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T. Nakano
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Yu-Lung Chiu, Fabienne Grégori, Haruyuki Inui & Patrick Veyssière
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Alain Couret, HectorA. Calderon & Patrick Veyssière. (2003) Intralamellar dislocation networks formed by glide in γ-TiAl I. The mechanism of formation. Philosophical Magazine 83:14, pages 1699-1718.
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Articles from other publishers (11)
Yufeng Wen, Xianshi Zeng, Yuanxiu Ye, Qingdong Gou, Bo Liu, Zhangli Lai, Daguo Jiang, Xinyuan Sun & Minghui Wu. (2022) Theoretical Study on the Structural, Elastic, Electronic and Thermodynamic Properties of Long-Period Superstructures h- and r-Al2Ti under High Pressure. Materials 15:12, pages 4236.
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Z. Zhen, H. Wang, C.Y. Teng, C.G. Bai, D.S. Xu & R. Yang. (2021) Dislocation self-interaction in TiAl: Evolution of super-dislocation dipoles revealed by atomistic simulations. Journal of Materials Science & Technology 69, pages 138-147.
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Yan He, Zhao Liu, Gang Zhou, Hao Wang, Chunguang Bai, David Rodney, Fritz Appel, Dongsheng Xu & Rui Yang. (2018) Dislocation dipole-induced strengthening in intermetallic TiAl. Scripta Materialia 143, pages 98-102.
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R. Porizek, S. Znam, D. Nguyen-Manh, V. Vitek & D. G. Pettifor. (2011) Atomistic Studies of Dislocation Glide in γ-TiAl. MRS Proceedings 753.
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Patrick Veyssière, Yu-Lung Chiu & Fabienne Grégori. (2011) Micromechanisms of deformation in γ-TiAl. MRS Proceedings 753.
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Fabienne Grégori & Patrick Veyssière. (2001) A microstructural analysis of Al-rich γ-TiAl deformed by 〈0 1 1] dislocations. Materials Science and Engineering: A 309-310, pages 87-91.
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Fabienne Grégori & Patrick Veyssière. (2011) The generation of faulted dipoles and dislocation activity in γ-TiAl. MRS Proceedings 646.
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