Journal of Material & Metallurgical Engineering

Metal working processes of warm working require an advanced quantitative analysis of dynamic and static recovery of dislocations to control microstructures and crucial shape forming properties. Feasibility of dynamic recovery by thermal glide and static recovery by climb of constricted jogs, applicable to ausforming, nano bulk forming by SPD and normalizing has been addressed to design new steels, used for hulls and tribologically superior bearings. Predictive dislocation recovery analysis shows Taylor factor as an important dynamic recovery controller for mean dislocation dynamics and crystallographic orientation dependent dislocation dynamics, to govern work hardening and recovery strain rate of materials. Taylor factor has been defined as glide plane specific stacking fault energy. In contrast to static recovery by climb, present mechanism has found that less stacking fault energy will have enhanced dynamic recovery kinetics. Predicted recovery kinetics has been qualitatively validated by frequency of low angle boundaries, formed during ausforming and normalizing, in regard to Taylor factors of crystallographic orientations of retained austenite, detected by EBSD. 

Humphreys FJ, Hatherly M (2004) Recrystallization and related annealing phenomena, Elsevier, Oxford.

Kubin L, Hoc T, Devincre B (2009) Dynamic recovery and its orientation dependence in face-centered cubic crystals, Acta Mater. 57: 2567-2575.

Bacroix B, Brenner R (2012) A phenomenological anisotropic description for dislocation storage and recovery processes in fcc crystals, Comp Mater. Sci. 54: 97-100.

Dieter G (1988) Mechanical metallurgy. SI Metric Ed. McGraw-Hill, London.

M. Crumbach M, G. Gottstein G (2004) Analysis of the activity of {110}〈110〉 slip in AA3103 by inverse modeling, Mater. Sci. Engg. A. 387-389: 282-287.

He J, Zhao A, Zhi C, Fan H (2015) Acceleration of nanobainite transformation by multi-step ausforming process, Scripta Mater. 107: 71–74.

Hirth JP, Lothe J (1982) Theory of dislocations 2nd Ed. John Wiley & Sons, New York.

Hull D, Bacon DJ (2011) Introduction to dislocations 5th Ed. Elsevier, London.

Radhakrishnan B, Sarma GB (2008) Coupled simulations of texture evolution during deformation and recrystallization of fcc and bcc metals, Mater. Sci. Engg. A. 494: 73-79.

Umezawa A, Inagaki H (2006), Development of cube recrystallization textures in high-purity Al, Z. Metllkd. 97: 49-58.

Baudin T, Julliard F, Paillard P, Penelle R (2000) Simulation of primary recrystallization from tem orientation data, Scr. Mater. 43: 63-68.

Vitek V (1975) Stacking faults on {111} and {110} planes in aluminium, Scr. Metall. 9: 611-615.

Koch CC (2003) Ductility in nanostructured and ultra fine grained materials: recent evidence for optimism, J. Metastable Nanocryst. Mater. 18: 9-20.

Chung CS, Kim JK, Kim HK, Kim WJ (2002) Improvement of high-cycle fatigue life in a 6061 Al alloy produced by equal channel angular pressing, Mater. Sci. Engg. A 337: 39-44.

Tanimoto H, Sakai S, Mizubayashi H (1999), Mechanical property of high density nanocrystalline gold prepared by gas deposition method, Nanostruct. Mater. 12: 751-756.

Meyers MA, Mishra A, Benson DJ (2006) Mechanical properties of nanocrystalline materials, Prog. Mater. Sci. 51: 427-556.

Kumar KS, Swygenhoven HV, Suresh S (2003) Mechanical behavior of nanocrystalline metals and alloys, Acta Mater. 51: 5743-5774.

Swygenhoven HV, Caro A (1997) Plastic behavior of nanophase Ni: A molecular dynamics computer simulation, Appl. Phys. Lett. 71: 1652-1654.

Swygenhoven HV, Derlet PM (2001) Grain-boundary sliding in nanocrystalline fcc metals, Phys. Rev. B 64 224105: 1-9.

Asaro RJ, Krysl P, Kad B (2003) Deformation mechanism transitions in nanoscale fcc metals Phil. Mag. 83: 733-743.

Liao XZ, Srinivasan SG, Zhao YH, Baskes MI, Zhu YT, Zhou F, Lavernia EJ, Xu HF (2004) Formation mechanism of wide stacking faults in nanocrystalline Al, Appl. Phys. Lett. 84: 3564-3566.

Iwahashi Y, Wang JT, Horita Z, Nemoto M, Langdon TG (1996) Principle of equal-channel angular pressing for the processing of ultra-fine grained materials, Scr. Mater. 35: 143-146.

Valiev RZ, Alexandrov IV (1999) Nanostructured materials from severe plastic deformation, Nanostruct. Mater. 12: 35-40.