REFERENCES

1. Li, X.; Zheng, M.; Pan, H.; Mao, C.; Ding, W. An integrated design of novel RAFM steels with targeted microstructures and tensile properties using machine learning and CALPHAD. J. Mater. Inf. 2024, 4, 27.

2. Tang, Y. T.; Panwisawas, C.; Ghoussoub, J. N.; et al. Alloys-by-design: application to new superalloys for additive manufacturing. Acta. Mater. 2021, 202, 417-36.

3. Alabort, E.; Barba, D.; Shagiev, M.; et al. Alloys-by-design: application to titanium alloys for optimal superplasticity. Acta. Mater. 2019, 178, 275-87.

4. Yang, Q.; Wang, Z.; Xiao, X.; Xie, J. CALPHAD-assisted composition and processing design of high-strength and high-conductivity copper alloy. Mater. Sci. Eng. A. 2023, 881, 145432.

5. Shen, C. The synergy of machine learning and CALPHAD: revitalizing traditional approaches. Comput. Mater. Sci. 2025, 258, 113970.

6. Li, X.; Chen, X. Data‐driven discovery of new eutectic high‐entropy alloys via calculation of phase diagrams and machine learning integration. Adv. Eng. Mater. 2025, 27, 2500879.

7. He, L.; Wang, C.; Zhang, M.; Li, J.; Chen, T.; Zhou, X. Design of BCC/FCC dual-solid solution refractory high-entropy alloys through CALPHAD, machine learning and experimental methods. npj. Comput. Mater. 2025, 11, 105.

8. Sheikh, S.; Vela, B.; Honarmandi, P.; et al. High-throughput alloy and process design for metal additive manufacturing. npj. Comput. Mater. 2025, 11, 179.

9. Wall, A.; Benoit, M. J. A review of existing solidification crack tests and analysis of their transferability to additive manufacturing. J. Mater. Process. Technol. 2023, 320, 118090.

10. Balluffi, R. W.; Mehl, R. F. Grain boundary diffusion mechanisms in metals. Metall. Trans. A. 1982, 13, 2069-95.

11. Sheikh, S.; Vela, B.; Attari, V.; et al. Exploring chemistry and additive manufacturing design spaces: a perspective on computationally-guided design of printable alloys. Mater. Res. Lett. 2024, 12, 235-63.

12. Mu, Y.; Zhang, X.; Chen, Z. Modeling of crack susceptibility of Ni-based superalloy for additive manufacturing via thermodynamic calculation and machine learning. Acta. Metall. Sin. 2023, 59, 1075-86.

13. Peachey D, He Y, Zhang P, et al. ABD-1000AM: a highly processible superalloy for additive manufacturing, computationally designed for 1000 °C applications. In AM-EPRI 2024, Indian Wells, USA, 2024; pp. 861-72.

14. Wang, J.; Kwon, H.; Oh, S.; Kim, H. S.; Lee, B. Interpretable and physics-informed modeling of solidification in alloy systems: a generalized framework for multi-component prediction. Acta. Mater. 2025, 286, 120716.

15. Lou, M.; Xu, K.; Chen, L.; et al. Development of robust surfaces for harsh service environments from the perspective of phase formation and transformation. J. Mater. Inf. 2021, 1, 5.

16. Szymanski, N. J.; Rendy, B.; Fei, Y.; et al. An autonomous laboratory for the accelerated synthesis of novel materials. Nature 2023, 624, 86-91.

17. Merchant, A.; Batzner, S.; Schoenholz, S. S.; Aykol, M.; Cheon, G.; Cubuk, E. D. Scaling deep learning for materials discovery. Nature 2023, 624, 80-5.

18. Zhu, S.; Sarıtürk, D.; Arróyave, R. Accelerating CALPHAD-based phase diagram predictions in complex alloys using universal machine learning potentials: opportunities and challenges. Acta. Mater. 2025, 286, 120747.

19. Andersson, J. O.; Helander, T.; Höglund, L.; Shi, P.; Sundman, B. Thermo-Calc & DICTRA, computational tools for materials science. Calphad 2002, 26, 273-312.

20. Chen, S.; Daniel, S.; Zhang, F.; et al. The PANDAT software package and its applications. Calphad 2002, 26, 175-88.

21. Saunders, N.; Guo, U. K. Z.; Li, X.; Miodownik, A. P.; Schillé, J. Using JMatPro to model materials properties and behavior. JOM 2003, 55, 60-5.

22. Lukas, H.; Fries, S. G.; Sundman, B. Computational thermodynamics: the Calphad method. Cambridge University Press: Cambridge, 2007. https://dl.acm.org/doi/10.5555/1537219. (accessed 2026-05-26).

23. Hillert, M.; Jarl, M. A model for alloying in ferromagnetic metals. Calphad 1978, 2, 227-38.

24. Sundman, B.; Chen, Q.; Du, Y. A review of Calphad modeling of ordered phases. J. Phase. Equilib. Diffus. 2018, 39, 678-93.

25. Sundman, B.; Lu, X.; Ohtani, H. The implementation of an algorithm to calculate thermodynamic equilibria for multi-component systems with non-ideal phases in a free software. Comput. Mater. Sci. 2015, 101, 127-37.

26. Schmid, R.; Chang, Y. A thermodynamic study on an associated solution model for liquid alloys. Calphad 1985, 9, 363-82.

27. Campbell, C.; Boettinger, W.; Kattner, U. Development of a diffusion mobility database for Ni-base superalloys. Acta. Mater. 2002, 50, 775-92.

28. Ury, N.; Neuberger, R.; Sargent, N.; Xiong, W.; Arróyave, R.; Otis, R. Kawin: an open source Kampmann–Wagner Numerical (KWN) phase precipitation and coarsening model. Acta. Mater. 2023, 255, 118988.

29. Gulliver, G. H. The quantitative effect of rapid cooling upon the constitution of binary alloys. J. Inst. Met. 1915, 13, 120-57.

30. Chen, Q.; Sundman, B. Computation of partial equilibrium solidification with complete interstitial and negligible substitutional solute back diffusion. Mater. Trans. 2002, 43, 551-9.

31. Wahlmann, B.; Leidel, D.; Markl, M.; Körner, C. Numerical alloy development for additive manufacturing towards reduced cracking susceptibility. Crystals 2021, 11, 902.

32. Lu, X.; Selleby, M.; Sundman, B. Assessments of molar volume and thermal expansion for selected bcc, fcc and hcp metallic elements. Calphad 2005, 29, 68-89.

33. Zhu, N.; Liu, W.; Wang, Z.; Lu, X. Modeling of molar volume for the Ni–Al γ/γ′ binary phases within the framework of CALPHAD method. Calphad 2020, 71, 101792.

34. Sichen, D.; Bygd’en, J.; Seetharaman, S. A model for estimation of viscosities of complex metallic and ionic melts. Metall. Mater. Trans. B. 1994, 25, 519-25.

35. Schick, M.; Brillo, J.; Egry, I.; Hallstedt, B. Viscosity of Al–Cu liquid alloys: measurement and thermodynamic description. J. Mater. Sci. 2012, 47, 8145-52.

36. Ho, C. Y.; Ackerman, M. W.; Wu, K. Y.; Oh, S. G.; Havill, T. N. Thermal conductivity of ten selected binary alloy systems. J. Phys. Chem. Ref. Data. 1978, 7, 959-1178.

37. Du, B.; Tan, J.; Wu, Q.; Wen, S.; Liu, Y.; Du, Y. Assessment of thermal conductivity for FCC Al-X (X=Zn, Mg) and Al-Zn-Mg alloys: experiments and modeling. Calphad 2024, 87, 102763.

38. Bochvar, N. R.; Vigdorovich, V. N.; Leonova, N. P.; Lysova, E. V. Electrical resistivity of alloys in the systems Cu–Mn–Ge, Cu–Mn–Sn, and Cu–Ge–Sn. Met. Sci. Heat. Treat. 1984, 26, 175-8.

39. Gypen, L. A.; Deruyttere, A. Multi-component solid solution hardening: Part 2 Agreement with experimental results. J. Mater. Sci. 1977, 12, 1034-8.

40. Gladman, T. Precipitation hardening in metals. Mater. Sci. Technol. 1999, 15, 30-6.

41. Cao, W.; Zhang, F.; Chen, S.; et al. Precipitation modeling of multi-component nickel-based alloys. J. Phase. Equilib. Diffus. 2016, 37, 491-502.

42. Hall, E. O. The deformation and ageing of mild steel: III discussion of results. Proc. Phys. Soc. B. 1951, 64, 747.

43. Chen, S. L.; Chou, K. C.; Chang, Y. A. On a new strategy for phase diagram calculation 1. Basic principles. Calphad 1993, 17, 237-50.

44. Chen, S. L.; Chou, K. C.; Chang, Y. On a new strategy for phase diagram calculation 2. Binary systems. Calphad 1993, 17, 287-302.

45. Sundman, B.; Dupin, N.; Hallstedt, B. Algorithms useful for calculating multi-component equilibria, phase diagrams and other kinds of diagrams. Calphad 2021, 75, 102330.

46. Liu, X. L.; Lindwall, G.; Gheno, T.; Liu, Z. Thermodynamic modeling of Al–Co–Cr, Al–Co–Ni, Co–Cr–Ni ternary systems towards a description for Al–Co–Cr–Ni. Calphad 2016, 52, 125-42.

47. Wang, Y.; Cacciamani, G. Experimental investigation and thermodynamic assessment of the Al-Co-Ni system. Calphad 2018, 61, 198-210.

48. Chen, H.; Chen, Q.; Engström, A. Development and applications of the TCAL aluminum alloy database. Calphad 2018, 62, 154-71.

49. Lee, B. A thermodynamic evaluation of the Fe-Cr-Mn-C system. Metall. Trans. A. 1993, 24, 1017-25.

50. Liu, M.; Zhang, L.; Chen, W.; Xin, J.; Du, Y.; Xu, H. Diffusivities and atomic mobilities in fcc_A1 Ni–X (X=Ge, Ti and V) alloys. Calphad 2013, 41, 108-18.

51. Liu, F.; Wang, Z.; Wang, Z.; et al. High-throughput determination of interdiffusivity matrices in Ni-Al-Ti-Cr-Co-Mo-Ta-W multicomponent superalloys and their application in optimization of creep resistance. Mater. Today. Commun. 2020, 24, 101018.

52. Saunders, N.; Guo, Z.; Li, X.; Miodownik, A. P.; Schillé, J. P. The calculation of TTT and CCT diagrams for general steels. 2004. https://www.researchgate.net/publication/242271477_The_Calculation_of_TTT_and_CCT_diagrams_for_General_Steels. (accessed 2026-05-26).

53. American Society for Metals. Atlas of isothermal transformation and cooling transformation diagrams. 1977. https://www.scribd.com/document/572302665/ATLAS-OF-ISOTHERMAL-TRANSFORMATION-AND-COOLING-TRANSFORMATION-DIAGRAMS-compressed. (accessed 2026-05-26).

54. British Iron And Steel Research Association Metallurgy (General) Division. Atlas of isothermal transformation diagrams of B.S. En Steels. 2nd ed.; Iron and Steel Institute: London, 1949. https://books.google.com/books/about/Atlas_of_Isothermal_Transformation_Diagr.html?id=UeTJCnjaMRIC. (accessed 2026-05-26).

55. Fang, X.; Li, Y.; Zheng, Q.; et al. Theoretical prediction of structural, mechanical, and thermophysical properties of the precipitates in 2xxx series aluminum alloy. Metals 2022, 12, 2178.

56. Feng, X.; Liang, F. Measurement and analysis of molten Ni-Co-Al alloy density. J. Mater. Sci. Technol. 2003, 19, 388-90. https://www.jmst.org/CN/abstract/abstract6501.shtml. (accessed 2026-05-26).

57. Sato, Y. Representation of the viscosity of molten alloy as a function of the composition and temperature. Jpn. J. Appl. Phys. 2011, 50, 11RD01.

58. Zhou, K.; Wang, H. P.; Chang, J.; Wei, B. Surface tension measurement of metastable liquid Ti–Al–Nb alloys. Appl. Phys. A. 2011, 105, 211-4.

59. Otter, F. A. Thermoelectric power and electrical resistivity of dilute alloys of Mn, Pd, and Pt in Cu, Ag, and Au. J. Appl. Phys. 1956, 27, 197-200.

60. Yang, L.; Yang, J.; Han, F.; et al. Hot cracking susceptibility prediction from quantitative multi-phase field simulations with grain boundary effects. Acta. Mater. 2023, 250, 118821.

61. Koshikawa, T.; Gandin, C.; Bellet, M.; Yamamura, H.; Bobadilla, M. Computation of phase transformation paths in steels by a combination of the partial- and para-equilibrium thermodynamic approximations. ISIJ. Int. 2014, 54, 1274-82.

62. Zheng, L.; Gu, C.; Zheng, Y. Investigation of the solidification behavior of a new Ru-containing cast Ni-base superalloy with high W content. Scr. Mater. 2004, 50, 435-9.

63. Chen, Y.; Lu, F.; Zhang, K.; et al. Dendritic microstructure and hot cracking of laser additive manufactured Inconel 718 under improved base cooling. J. Alloys. Compd. 2016, 670, 312-21.

64. Tian, J.; Song, A.; Chen, S.; Liu, C.; Ye, X. Weldability of GH3539 superalloy: unraveling the dueling roles of Zr, C, and Si in solidification crack formation and healing. J. Mater. Res. Technol. 2025, 39, 4561-75.

65. Cloots, M.; Uggowitzer, P. J.; Wegener, K. Investigations on the microstructure and crack formation of IN738LC samples processed by selective laser melting using Gaussian and doughnut profiles. Mater. Design. 2016, 89, 770-84.

66. Zhang, X.; Chen, H.; Xu, L.; Xu, J.; Ren, X.; Chen, X. Cracking mechanism and susceptibility of laser melting deposited Inconel 738 superalloy. Mater. Design. 2019, 183, 108105.

67. Hariharan, A.; Lu, L.; Risse, J.; et al. Misorientation-dependent solute enrichment at interfaces and its contribution to defect formation mechanisms during laser additive manufacturing of superalloys. Phys. Rev. Mater. 2019, 3, 123602.

68. Ogawa, Y.; Noguchi, K.; Takakuwa, O. Criteria for hydrogen-assisted crack initiation in Ni-based superalloy 718. Acta. Mater. 2022, 229, 117789.

69. Qi, H.; Azer, M.; Ritter, A. Studies of standard heat treatment effects on microstructure and mechanical properties of laser net shape manufactured INCONEL 718. Metall. Mater. Trans. A. 2009, 40, 2410-22.

70. Chen, Y.; Zhang, K.; Huang, J.; Hosseini, S. R. E.; Li, Z. Characterization of heat affected zone liquation cracking in laser additive manufacturing of Inconel 718. Mater. Design. 2016, 90, 586-94.

71. Johnson, L.; Mahmoudi, M.; Zhang, B.; et al. Assessing printability maps in additive manufacturing of metal alloys. Acta. Mater. 2019, 176, 199-210.

72. Special Metals. https://www.specialmetals.com/. (accessed 2026-05-26).

73. Davis, J. R. Metals Handbook Desk Edition. 2nd Edition. ASM International; 1998. https://books.google.com/books/about/Metals_Handbook_Desk_Edition_2nd_Edition.html?id=IpEnvBtSfPQC. (accessed 2026-05-26).