Paper Titles

Modelling Grain Boundary Sliding from First Principles
p.11

Multi-Scale Modeling of Nanocrystalline Materials
p.19

Grain Boundary Sliding of Ʃ5(001) Twist Grain Boundary in Aluminium Bicrystal from First-Principles Calculations
p.27

Assessment of Contribution of Intragranular Slip to Grain Boundary Sliding in Bicrystals
p.33

Cooperative Grain Boundary Processes in Superplastic Flow
p.41

Dynamics of Grain Boundary Networks in Superplasticity
p.49

Comparison between 2D and 3D Characterisations of Damage Induced by Superplastic Deformation
p.55

Dynamic Grain Growth in Superplastic and Non-Superplastic Aluminium Alloys
p.61

Cavitation Behaviors in a Tetragonal Zirconia Polycrystal Subjected to Superplastic Deformations Measured by SANS Method
p.67

HomeMaterials Science ForumMaterials Science Forum Vols. 447-448Cooperative Grain Boundary Processes in...

Cooperative Grain Boundary Processes in Superplastic Flow

Article Preview

Abstract:

You might also be interested in these eBooks

Superplasticity in Advanced Materials - ICSAM 2003

Info:

Periodical:

Materials Science Forum (Volumes 447-448)

Pages:

41-48

DOI:

https://doi.org/10.4028/www.scientific.net/MSF.447-448.41

Citation:

Cite this paper

Online since:

February 2004

Authors:

Michael Zelin, Amiya K. Mukherjee

Keywords:

Cooperative Phenomena, Grain Boundary Sliding (GBS), Superplasticity

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

© 2004 Trans Tech Publications Ltd. All Rights Reserved

Share:

Citation:

[1] M.G. Zelin and A.K. Mukherjee: Phil. Mag. Letters, v. 68 (1993), p.201.

[2] M.G. Zelin, M.R. Dunlap, A. Rosen, A.K. Mukherjee: J. Appl. Physics, v. 74 (1993), p.4972.

[3] M.G. Zelin and A.K. Mukherjee: Metall. Trans. v. 26A (1995), p.747.

[4] M.G. Zelin and A.K. Mukherjee: Acta Metallurgica et Materialia, v. 43 (1995), p.2359.

[5] M. G. Zelin and A.K. Mukherjee: Mater. Sci. & Eng., v. A208 (1996), p.210.

[6] M. G. Zelin: Materials Characterization, v. 37 (1996), p.311.

[7] M. G. Zelin and S. Guillard: Mater. Sci. & Tech., v. 5 (1999), p.309.

[8] M.G. Zelin and A.K. Mukherjee: Materials Sci. Forum, v. 357-359 (2001), p.283.

[9] V.V. Astanin, O.A. Kaibyshev, and S.N. Faizova: Scripta Met., v. 25 (1991), p.2663.

[10] V.V. Astanin, O.A. Kaibyshev, and S.N. Faizova: Acta Metals Mater., v. 42 (1994), p.2617.

[11] A. Nadai: Theory of Flow and Fracture of Solids, 2nd ed., (McGraw Hill, New York, 1950).

[12] A.D. Tomlyenov: Metallurgy, Moscow (1972), p.232.

[13] B.L. Adams: Ultramicroscopy, 67 (1997), p.11. 2µm.

[14] J. Pilling and N. Ridley: Superplasticity in Crystalline Solids (Institute of Metals, London, 1989).

[15] J.E. Morral and M.F. Ashby: Acta Metall., v. 22 (1974), p.567.

[16] D.J. Sherwood and C.H. Hamilton: Phil. Mag. A, v. 70 (1994), p.109.

[17] A.I. Pshenichnuk, O.A. Kaibyshev, and V.V. Astanin: Phys. Solid. Bodies, v. 39 (1997), p.2179.

[18] K.A. Padmanbhan and J. Schlipf: Mater. Sci. & Tech., v. 12 (1996), p.391. Acknowledgement This work was supported by NSF DMR Grant #0240144. The EBSP results were provided by Mr. H. Dong, Concurrent Technology Corporation.