increase with the increasing interfacial area. The stress field around the particle interact with the dislocation stress field, which hinder the dislocation movement. It is a process of energy rising when the dislocation cuts through the particle, which make the dislocation slip difficult and the steel strengthened.
Figure 6 shows the TEM morphology of precipitated particles after aging treatment at 750 °C for 2 h. The morphology of (Nb, V)(C, N) particles are large block or ellipsoid and the average diameter of (Nb, V)(C, N) particles was 253 nm (Figure 6a). In general, Nb-rich carbonitrides are preferentially precipitated at the {111} γ plane [29,30]. But in this study, the diffraction spots of the precipitated phase do not all appear under the same low-index ribbon axis (the red circular frame portion in Figure 6b by calibrating the coarse (Nb, V)(C, N) diffraction patterns. It can be determined that the original cubic-cubic orientation between coarsened (Nb, V)(C, N) particles and matrix has been lost, which means the coherent relationship with the matrix is gradually lost with the coarsening of (Nb, V)(C, N). At the trigeminal boundary, a discontinuous cell or sheet structure was observed. It is found by diffraction pattern calibration that the precipitated particle was M23C6 (Figure 6c) showing a non-coherent orientation with the matrix, as shown in Figure 6d. The deformation mechanism transfer from cutting to bowing out when the hard particles are large and incoherent with the matrix, as shown in Figure 6a. The schematic diagram of dislocation bypass mechanism is as shown in Figure 6e. When the dislocations sweep through the large precipitates, the dislocations would bypass the particles and continued to move. The dislocation line will bend when it bypasses the particles. When the bending of dislocation line is serious, the two ends of the dislocation line will meet and the dislocation will continue to move forward with leaving a dislocation loop. The energy increases due to stretch the dislocation in bending process. Therefore, the dislocations are difficult to move and the alloy is strengthened.

3.4. Mechanical Properties

Figure 7 shows the tensile curves and mechanical properties of the experimental steel plates under different aging treatment conditions. It can be found that the strength of the steel sheet is significantly improved after aging treatment. This is the results of the precipitation which contributes to an increase of strength for the stainless steel. Table 2 shows the tensile properties of the experimental steel after different aging treatment. The optimal aging treatment process parameters is at 650 °C for 2 h, while the yield strength, the tensile strength and the elongation is 705.6 MPa, 1002.3 MPa and 37.8%. When the aging temperature is lower than 650 °C, there is almost no change at the grain boundary, fine (Nb,V)(C,N) particles in the grain remain coherent or semi-coherent relationship with the matrix and strongly hinders dislocation slip during plastic deformation. When the aging temperature is higher than 650 °C, the precipitated particles in the grain will increase and the coarsened particles gradually lose their coherent or semi-coherent relationship with the matrix, which greatly reduces the total interfacial energy and weakens the strengthening effect.

3.5. Magnetic Properties

Figure 8 shows the hysteresis loop of steel sheet sample under different aging treatment conditions. It can be seen that the hysteresis loops of the experimental steel are almost completely coincident and close to a perfect linear relationship, and no typical hysteresis loop occurs. It can be known from the microscopic analysis that since the precipitated phases are all face-centered cubic structures, no ferromagnetic phases exist. The relative magnetic permeability is calculated as 1.003, which means the stainless steel has good low magnetic characteristics. When aging treatment is carried out under different conditions, the number and size of precipitates in the experimental steel are different. However, through the magnetic properties test, it is found that the hysteresis loop of the experimental steel after various aging treatments is still a straight line, showing paramagnetic properties. Therefore, the precipitates produced in the aging process of the experimental steel will not affect the paramagnetic properties of the experimental steel. Aging treatment will not destroy the paramagnetic stability of the experimental steel.

4. Discussion

4.1. Precipitate in Aging Treatment

In the conventional Cr-Ni austenitic stainless steel, the precipitated phase include MX (M = Nb, V, Ti, X = C, N), M23C6 (M = Fe, Cr), Z phase (Cr(Nb,V)N), hard and brittle σ phase (FeCr). In this experiment, combined with the TEM diffraction spot calibration, it can be further determined that the precipitated particles are (Nb, V)(C, N) of the face-centered cubic structure and have a cube-on-cube orientation relationship with the austenite matrix. Z phase particles have a body-centered cubic (BCC) structure, which are easily formed in steels containing high Cr, high Nb and high N [26]. Once the Z phase arises, it will grow up at a rapid speed with the cost of MX-type carbonitrides, and it is difficult to control the size, which is not beneficial to the strength of the steel. The precipitation of Z phase needs high temperature environment or long time aging [31]. In this study, through the energy spectrum analysis of (Nb, V)(C, N) particles aged at 650 °C for 10 h (Figure 9a,b) and aged at 750 °C for 2 h (Figure 9c,d), 11 during the whole aging process, and the composition of Cr always keeps a low content, which is consistent with the thermodynamic calculation results. The results show that there was no Z-phase particles in the aging process.
Formation of an intermetallic phase known as σ-phase is a severe problem when using standard austenitic stainless steels at elevated temperatures [32,33]. In the initial state of austenitic stainless steel which contains 0.18% carbon will be present a ferrite α-phase. As a result, at the temperature of 450−550 °C, stratification of the high-chromium α-solid solution will occur and a brittle σ-phase is formed. Therefore, aging is best carried out in the temperature range 600−650 °C, then the microstructure of the steel will be precisely balanced. In this paper, due to the high amount of N (0.368%) and the higher affinity for Nb, V than that of carbon, the nitrogen in experimental steel is consumed for the stabilization of austenite partially and for the formation of nitride phases with niobium and vanadium firstly. At the same time, the affinity of Nb and V for C is stronger than that of Cr and Mo, which is not conducive to the formation of intergranular precipitation phase M23C6. By reducing the Cr-depleted region and the diffusion rate of Cr, the probability of σ phase formation decrease.

4.2. Coarsening of the (Nb, V)(C, N) Precipitates

The precipitation and dissolution of second phase particles in the steel is actually a diffusion process. When the temperature is high enough or the time is long enough, the coarsening of precipitates is unavoidable [22,24], which weaken the strengthening effect. According to the LSW theory proposed by Lifshitz, Slyozov and Wagner [23,25], the relationship between the size of roughened particles and time is shown in Equation (1).
r t 3 r 0 3 = k t k = 8 D σ C α ( ) V m 9 R T
where, rt is the average radius of the precipitated particles, m; r0 is the initial average radius of the precipitated phase, m; k is the roughening rate, m3/s; D is the diffusion coefficient of the solute atom in the matrix; σ is the interfacial energy between precipitated phase and austenite matrix, J/m2; Cα represents the equilibrium concentration of the solute atom at infinity from the precipitation phase, mol/m3; Vm represents the molar volume fraction of precipitated phase, m3/mol; T is the Kelvin temperature, K.
Since the experimental steel is solution treated before aging treatment, r0 is negligible. Equation (1) can be expressed as Equation (2).
r t 3 k t
The size of precipitates in the aging treatment are calculated by Image Pro Plus image processing software. The change of the coarsening rate and average radius of the intragranular particles is shown in Figure 10. It can be seen that the roughening rate is low at 550, 600 and 650 °C (Figure 10a), which can be ascribed to the value of D and Vm in Equation (1) is small at 650 °C. While the aging temperature exceeds 650 °C, the coarsening rate increases rapidly. Because the activity of the solute atoms increases, the diffusion is sufficient. The small-sized (Nb, V)(C, N) particles begin to dissolve, reducing the total surface area of precipitated particles in the grain, which in turn reduces the interfacial energy, with the temperature increasing the Ostwald ripening phenomenon occurs. The average radius of intragranular (Nb, V)(C, N) particles at 650 °C for 0.5–10 h by calculation and experimental was shown in Figure 10b. It can be found that the calculated value is consistent well with the predicted value.

4.3. Effect of Precipitates on Mechanical Properties

In this study, the strength of the experimental steel increased after different aging treatment temperature and 650 °C with different time at as shown in Figure 11. The maximum strength existed in the process of aging at 650 °C for 2 h. When the aging temperature is lower than 650 °C (Figure 11a) or the aging time is less than 2 h (Figure 11b), the amount of (Nb, V)(C, N) particles increases gradually with the rising of temperature or time, and the size of (Nb, V)(C, N) particles remain unchanged. It keeps coherent or semi-coherent relationship with the matrix. There is a high-energy strain field between the second phase particles and the matrix, which can strongly block the dislocation slip in the process of plastic deformation [34]. It is called coherent mechanism in the second phase strengthening. When the aging temperature is higher than 650 °C or time is higher than 2 h, the coarsened particles gradually lose the coherent or semi coherent relationship with the matrix. When the coherent relationship is lost, the total interface energy will be greatly reduced, and the total amount of reduction will exceed the elastic strain energy generated by coherent strengthening, that is, the high energy region is lost, and the strengthening effect is weakened [35].
There existed Orowan or cutting mechanism on interaction between dislocations and particles for precipitation strengthening [36], which mechanism plays a leading role depends on the size of the particles. They are all related to the size distribution and volume fraction of particles.
The pinning effect of precipitated particles on dislocation is shown in Equation (3) [36,37]:
Δ τ = α G b λ
where, α is a constant; G is the shear modulus, MPa; b is the Bernoulli vector of dislocation, nm. λ is the average free path of particle motion, as shown in Equation (4) [38]:
λ = d ( 1 f 1 / 3 ) f 1 / 3
where, d is the average diameter of precipitated particles, m; f is the volume fraction of precipitated phase, %. At low temperature or early aging stage, combined with the calculation of microstructure and particle coarsening rate, it can be seen that the particles keep small size and have enough stability, and then increase the volume fraction f of the second phase, so it has a significant strengthening effect. The microstructure observation shows that the coarsening rate increases with the increase of temperature or time, the precipitation amount and volume fraction of particles decrease and the average free path λ increases, which leads to the decrease of the pinning effect of particles on dislocations in the plastic deformation process of the whole system [39].
Figure 12 shows the tensile fracture morphology of steel plate under different heat treatment conditions. As shown in Figure 12a, after solution treatment, the fracture surface is dominated by large and deep equiaxed dimples, showing good ductile fracture characteristics, which is a typical fracture mode of micropore aggregation. As shown in Figure 12b, after aging at 650 °C for 2 h, the fracture mode is still ductile fracture, but the average diameter and average depth of dimple are greatly reduced compared with that of solution treated fracture. From the enlargement of Figure 12b, there are a large number of particles at the bottom of the dimple, which indicates that dislocations pile up around the second phase particles during the tensile process, resulting in local deformation and detachment from the austenite matrix. After aging at 650 °C with 10 h (Figure 12c) and at 750 °C with 2 h (Figure 12d), brittle fracture characteristics such as intergranular fracture and flat cleavage surface appear, which belong to the mixed fracture mode of toughness and brittleness. With the increase of aging temperature and aging time, the precipitates on grain boundary begin to gather, the size of precipitates in grain becomes larger and the coherent relationship with matrix is lost. On the one hand, the crystal structure of the coarse intermetallic compound is different from that of the matrix, so it is easy to produce the uncoordinated deformation in the plastic deformation, resulting in the stress concentration at the interface between the intermetallic compound and the matrix, forming the crack source [40,41]. On the other hand, the mechanism of dislocation slip changes from shear to bypass. When intragranular dislocation slip encounters precipitated phase, the critical shear stress required to bypass precipitated phase is lower than that required by shear. Dislocations tend to bypass precipitates and gather at grain boundaries, leading to stress concentration, intergranular fracture and brittle fracture.
According to the change trend of tensile properties with aging temperature and time, it can be seen that the plasticity presents a downward trend, which is mainly caused by two factors. Firstly, particles coarsen rapidly during high temperature or long aging, which weakens the effect of particles on moving dislocation pinning during plastic deformation; secondly, non-coherent M23C6 is produced at the trigeminal grain boundary. As we all know, the existence of non-coherent M23C6 will greatly reduce the toughness of the material, because the coarse and non-coherent M23C6 seriously weakens the bond strength between the original grain boundaries [42,43], and then leads to the rapid crack initiation in the process of tensile deformation and reduces the plasticity of the steel plate.

5. Conclusions

The effect of aging on the precipitates, mechanical and magnetic properties of Fe-21Cr-15Ni-6Mn-Nb low magnetic stainless steel was investigated.
(1) When the aging treatment is at 500–650 °C for 2 h, the fine (Nb, V)(C, N) is diffused with the temperature increases, which is in a coherent or semi-coherent relationship with the matrix. When the temperature exceeds 650 °C, the (Nb, V)(C, N) particles gradually lose their coherent relationship with the matrix, the grain boundary is gradually coarsened and chain-like distribution of M23C6 occur, which is in a non-coherent relationship with the matrix. During the whole aging process, the Z phase and the σ phase do not appear.
(2) The coarsening behavior of intragranular (Nb, V)(C, N) particles during the aging treatment was analyzed by LSW theory. It was found that the roughening rate rises rapidly when the aging temperature exceeded 650 °C. The particle size of the precipitated particles at 650 °C with different time was calculated. The theoretical values of the precipitated particles in the grain are consistent with the measured values.
(3) Under the aging treatment process at 650 °C with 2 h, the yield strength, tensile strength, elongation and the relative magnetic permeability of the experimental steel is 705.6 MPa, 1002.3 MPa, 37.8% and 1.003. It demonstrates that the precipitates through aging treatment improved the strength and kept low magnetic property.

Author Contributions

C.L. conceived and designed the experiments; K.L. performed the experiments and wrote the paper; Y.S. performed the experiments; J.D. and J.R. analyzed the data. All authors have read and agreed to the published version of the manuscript.

Funding

This work was funded by the joint project from the National Natural Science Foundation of China and Baowu Steel Group Co. Ltd. (Grant No. U1660205).

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

Not applicable.

Conflicts of Interest

The authors declare no conflict of interest.

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Figure 1. Equilibrium phase fractions of precipitates for experimental steel calculated by Thermal-Calc. (a) 0~1 mol of Y axis, (b) 0~0.1 mol of Y axis, (c) variation of C, N, V, Nb and Cr in FCC_A1#2.
Figure 1. Equilibrium phase fractions of precipitates for experimental steel calculated by Thermal-Calc. (a) 0~1 mol of Y axis, (b) 0~0.1 mol of Y axis, (c) variation of C, N, V, Nb and Cr in FCC_A1#2.
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Figure 2. Microstructure of solution-treated experimental steel. (a) SEM of solution-treated experimental steel, the precipitates on the grain boundary are marked with red circles, (b) energy spectrum analysis of precipitates.
Figure 2. Microstructure of solution-treated experimental steel. (a) SEM of solution-treated experimental steel, the precipitates on the grain boundary are marked with red circles, (b) energy spectrum analysis of precipitates.
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Figure 3. TEM morphology of the steel after solution treatment. (a) Bright field image of retained particles, (b) diffraction pattern calibration of precipitates.
Figure 3. TEM morphology of the steel after solution treatment. (a) Bright field image of retained particles, (b) diffraction pattern calibration of precipitates.
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Figure 4. XRD and SEM of the specimens aged at different temperature for 2 h. (a) XRD analysis, (b) 550 °C, (c) 600 °C, (d) 650 °C, (e) 700 °C, (f) 750 °C.
Figure 4. XRD and SEM of the specimens aged at different temperature for 2 h. (a) XRD analysis, (b) 550 °C, (c) 600 °C, (d) 650 °C, (e) 700 °C, (f) 750 °C.
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Figure 5. TEM analysis of the precipitates in specimens aged at 650 °C for 2 h. (a) The bright field image and energy spectrometer detection of the particles, (b) diffraction patterns of the particles, (c) the schematic diagram of dislocation cutting mechanism.
Figure 5. TEM analysis of the precipitates in specimens aged at 650 °C for 2 h. (a) The bright field image and energy spectrometer detection of the particles, (b) diffraction patterns of the particles, (c) the schematic diagram of dislocation cutting mechanism.
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Figure 6. TEM analysis of the precipitates in specimens aged at at 750 °C for 2 h. (a,b) The bright field image and diffraction patterns of the coarsening (Nb, V)(C, N) particles, (c,d) the bright field image and diffraction patterns of M23C6 in the angular boundary, (e) the schematic diagram of dislocation bypass the particles mechanism.
Figure 6. TEM analysis of the precipitates in specimens aged at at 750 °C for 2 h. (a,b) The bright field image and diffraction patterns of the coarsening (Nb, V)(C, N) particles, (c,d) the bright field image and diffraction patterns of M23C6 in the angular boundary, (e) the schematic diagram of dislocation bypass the particles mechanism.
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Figure 7. Stress-strain curve of the experimental steel after different aging treatment. (a) different temperatures with 2 h, (b) 650 °C with different time.
Figure 7. Stress-strain curve of the experimental steel after different aging treatment. (a) different temperatures with 2 h, (b) 650 °C with different time.
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Figure 8. Hysteresis loop of experimental steel under different aging treatment conditions. (a) Different temperatures with 2 h, (b) 650 °C with different time.
Figure 8. Hysteresis loop of experimental steel under different aging treatment conditions. (a) Different temperatures with 2 h, (b) 650 °C with different time.
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Figure 9. TEM and EDS analysis of elements in the steel after aging treatment. (a,b) aging at 650 °C for 10 h, (c,d) aging at 750 °C for 2 h.
Figure 9. TEM and EDS analysis of elements in the steel after aging treatment. (a,b) aging at 650 °C for 10 h, (c,d) aging at 750 °C for 2 h.
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Figure 10. Calculation of coarsening rate of precipitates (a) at different aging temperatures with 2 h, (b) comparison of the calculated and measured precipitates inside the grains at 650 °C with different aging times.
Figure 10. Calculation of coarsening rate of precipitates (a) at different aging temperatures with 2 h, (b) comparison of the calculated and measured precipitates inside the grains at 650 °C with different aging times.
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Figure 11. Influence of aging parameters on YS, UTS and elongation for the experimental steel. (a) Aging at different temperatures with 2h, (b) aging at 650 °C with different time.
Figure 11. Influence of aging parameters on YS, UTS and elongation for the experimental steel. (a) Aging at different temperatures with 2h, (b) aging at 650 °C with different time.
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Figure 12. Fracture morphology of tensile specimens after different aging treatment. (a) Solution treatment, (b) aging at 650 °C with 2 h after solution treatment, the precipitates at the bottom of the dimple are indicated by red arrows, (c) aging at 650 °C with 10h after solution treatment, cleavage fracture is marked by yellow circle, (d) aging at 750 °C with 2 h after solution treatment, intergranular fracture is marked by yellow circle.
Figure 12. Fracture morphology of tensile specimens after different aging treatment. (a) Solution treatment, (b) aging at 650 °C with 2 h after solution treatment, the precipitates at the bottom of the dimple are indicated by red arrows, (c) aging at 650 °C with 10h after solution treatment, cleavage fracture is marked by yellow circle, (d) aging at 750 °C with 2 h after solution treatment, intergranular fracture is marked by yellow circle.
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Table 1. The chemical composition of the experimental steel (mass, %).
Table 1. The chemical composition of the experimental steel (mass, %).
CSiMnMoNiCrNbVNBal
0.180.2035.90.5014.8520.251.340.350.368Fe
Table 2. Tensile properties of the experimental steel after different aging treatment.
Table 2. Tensile properties of the experimental steel after different aging treatment.
Aging TreatmentYield Strength/MPaTensile Strength/MPaElongation/%
550 °C, 2 h66090148
600 °C, 2 h68097343
650 °C, 2 h705100238
700 °C, 2 h69396337
750 °C, 2 h67693132
650 °C, 0.5 h66189848
650 °C, 1 h69397142
650 °C, 4 h68597938
650 °C, 10 h67296534
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Li, C.; Li, K.; Dong, J.; Ren, J.; Song, Y. The Effect of Aging on Precipitates, Mechanical and Magnetic Properties of Fe-21Cr-15Ni-6Mn-Nb Low Magnetic Stainless Steel. Metals 2021, 11, 819. https://0-doi-org.brum.beds.ac.uk/10.3390/met11050819

AMA Style

Li C, Li K, Dong J, Ren J, Song Y. The Effect of Aging on Precipitates, Mechanical and Magnetic Properties of Fe-21Cr-15Ni-6Mn-Nb Low Magnetic Stainless Steel. Metals. 2021; 11(5):819. https://0-doi-org.brum.beds.ac.uk/10.3390/met11050819

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Li, Changsheng, Kun Li, Jingbo Dong, Jinyi Ren, and Yanlei Song. 2021. "The Effect of Aging on Precipitates, Mechanical and Magnetic Properties of Fe-21Cr-15Ni-6Mn-Nb Low Magnetic Stainless Steel" Metals 11, no. 5: 819. https://0-doi-org.brum.beds.ac.uk/10.3390/met11050819

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