From Springer Nature via Jisc Publications RouterHistory: received 2020-06-22, accepted 2020-08-21, registration 2020-09-04, pub-electronic 2020-09-29, online 2020-09-29, collection 2020-12Publication status: PublishedAbstract: Twin boundaries (TBs) in Ni-based superalloys are vulnerable sites for failure in demanding environments, and a current lack of mechanistic understanding hampers the reliable lifetime prediction and performance optimisation of these alloys. Here we report the discovery of an unexpected γ″ precipitation mechanism at TBs that takes the responsibility for alloy failure in demanding environments. Using multiscale microstructural and mechanical characterisations (from millimetre down to atomic level) and DFT calculations, we demonstrate that abnormal γ″ precipitation along TBs accounts for the premature dislocation activities and pronounced strain localisation associated with TBs during mechanical loading, which serves as a precursor for crack initiation. We clarify the physical origin of the TBs-related cracking at the atomic level of γ″-strengthened Ni-based superalloys in a hydrogen containing environment, and provide practical methods to mitigate the adverse effect of TBs on the performance of these alloys

Harte, Allan

Lu, Song

Morana, Roberto

Preuss, Michael

Yang, Zhibiao

Zhang, Zhenbo

ChesterRep

Supplementary Information  Strain localisation and failure at twin-boundary complexions in nickel-based superalloys  Zhang et al.                          Supplementary Figures  Supplementary Figure 1. Twin boundaries in Alloy 945X: (a) boundary map obtained by EBSD, where red lines and black lines indicate the Σ3 twin boundaries and general high angle boundaries, respectively; (b) misorientation angle distribution of all grain boundaries; (c) and (d) dark field TEM images of γʺ from the grains at both sides of the TB, incident electron beam is along <110>γ  Supplementary Figure 2. Young’s modulus map of alloy 945X that is used for statistic analysis in Fig.3i and 3j obtained from EBSD data.   Supplementary Figure 3. (a) SEM image from a region in Figure R9 with slip traces along TBs indicated by arrows; (b) the corresponding elastic modulus map with the elastic modulus notated in each grains, and twin boundaries are highlight in green color   Supplementary Figure 4. HRDIC analysis of shear strain distribution in the sample after tensioning to a strain of 0.6%: (a) EBSD grain boundary map and (b) the maximum shear strain map obtained by HRDIC from the same region in (a) with the colour legend below (b)      Supplementary Figure 5. Fractographic analysis of the H-charged Alloy 945X after SSRT to failure: (a) an overview SEM images of the whole cross section showing the quasi-cleavage fracture in the outer ring; (b) and (e) showing four flat facets selected from the quasi-cleavage region in (a); (c) and (f) the corresponding images obtained by confocal laser microscope; (d) and (g) EBSD maps from the sample surface containing the facets I, II, III and IV, the {111} plane traces and their maximum Schmid factors are noted.  A table below the images summarises the data obtained from EBSD and confocal laser microscope.     Supplementary Figure 6. BSE images showing H-induced cracking along the DSBs at the vicinity of TBs in Alloy 945X: (a) a crack along a DSB at a TB, which is in a region far from the fracture surface; (b) cracks near a TB close to the fracture surface; (c) an enlarged BSE image from (c) showing both the main cracks and a secondary crack exactly follow the DSBs developed due to the V-shaped γʺ.      Supplementary Figure 7. BSE image showing γʺ along TBs and in the grain interior in an under-aged 945X sample (annealed at1040 °C/1h followed by cooling to ambient temperature with a rate of ~900 °C/h, and then aged at 735 °C/6 hrs + 635 °C/18 hrs)   Supplementary Figure 8. Schematic diagram illustrates how the highly ordered γʺ along TBs incurs the formation of weak planes without precipitation strengthening.        Supplementary Figure 9. Slip trace development captured during in-situ loading and strain map obtained by HRDIC: (a) grain boundary map obtained by EBSD with twin boundaries in red lines; (b)-(d) images from the identical region as (a) recorded during loading; (e) shear strain map obtained by HRDIC from the framed region in (d). The sample has the same condition as that in Figure R3 (annealed 1040 °C /1h, cooling in air; aged 706 °C/6 hrs + 607 °C/18 hrs).     Supplementary Figure 10. Microstructure and shear strain maps of Inconel 718 alloy after different heat treatments (I) annealed 1040 °C /1h, air cooling and aged at 774 °C /6hrs and (II) annealed 1040 °C /1h, air cooling and aged at 800 °C /48hrs with different microstructures: (a),(d) dark field TEM image showing γʺ precipitates; (b), (e) grain boundary maps with TBs in red lines; (c), (f) shear strain maps from the same region shown in (b) and (e) respectively, of the two samples after tensioning to a total strain of about 2%.     Supplementary Figure 11. BSE image of Alloy 945X after solution annealing at 1040 °C for 1 h followed by cooling to room temperature with a cooling rate of 5 °C/min  Supplementary Figure 12. STEM-EDX analysis of a TB in the Alloy 945X after solution annealing and water quenched: (a) HAADF STEM image containing a TB; and its corresponding EDX elemental maps (b) Ni; (c) Nb; (d) Ti; (e) Al; (f) Cr    Supplementary Figure 13. BSE image of Inconel 718 after solution annealing at 1040 °C for 1 hour followed by cooling to room temperature with a cooling rate of 5 °C/min, and then aging at 802 °C for 8 hours.   Supplementary Figure 14. BSE images showing γʺ, TBs and DSBs in the sample after tensioning to a total strain of 1%. (a) a TB and a DSB very closely affiliated to the TB (hardly be separated) and (b) two parallel DSBs distributed very adjacent to a TB, in the under-aged 945X sample (annealed 1040 °C /1h, cooling in air; aged 706 °C/6 hrs + 607 °C/18 hrs)       Supplementary Figure 15. Microstructural study on the dislocation slip bands (DSBs) and twin boundaries (TBs) in Alloy 945X-LB (low band treated)*: (a) BSE image shows DSBs across several TBs in the sample after tensioning to a strain of 1 %; (b) the schematic diagram of (a); (c) and (d) enlarged images from two regions marked in (a) showing DSB along a TB; (e) fracture surface of the H-charged sample after SSRT to failure. It can be seen from images (a)-(d) that the size difference in γʺ between that along TBs and in the grain interiors is not appreciable, which is very different to that observed in Fig.1 of 945X-HB (high band treated)*. Consequently, in contrast to 945X-HB, DSBs at TBs in 945X-LB are so close to TBs, so we cannot separate them even at very high magnification. It is also evident that DSBs are not only along TBs but also in grain interiors at this stage. Due to such significant difference in the character of TBs and dislocation plasticity between two samples, the fracture surface of H-charged 945X-LB is very different to that of 945X-HB. H-charged 945X-HB exhibits very flat facets on the fracture surface which results from cracking along TBs, whereas the fracture mode of 945X-LB is much more ductile and cracking along TBs is effectively suppressed.  * Alloy conditions: 945X-HB 1040 °C /1h, 5°C /min cooling rate; 735 °C/6 hrs + 635 °C/18 hrs 945X-LB 1040 °C /1h, cooling in air; 706 °C/6 hrs + 607 °C/18 hrs                    Supplementary Figure 16. Microstructure and properties of 945X-LB and 945X-HB: (a) and (b) dark field TEM images along [100] zone axis showing the morphology of γʺ in the two samples; (c) properties of H-charged and non-charged alloys under the two conditions. It shows that 945X-LB has much smaller γʺ than 945X-HB, with average size of 16 nm and 39 nm respectively. As shown in the table, the H susceptibility of 945X-LB is much lower. In addition, using in-situ loading we obtained the stress level for DSBs initiation at TBs (σTwin) and grain matrix (σMatrix) in the non-charged sample. The ratio between them indicates how large of the γʺ effect on the dislocation activities at TBs.  It can be seen that the σTwin/σMatrix ratio is much larger in 945X-LB sample, which means the dislocation activities commence at similar stress level at TBs and grain interiors. In this manner, strain is more evenly distributed in the sample and the strain localisation at TBs is largely mitigated, which is believed to be the main reason for the better performance of 945X-LB with H in presence.              Supplementary Note 1 DFT calculations: lattice parameters of  and   Ni3Nb phases  To get the equilibrium structure of the    phase, the total energies E (c/a, V) as a function of the c/a and the volume (V) are calculated, then we obtain the optimized lattice parameters from the contour plot of E (c/a, V). For the   phase, the volume is assumed the same as that of the    phase 1, with this constrain, the optimized lattice parameters are obtained from E (b/a, c/a) contour. The lattice parameters of    and   Ni3Nb phases obtained by EMTO methods (Table S1) agree well with the previous theoretical results using the GGA and LDA functionals 2, 3 as well as the experimental results [14,15]. Supplementary Table 1 Calculated lattice parameters of    and   phases of Ni3Nb in comparison with the previous theoretical and experimental results. The lattice parameter of  phase is obtained with the constrain that it has the same volume as the  phase.     phase a(Å) c(Å) c/a   phase a(Å) b(Å) c(Å) EMTO 3.67 7.49 2.04 EMTO 5.12 4.24 4.53 LDA 2 3.58 7.33 2.05 LDA 3 5.02 4.18 4.47 GGA 2 3.66 7.48 2.04 GGA 3 5.13 4.27 4.57 Exp. 4 3.624 7.406 2.04 Exp. 5 5.14 4.23 4.53  DFT calculations: stacking fault and twin boundary energies  The calculated SFEs are summarized in Table S2. As a benchmark, the isf of pure Ni is calculated to be 151.1 mJ m-2, which is in good agreement with the previous DFT (e.g., 155 mJ m-2  ) 6 and experimental (125 mJ m-2 ) results7.   For the matrix with composition of Ni56Cr25Fe19, isf is calculated to be 21.1 mJ m-2, which is consistent with the experimental results showing that both Cr and Fe additions in Ni drastically decrease the SFE 8. The estimated experimental value 8 , 9 for the present composition is about 35 mJ m-2. Supplementary Table 1 Calculated γisf for fcc Ni and Ni-Cr25-Fe19 and for the D022 structure of Ni3Nb and Ni3(NbTi), in comparison with other theoretical results. Composition Structure 𝛾𝑖𝑠𝑓 (mJ m-2)  𝛾𝑡𝑤 (mJ m-2)  Previous 𝛾𝑖𝑠𝑓 (mJ m-2)  Ni fcc 151.1 75.6 155 6 Ni56Cr25Fe19 21.1 10.6 35 8  Ni3Nb  D022 6.9 3.5 2.3 2 Ni3(Nb,Ti)  1.2 0.6   For Ni3Nb, the calculated γisf is 6.9 mJ m-2, which agrees with the previous DFT result (2.3 mJ m-2) 2 where the structural relaxation was considered. Alloying Ti is found to strongly decrease the γisf to 1.2 mJ m-2. Based on the universal scaling relationship,12tw isf =  10, the twin boundary energies are estimated to be 3.5 mJ m-2 for Ni3Nb and 0.6 mJ m-2 for Ni3(Nb,Ti), respectively.  DFT calculations: interfacial energy of γ/γ The γ-Ni3Nb phase has two types of {001} planes, one with 100%Ni and the other with 50%Ni +50%Nb. Thereby, there are two (001)γ//(001)coherent interfaces and the averaged interfacial energy is calculated in the following. The interface supercell is composed of 8 layers of (001)γ and 8 layers of (001), which contains the above two interfaces due to the periodic boundary conditions. The underlying lattice parameters are taken as those of , and the  structure is relaxed accordingly. The interfacial distance is also relaxed. The total energy is denoted as 𝐸16𝛾/𝛾. The reference bulk energies of  and  phases are calculated using the incremental method. The total energy of a supercell containing 8 layers of (001)  and 6 layers (001) , 𝐸14𝛾/𝛾, is used to calculate the reference bulk energy of γ phase (per atom) according to, 𝐸𝛾 =(𝐸16𝛾/𝛾− 𝐸14𝛾/𝛾)/4). The bulk energy (per atom) of γ״ phase is calculated by 𝐸𝛾 =(𝐸16𝛾/𝛾− 𝐸12𝛾/𝛾)/8, where 𝐸12𝛾/𝛾 is the total energy of a supercell containing 8 layers of (001)γ and 4 layers of (001). The averaged interface energy of two (001)γ//(001)coherent interfaces is calculated by, 𝜎𝛾/𝛾 =𝐸16𝛾/𝛾−16𝐸𝛾−16𝐸𝛾′′2𝐴, where A is the interface area. The obtained interfacial energies for Ni/Ni3Nb at ferromagnetic and paramagnetic states are 145 and 112 mJ m-2, respectively. For Ni56Cr25Fe19/Ni3Nb at paramagnetic state, 𝜎𝛾/𝛾 is 76 mJ m-2. The above results are in nice agreement with previously reported value (95±17 11, 90 12, 52 13 mJ m-2).   Supplementary References 1. Li, C.-X., et al. Lattice parameters and relative stability of α″ phase in binary titanium alloys from first-principles calculations. Solid State Commun. 159, 70-75 (2013). 2. Lv, D. C., McAllister, D., Mills, M. J., Wang, Y. Deformation mechanisms of D022 ordered intermetallic phase in superalloys. Acta Mater. 118, 350-361 (2016). 3. Dai, S., Liu, W. First-principles study on the structural, mechanical and electronic properties of δ and γ″ phases in Inconel 718. Comp. Mater. Sci. 49, 414-418 (2010). 4. 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Strain localisation and failure at twin-boundary complexions in nickel-based superalloys

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Strain localisation and failure at twin-boundary complexions in nickel-based superalloys

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