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Molecular dynamics simulation is an effective computer simulation method. However, owing to the lack of suitable interatomic potential of multicomponent alloys, the application of molecular dynamics simulation is limited. The development of interatomic potential of multicomponent alloys has always been challenging. In this work, under the framework of EAM model, a construction method of interatomic potential suitable for ternary ordered alloys is proposed, and a new interatomic potential of Ti2AlNb alloys suitable for atomic-scale mechanical behavior simulation is developed. The potential can well reproduce the elastic constants of B2-Ti2AlNb, unrelaxation vacancy formation energy, substitutional atom formation energy, transposition atom formation energy, surface energy and cohesive energy of three ordered phase (B2, D019 and O phases ) in different volumes. To further test the potential functions, 1) the E-V curve of B2 phase is calculated, and the result is well consistent with Rose curve; 2) the melting transformation process of B2 phase is studied by molecular dynamics simulation, and the results roughly reflect the experimental fact. The present work provides a way to develop the interatomic potential of multicomponent alloys, and a option for the workers who simulate and calculate the Ti2AlNb alloys as well.
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Keywords:
- embedded atom method potential /
- Ti2AlNb alloys /
- defects
[1] Deringer V, Csanyi G 2017 Phys. Rev. B 95 094203Google Scholar
[2] Alizadeh Z, Mohammadizadeh M R 2019 Physica C 558 7Google Scholar
[3] Jordan M I, Mitchell T M 2015 Science 349 255Google Scholar
[4] Smith J S, Nebgen B, Mathew N, Chen J, Lubbers N, Burakovsky L, Tretiak S, Nam H A, Germann T, Fensin S, Barros K 2021 Nat. Commun. 12 1257Google Scholar
[5] Artrith N, Urban A 2016 Comput. Mater. Sci. 114 135Google Scholar
[6] Kumpfert J 2001 Adv. Eng. Mater. 3 851Google Scholar
[7] Boehlert C J, Majumdar B S 1999 Metall. Mater. Trans. A 30 2305Google Scholar
[8] 冯艾寒, 李渤渤, 沈军 2011 材料与冶金学报 10 30Google Scholar
Feng A H, Li B B, Shen J 2011 J. Mater. Metall. 10 30Google Scholar
[9] Gogia T K, Nandy T K, Banerjee D, Carisey T, Strudel J L, Franchet J M 1998 Intermetallics 6 741Google Scholar
[10] Banerjee D, Gogia A K, Nandi T K, Joshi V A 1988 Acta Metall. 36 871Google Scholar
[11] Pathak A, Singh A K 2015 Solid State Commun. 204 9Google Scholar
[12] Daw M S, Baskes M I 1984 Phys. Rev. B 29 6443Google Scholar
[13] Cheng C, Ma Y L, Bao Q L, Wang X, Sun J X, Zhou G, Wang H, Liu Y X, Xu D S 2019 Comput. Mater. Sci. 173 109432Google Scholar
[14] Johnson R A 1989 Phys. Rev. B 39 12554Google Scholar
[15] Voter A F 1994 Intermetallic Compounds (New York: Wiley) pp77—80
[16] Mishin Y, Mehl M J 2002 Phys. Rev. B 65 224114Google Scholar
[17] Ravi C, Vajeeston P, Mathijaya S, Asokamani R 1999 Phys. Rev. B:Condens. Matter. 60 683Google Scholar
[18] Kittel C 1976 Introduction to Solid State Physics (New Jersey: John Wiley & Sons) pp57–58
[19] Weast R C 1984 Handbook of Chemistry and Physics (Boca Raton: Chemical Rubber) p64
[20] Johnson R A 1972 Phys. Rev. B 6 2094Google Scholar
[21] Oh D J, Johnson R A 2011 Mater. Res. 3 471Google Scholar
[22] Bolef D I 1961 Appl. Phys. 32 100Google Scholar
[23] Agrawal A, Mishra R, Ward L, Flores K M, Windl W 2013 Modell. Simul. Mater. Sci. Eng. 21 085001Google Scholar
[24] Farkas D 1999 Modell. Simul Mater. Sci. Eng. 4 23Google Scholar
[25] Rose J H, Smith J R, Guinea F, Ferrante J 1984 Phys. Rev. B 29 2963Google Scholar
[26] Julius C S, Martin P 2006 J. Phase Equilib. Diffus. 27 255Google Scholar
[27] Vasudevan V K, Yang J, Woodfield A P 1996 Scr. Mater. 35 1033Google Scholar
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表 1 B2-Ti2AlNb的晶格常数和生成焓(单位: eV)
Table 1. Lattice constants and formation enthalpy for B2-Ti2AlNb (in eV).
表 2 单质Ti, Al, Nb的内聚能(单位: eV)
Table 2. Cohesive energies for Ti, Al and Nb (in eV)
表 3 Ti2AlNb合金EAM势的拟合参数
Table 3. Fitting parameters of EAM potential for Ti2AlNb alloys.
$ \phi \left({r}_{\mathrm{T}\mathrm{i}\mathrm{A}\mathrm{l}}\right) $ $ \phi \left({r}_{\mathrm{T}\mathrm{i}\mathrm{N}\mathrm{b}}\right) $ $ \phi \left({r}_{\mathrm{N}\mathrm{b}\mathrm{A}\mathrm{l}}\right) $ Parameter value Parameter value Parameter value $ \alpha $ –2.1129 $ \alpha $ –4.2151 $ \alpha $ –0.2797 $ \beta $ –1.3742 $ \beta $ –6.6808 $ \beta $ –2.5122 $ \gamma $ 0.2705 $ \gamma $ 1.4339 $ \gamma $ 1.6140 $ \epsilon $ 0.1758 $ \epsilon $ –0.0008 $ \epsilon $ 0.1140 $ \sigma $ –2.3191 $ \sigma $ –1.4062 $ \sigma $ –1.6132 $ \mu $ 0.0516 $ \mu $ 0.2694 $ \mu $ 0.4012 表 4 B2-Ti2AlNb的弹性常数(单位: GPa)
Table 4. Elastic constants for B2-Ti2AlNb (in GPa).
C11 C33 C44 C66 C12 C13 ABINIT[11] 136 — 81 — 100 — DFT 153.20 147.83 69.36 71.86 133.42 97.62 This work 195.82 178.95 64.35 66.83 136.92 127.04 表 5 B2-Ti2AlNb单空位形成能和双空位形成能(单位: eV)
Table 5. Mono-vacancy formation energies and di-vacancy formation energies for B2-Ti2AlNb (in eV).
DFT This work This-lmp EAM-fa $ {E}_{\mathrm{v}}^{\mathrm{f}} $ Ti 2.879 2.283 2.283 1.343 Al 2.859 3.265 3.265 1.391 Nb 2.194 1.763 1.657 4.919 $ {E}_{\mathrm{d}}^{\mathrm{f}} $ TiTi-1 5.454 4.503 4.498 2.562 TiTi-2 5.854 4.539 4.533 2.777 TiTi-3 5.688 4.570 4.567 2.724 TiAl-1 5.623 5.434 5.434 4.014 TiNb-1 4.731 3.980 3.980 3.699 AlNb-1 4.710 4.854 4.854 4.777 表 6 B2-Ti2AlNb置换原子和换位原子形成能(单位: eV)
Table 6. Substitutional atom and transposition atom formation energies for B2-Ti2AlNb (in eV).
DFT This work This-lmp EAM-fa $ {E}_{\mathrm{o}}^{\mathrm{f}} $ $ {\mathrm{T}\mathrm{i}}_{\mathrm{A}\mathrm{l}} $ 1.046 0.976 0.976 –2.863 $ {\mathrm{T}\mathrm{i}}_{\mathrm{N}\mathrm{b}} $ –0.384 –0.418 –0.418 –2.440 $ {\mathrm{A}\mathrm{l}}_{\mathrm{T}\mathrm{i}} $ 0.268 0.433 0.433 –1.164 $ {\mathrm{A}\mathrm{l}}_{\mathrm{N}\mathrm{b}} $ –1.310 –1.216 –1.216 –1.113 $ {\mathrm{N}\mathrm{b}}_{\mathrm{T}\mathrm{i}} $ 0.638 0.624 0.624 –7.439 $ {\mathrm{N}\mathrm{b}}_{\mathrm{A}\mathrm{l}} $ 1.522 1.289 1.289 0.911 $ {E}_{\mathrm{e}}^{\mathrm{f}} $ TiAl 1.097 1.181 1.181 –4.142 TiNb 0.270 0.191 0.191 –9.213 AlNb 0.123 0.172 0.172 –0.571 Clo 1.078 1.132 1.132 –3.169 Ant 0.453 0.413 0.413 –10.752 表 7 B2-Ti2AlNb的表面能(单位: eV)
Table 7. Surface energies for
B2-Ti2AlNb (in eV). DFT This work This-lmp EAM-fa $ {E}_{\mathrm{s}\mathrm{u}\mathrm{r}}^{\mathrm{f}} $ (100) 2.056 2.298 2.273 1.705 (110) 1.937 2.194 2.170 1.620 (100)′ 1.844 — 1.923 0.484 (110)′ 1.661 — 1.750 –11.000 表 8 Ti2AlNb合金的内聚能(单位: eV)
Table 8. Cohesive energies for Ti2AlNb alloys (in eV).
VB2 60% 67% 75% 83% 91% 1 110% 120% 130% 142% 154% E-DFT –3.22 –4.13 –4.75 –5.14 –5.35 –5.42 –5.37 –5.22 –5.02 –4.77 –4.48 $ V_{{\rm D0}_{19}} $ 57% 64% 72% 81% 90% 1 111% 122% 134% 147% 160% E-DFT –2.55 –3.78 –4.60 –5.10 –5.37 –5.44 –5.38 –5.21 –4.96 –4.66 –4.32 VO 58% 65% 73% 81% 90% 1 110% 121% 133% 145% 158% E-DFT –2.79 –3.92 –4.69 –5.16 –5.41 –5.48 –5.42 –5.26 –5.03 –4.74 –4.42 -
[1] Deringer V, Csanyi G 2017 Phys. Rev. B 95 094203Google Scholar
[2] Alizadeh Z, Mohammadizadeh M R 2019 Physica C 558 7Google Scholar
[3] Jordan M I, Mitchell T M 2015 Science 349 255Google Scholar
[4] Smith J S, Nebgen B, Mathew N, Chen J, Lubbers N, Burakovsky L, Tretiak S, Nam H A, Germann T, Fensin S, Barros K 2021 Nat. Commun. 12 1257Google Scholar
[5] Artrith N, Urban A 2016 Comput. Mater. Sci. 114 135Google Scholar
[6] Kumpfert J 2001 Adv. Eng. Mater. 3 851Google Scholar
[7] Boehlert C J, Majumdar B S 1999 Metall. Mater. Trans. A 30 2305Google Scholar
[8] 冯艾寒, 李渤渤, 沈军 2011 材料与冶金学报 10 30Google Scholar
Feng A H, Li B B, Shen J 2011 J. Mater. Metall. 10 30Google Scholar
[9] Gogia T K, Nandy T K, Banerjee D, Carisey T, Strudel J L, Franchet J M 1998 Intermetallics 6 741Google Scholar
[10] Banerjee D, Gogia A K, Nandi T K, Joshi V A 1988 Acta Metall. 36 871Google Scholar
[11] Pathak A, Singh A K 2015 Solid State Commun. 204 9Google Scholar
[12] Daw M S, Baskes M I 1984 Phys. Rev. B 29 6443Google Scholar
[13] Cheng C, Ma Y L, Bao Q L, Wang X, Sun J X, Zhou G, Wang H, Liu Y X, Xu D S 2019 Comput. Mater. Sci. 173 109432Google Scholar
[14] Johnson R A 1989 Phys. Rev. B 39 12554Google Scholar
[15] Voter A F 1994 Intermetallic Compounds (New York: Wiley) pp77—80
[16] Mishin Y, Mehl M J 2002 Phys. Rev. B 65 224114Google Scholar
[17] Ravi C, Vajeeston P, Mathijaya S, Asokamani R 1999 Phys. Rev. B:Condens. Matter. 60 683Google Scholar
[18] Kittel C 1976 Introduction to Solid State Physics (New Jersey: John Wiley & Sons) pp57–58
[19] Weast R C 1984 Handbook of Chemistry and Physics (Boca Raton: Chemical Rubber) p64
[20] Johnson R A 1972 Phys. Rev. B 6 2094Google Scholar
[21] Oh D J, Johnson R A 2011 Mater. Res. 3 471Google Scholar
[22] Bolef D I 1961 Appl. Phys. 32 100Google Scholar
[23] Agrawal A, Mishra R, Ward L, Flores K M, Windl W 2013 Modell. Simul. Mater. Sci. Eng. 21 085001Google Scholar
[24] Farkas D 1999 Modell. Simul Mater. Sci. Eng. 4 23Google Scholar
[25] Rose J H, Smith J R, Guinea F, Ferrante J 1984 Phys. Rev. B 29 2963Google Scholar
[26] Julius C S, Martin P 2006 J. Phase Equilib. Diffus. 27 255Google Scholar
[27] Vasudevan V K, Yang J, Woodfield A P 1996 Scr. Mater. 35 1033Google Scholar
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