[1] Kushan M.C., Uzgur S.C., Cevik S., Diltemiz F., ALLVAC 718 Plus™ superalloy for aircraft engine application. Turkey. Second Edittion, 2012. DOI: 10.5772/38433
[2] Schafrik. R.E., Ward D.D., Groh J.R., Application of alloy 718 in GE aircraft engines: past, present and next five years, Proceedings of Superalloys 718, 625, 706 and various derivatives, Ohio. TMS, 2005, 1-11.
[3] Kennedy. R., ALLVAC 718PLUS™, superalloy for the next forty years, Proceedings of Superalloys 718, 625, 706 and various derivatives, Ohio: TMS, 2005, 625-706.
[4] Lech S., Wusatowska-Sarnek A.M., Wieczerzak K., Kruk A., Evolution of microstructure and mechanical properties of ati 718Plus superalloy after graded solution treatment, Metallurgical and Materials Transactions A, 2023, 54, 2011–2021.
[5] Dempster I., Cao W.D., Kennedy R. et. al. Structure and property comparison of ALLVAC 718PLUS™ alloy and waspaloy forgings. Proceedings of Superalloys 718, 625, 706 and various derivatives. Ohio: TMS, 2005, 155-164.
[6] Asala G., Andersson J., Ojo Q.A., A study of the dynamic impact behavior of IN718 and ATI718Plus superalloys, The Philosophical Magazine A 2018, 99, 1-19.
[7] Jiang W., Lu. J. Gun. H., et al., Study of pre-precipitated δ phase promoting deformation twinning and recrystallization behavior of Inconel 718 superalloy during hot compression. Materials & Design. 2023. 226 111693.
[8] Zhu Y., Zhang Sh., Zhang T. et. al., Effect of P, S, B and Si on the solidification segregation of In718plus alloy, Proceedings of Superalloys 718, 625, 706 and various derivatives. Ohio: TMS, 1994, 89-98.
[9] Zhang J., Singer R., Effect of Zr and B on castability of Ni-based superalloy IN792, Metallurgical and Materials Transactions A, 2004, 35 (4) 1337-1342.
[10] R.F. Decker. Freeman J.W. The mechanism of beneficial effects of boron and zirconium on creep-rupture properties of a complex heat-resistant alloy. Transactions of The American Institute of Mining and Metallurgical Engineers, 1957, 218(2) 277-285.
[11] Radavich J., Effects of Zr variations on the microstructural stability of alloy 713C, Proceedings of Superalloys. Warrendale: TMS, 1968, 199-226.
[12] Antony K., Radavich J., Solute effects of boron and zirconium on microporosity. Proceedings of The Third International Symposium, Claitor Publishing, 1976.
[13] Hu Z., Song H., Guo Sh., Sun W., Role of P, S and B on creep behavior of alloy 718, Journal of Materials Science and Technology, 2001, 17, 399-402.
[14] Heydari D., Fard A.S., Bakhshi A., Drezet J.-M., Hot tearing in polycrystalline Ni-based IN738LC superalloy, Influence of Zr content, Journal of Materials Processing Technology, 2014, 214(3) 681-687.
[15] Yamin L., Hongjun L., Jie L., Zhipeng W., Yuan H., Effect of Zr addition on precipitates in K4169 superalloy, Research & Development, 2012.
[16] Aerospace Material Specification (AMS 5442): 2011-09. SAE International Group. 1-9.
[17] Kattoura M.A., Effects of advanced surface treatments on the fatigue behavior of ATI 718 plus at room and elevated temperatures, PhD Thesis, University of Cincinnati, Cincinnati, Ohio USA, 2017.
[18] Fedorova T., Rösler J., Gehrmann B., Klöwer J., Influence of B and Zr on microstructure and mechanical properties of alloy 718, Proceedings of Superalloys 718, 625, 706 and various derivatives, Ohio: TMS, 2005, 837-846.
[19] Meyers M., Chawla K., Mechanical Behavior of Materials. Cambidge. Cambidge Uiversity Press. 2009. 92-98.
[20] Stotter C., Stotter Ch., Sommitsch Ch. et al., Characterization of δ-phase in superalloy ALLVAC 718Plus TM, International Journal of Materials Research, 2008, 99(4) 376-380.
[21] Guo Q. Ji K. Zhang T. et al., Precipitates evolution and tensile behavior of wrought Ni-based ATI 718Plus superalloy during long-term thermal exposure. Science China Technological Sciences. 2022, 65, 1283–1299.
[22] Hosseini S. A., Abbasi S. M., Zangeneh Madar K., The effect of boron and zirconium on microstructure and tensile properties of the wrought nickel-based superalloy ATI 718Plus. Materials Science and Engineering: A, 2018, 712, 780-789.
[23] Zhou P.J., Yu J.J., Sun X. F., Guan H.R., The role of boron on a conventional nickel-based, superalloy, Materials Science and Engineering A, 2008, 49(1) 159-163.
[24]Xiao L., Chaturvedi M., Chen D. Low-cycle fatigue behavior of IN 718 superalloy with different concentrations of boron at room temperature. Metallurgical and Materials Transactions A, 2005, 36(10) 2671-2684.
[25] Hosseini S.A., Abbasi S.M., Zangeneh-Madar K., Mohammad Karimi Yazdi H. The effect of boron and zirconium on wrought structure and γ-γ′ lattice misfit characterization in nickel-based superalloy ATI 718Plus. Materials Chemistry and Physics, 2018, 211, 302-311.
[26] Tsai Y.L., Wang S.F., Bor H.Y., Hsu Y.F., Effects of Zr addition on the microstructure and mechanical behavior of a fine-grained nickel-based superalloy at elevated temperatures, Materials Science and Engineering A, 2014, 607, 294-301.
