[1] Alencar, G.; de Jesus, A.; da Silva, J.G.S.; Calcada, R. Fatigue cracking of welded railway bridges: A review. Eng. Fail. Anal. 2019, 104, 154–176.
[2] Alencar, G.; de Jesus, A.; da Silva, J.G.S.; Calçada, R. A finite element post-processor for fatigue assessment of welded structures, based on the Master SN curve method. Int. J. Fatigue 2021, 153, 106482.
[3] Beck T, Pitz G, Lang K H, Lahe D, Thermal-mechanical and isothermal fatigue of IN 792 CC, Mater. Sci. Eng. A 234–236 (1997) 719–722
[4] Cheng C F, Cheng C Y, Diercks D R, Weeks R W, Low cycle fatigue behaviour of types 304 and 316 stainless steel at LMFBR operating temperature, in: A.E. Carden, A.J. McEvily, C.H. Wells (Eds.), Fatigue at Elevated Temperatures, ASTM STP 520, American Society for Testing and Materials, Philadelphia, 1973, pp. 355–364.
[5] Fekete B, Kasl J, Jandova D, Joni B, Misjak F, Trampus P, Low cycle thermomechanical fatigue of reactor steels: microstructural and fractographic investigations, Mater. Sci. Eng. A 640 (2015) 357–374.
[6] IAEA-TECDOC-742, 2019, “Design basis and design features of WWER-440 model213nuclear power plants. Reference plant: Bohunice V2 (Slovakia)”.
[7] Jaske C E, Thermal-mechanical, low cycle fatigue of AISI 1010 Steel, in: D. A. Spera, D.F. Mowbray (Eds.), Thermal Fatigue of Materials and Components, ASTM STP 612, American Society for Testing and Materials, Philadelphia, 1976, pp. 170–198.
[8] Liu, N.; Xiao, J.; Cui, X.; Liu, P.; Lua, J. A continuum damage mechanics (Cdm) modeling approach for prediction of fatigue failure of metallic bolted joints. In AIAA Scitech 2019 Forum; Aerospace Research Central: Reston, VA, USA, 2019; pp. 1–11.
[9] Luo, P.; Yao, W.; Li, P. A notch critical plane approach of multiaxial fatigue life prediction for metallic notched specimens. Fatigue Fract. Eng. Mater. Struct. 2019, 42, 854–870.
[10] Nagesha A, Kannan R, Parameswaran P, Sandhya R,. Bhanu Sankara Rao K, Vakil Singh, A comparative study of isothermal and thermomechanical fatigue on type 316 LN austenitic stainless steel, Mater. Sci. Eng. A 527 (2010) 5969–5975.
[11] Okazaki M, Take K. Kakeshi K, Yamazaki Y, Sakane M, Arai M, S. Sakurai S, Kaneko H, Harada Y, Sugita Y, Okuda T, Nonaka I Fujiyama K, Nanba K, Collaborative research on the thermomechanical and isothermal low cycle fatigue strength of Ni-base super alloys and protective coatings at elevated temperatures, in: McGaw M A, Kalluri S, Bressers J, Peteves (Eds.) S D, Thermo-mechanical Fatigue Behaviour of Materials, ASTM STP 1428, American Society for Testing and Materials, Philadelphia, 2003, pp. 180–194.
[12] Pang, J.C.; Li, S.X.; Wang, Z.G.; Zhang, Z.F. General relation between tensile strength and fatigue strength of metallic materials. Mater. Sci. Eng. A 2013, 564, 331–341.
[13] Rosatom launches annealing technology for VVER-1000 units". World Nuclear News. 27 November 2018. Retrieved 28 November, 2018.
[14] Suresh Kumar T, Nagesha A, Kannan R, Thermal cycling effects on the creep-fatigue interaction in type 316 LN austenitic stainless steel weld joint, Int. J. Press. Vessel. Pip. (2019), https://doi.org/10.1016/j.ijpvp.2019.104009.
[15] Suresh Kumar T, Nagesha A, Sandhya R, Prakash R, Suresh Kumar R, Nagesha A, G. Sasikala G, A. Bhaduri (Eds.) A, Structural Integrity Assessment, Lecture Notes in Mechanical Engineering, Springer, Singapore, 2019, pp. 377–386.
[16] Trampus, P. A reaktortartály üzemi kérdései. 2013. in: Csom Gyula (ed.): Atomerőművek üzemtana II.4: Az energetikai atomreaktorok üzemtana. Budapest: Pauker Holding
[17] Ye, X.W.; Su, Y.H.; Jin, T.; Chen, B.; Han, J.P. Master S-N Curve-Based Fatigue Life Assessment of Steel Bridges Using Finite Element Model and Field Monitoring Data. Int. J. Struct. Stab. Dyn. 2019, 19, 1940013.