![]() ![]() Sakuma T, Ikuhara Y, Yamamoto T, Yoshida H (2002) Ann Chim Sci Mat 27:S345 Yoshinaga H (1990) Mater Trans JIM 31:233 Tsurekawa S, Tanaka T, Yoshinaga H (1994) Mater Sci Eng A176:341 Academic Press, London, p 43Ĭhou YT, Cai BC, Romig AD, Lin LS (1983) Philos Mag A47:363 Pande CS, Chou YT (1975) In: Herman H (ed) Treatise on materials science and technology. Gleiter H, Chalmers B (1972) Prog Mater Sci 16:1 Raman V, Watanabe T, Langdon TG (1989) Acta Mater 37:705 Kobayashi S, Kamata A, Watanabe T (2009) Scripta Mater 61:1032īirringer R, Herr U, Gleiter H (1986) In: Proceedings of the 4th JIM internal conference on grain boundary structure and related phenomena, Trans JIM 27:43Īust KT, Palumbo G (1989) In: Wilkinson DS (ed) Proceedings of internal symposium on advanced structural materials. Kluwer Academic/Plenum Publishers, New York Schwartz AJ, Kumar M, Adams BL (eds) (2000) Electron back scatter diffraction in materials science. Oxford University Press, OxfordĪdams BL, Wright SI, Kunze K (1993) Met Trans A24:819 Sutton A, Balluffi RW (1995) Interfaces in crystalline materials. McLean D (1957) Grain boundaries in metals. Hirsch PB, Horne RW, Whelan MJ (1957) In: Fisher JC, Johnston WG, Thomson R, Vreeland T (eds) Dislocation and mechanical properties of crystals. AIME, New York, p 37Īmelinckx S (1957) In: Fisher JC, Johnston WG, Thomson R, Vreeland T (eds) Dislocations and mechanical properties of crystals. Read WT, Shockley W (1954) In: Cohen M (ed) Dislocations in metals. Read WT Jr (1953) Dislocation in crystals. Pergamon Press, AmsterdamĪust KT, Chalmers B (1952) Energies and structure of grain boundaries. North Holland Publishing Co., AmsterdamĬahn RW (2001) The coming of materials science, chap 6. In: Cahn RW, Haasen P (eds) Physical metallurgy, 3rd edn, chap 1. Mehl RF (1983) The historical development of physical metallurgy. Watanabe T, Tsurekawa S, Zhao X, Zuo L, Esling C (2006) J Mater Sci 41:7747. Martin JW, Doherty JD, Cantor B (1997) Stability of microstructure in metallic systems, 2nd edn. Ray RK, Murthy VSR, Batra NK, Padmanabhan KA, Ranganathan S (eds) (2001) Materials for the third millennium. Academic Press, New Yorkĭas SK, Keer BH, Adam CM (eds) (1985) Rapidly solidified crystalline alloys. Tien JK, Ansell GS (eds) (1976) Alloy and microstructural design. Hondros ED (1996) In: Proceedings of the Donald McLean symposium on structural materials: engineering application through scientific insight, Institute of Materials Cambridge University Press, p 1, reproduced optical micrograph from Sorby HC (1887) J Iron Steel Inst 1:255 Future prospects of the grain boundary and interface engineering have been outlined, hoping that a new dimension will emerge pertaining to the discovery of new materials and the generation of a new property originating from the presence of grain boundaries and interfaces in advanced polycrystalline materials. Recent advancements based on these concepts clearly demonstrate the high potential and general applicability of grain boundary engineering for various kinds of structural and functional materials. A new approach in terms of the concept of grain boundary and interface engineering is discussed for the design and development of high performance materials with desirable bulk properties. It has been emphasized that the accumulation of fundamental knowledge about the structure and properties of grain boundaries and interfaces has been extensively done by many researchers during the past one century. A brief introduction of the historical background of grain boundary engineering for structural and functional polycrystalline materials is presented herewith. ![]()
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