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Philosophical Magazine A Volume 75, 1997 - Issue 3
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Original Articles

The role of slip and twinning in the deformation behaviour of polysynthetically twinned crystals of TiAl: A micromechanical model

Sabine M. Schlögl Christian Doppler Laboratory for Micromechanics of Materials, University for Mining and Metallurgy Leoben, Franz-Josef-Straβe 18, A-8700, Leoben, Austria
&
Franz D. Fischer Institute of Mechanics, University for Mining and Metallurgy Leoben, Franz-Josef-Straβe 18, A-8700, Leoben, Austria
Pages 621-636 | Received 19 Mar 1996, Accepted 23 Jun 1996, Published online: 20 Aug 2006

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J.E. Butzke & S. Bargmann. (2015) Thermomechanical modelling of polysynthetically twinned TiAl crystals. Philosophical Magazine 95:24, pages 2607-2626.
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Articles from other publishers (45)

Z. Wang, W.H. Wong & T.F. Guo. (2024) Micromechanical analyses on bending of polysynthetically twinned single crystal of titanium aluminide. Journal of the Mechanics and Physics of Solids 187, pages 105608.
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Wei Zhang, Anheng Wang, Jianbin Wang, Qiaoyu Wang, Fan Li & Kuai Lu. (2024) Advances in Fatigue Performance of Metal Materials with Additive Manufacturing Based on Crystal Plasticity: A Comprehensive Review. Materials 17:5, pages 1019.
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Wenjuan Zhao, Hongmin Liao, Yexiong Lun, Shuangqian Zhang & Binna Song. (2022) Role of interfaces in the deformation behavior of lamellar TiAl-based alloys with CPFEM simulation. Materials Today Communications 32, pages 103942.
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Ji Young Kim, Eun Soo Park, Taegu Lee, Seunghwa Ryu, Seung-Eon Kim & Seong-Woong Kim. (2022) Origin of enhanced room temperature ductility in TiAl alloys: Reducing activation difference of deformation mechanism of γ phase. Journal of Alloys and Compounds 899, pages 163307.
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Jan E. Schnabel & Ingo Scheider. (2021) Crystal Plasticity Modeling of Creep in Alloys with Lamellar Microstructures at the Example of Fully Lamellar TiAl. Frontiers in Materials 7.
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Liu Chen, Thomas Edward James Edwards, Fabio Di Gioacchino, William John Clegg, Fionn P.E. Dunne & Minh-Son Pham. (2019) Crystal plasticity analysis of deformation anisotropy of lamellar TiAl alloy: 3D microstructure-based modelling and in-situ micro-compression. International Journal of Plasticity 119, pages 344-360.
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Swantje Bargmann, Benjamin Klusemann, Jürgen Markmann, Jan Eike Schnabel, Konrad Schneider, Celal Soyarslan & Jana Wilmers. (2018) Generation of 3D representative volume elements for heterogeneous materials: A review. Progress in Materials Science 96, pages 322-384.
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Jan Schnabel & Swantje Bargmann. (2017) Accessing Colony Boundary Strengthening of Fully Lamellar TiAl Alloys via Micromechanical Modeling. Materials 10:8, pages 896.
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Svea Mayer, Petra Erdely, Franz Dieter Fischer, David Holec, Michael Kastenhuber, Thomas Klein & Helmut Clemens. (2017) Intermetallic β‐Solidifying γ‐TiAl Based Alloys − From Fundamental Research to Application . Advanced Engineering Materials 19:4.
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F. Appel, H. Clemens & F.D. Fischer. (2016) Modeling concepts for intermetallic titanium aluminides. Progress in Materials Science 81, pages 55-124.
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H.W. Liu, M.F. Xian, J.Y. Huang, G.C. Su, J.W. Liu & L.Z. Ouyang. (2016) Growth morphology and crystallography of precipitate in a new high-temperature structural intermetallic Ti–40Al–10Fe. Intermetallics 69, pages 62-73.
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Fritz Appel, Jonathan David Heaton Paul & Michael Oehring. 2011. Gamma Titanium Aluminide Alloys. Gamma Titanium Aluminide Alloys 125 248 .
C. Zambaldi, F. Roters & D. Raabe. (2011) Analysis of the plastic anisotropy and pre-yielding of (γ/α2)-phase titanium aluminide microstructures by crystal plasticity simulation. Intermetallics 19:6, pages 820-827.
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D. Peter, G.B. Viswanathan, A. Dlouhy & G. Eggeler. (2010) Analysis of local microstructure after shear creep deformation of a fine-grained duplex γ-TiAl alloy. Acta Materialia 58:19, pages 6431-6443.
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Franz Roters, Philip Eisenlohr, Thomas R. Bieler & Dierk Raabe. 2010. Crystal Plasticity Finite Element Methods. Crystal Plasticity Finite Element Methods 173 193 .
F. Roters, P. Eisenlohr, L. Hantcherli, D.D. Tjahjanto, T.R. Bieler & D. Raabe. (2010) Overview of constitutive laws, kinematics, homogenization and multiscale methods in crystal plasticity finite-element modeling: Theory, experiments, applications. Acta Materialia 58:4, pages 1152-1211.
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A. Prakash, S.M. Weygand & H. Riedel. (2009) Modeling the evolution of texture and grain shape in Mg alloy AZ31 using the crystal plasticity finite element method. Computational Materials Science 45:3, pages 744-750.
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Franz Dieter Fischer, Helmut Clemens, Thomas Schaden & Fritz Appel. (2007) Compressive deformation of lamellar microstructures – a short review. International Journal of Materials Research 98:11, pages 1041-1046.
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T. Schaden, F. D. Fischer, H. Clemens, F. Appel & A. Bartels. (2006) Numerical Modelling of Kinking in Lamellar γ‐TiAl Based Alloys. Advanced Engineering Materials 8:11, pages 1109-1113.
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O. Berteaux, M. Jouiad, M. Thomas & G. Hénaff. (2006) Microstructure–low cycle fatigue behaviour relationships in a PM γ-TiAl alloy. Intermetallics 14:10-11, pages 1130-1135.
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M. Werwer & A. Cornec. (2006) The role of superdislocations for modeling plastic deformation of lamellar TiAl. International Journal of Plasticity 22:9, pages 1683-1698.
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Franz Dieter Fischer, Thomas Schaden, Fritz Appel & Helmut Clemens. (2006) Continuum Mechanics of Deformation Twinning – A Review. Multidiscipline Modeling in Materials and Structures 2:2, pages 167-187.
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Alain Couret, Guy Molénat, Jean Galy & Marc Thomas. (2011) Effect of SPS processing temperature on the microstructure and properties of a Ti 49 Al 47 Cr 2 Nb 2 alloy . MRS Proceedings 980.
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A. Roos, J.-L. Chaboche, L. Gélébart & J. Crépin. (2004) Multiscale modelling of titanium aluminides. International Journal of Plasticity 20:4-5, pages 811-830.
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T. Schaden, F. D. Fischer, H. Clemens, F. Appel & A. Bartels. (2011) A Study of the Deformation Behavior of Lamellar γ-TiAl by Numeric Modeling. MRS Proceedings 842.
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H. Petryk, F. D. Fischer, W. Marketz, H. Clemens & F. Appel. (2003) An energy approach to the formation of twins in TiAl. Metallurgical and Materials Transactions A 34:12, pages 2827-2836.
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Robert A. Brockman. (2003) Analysis of elastic-plastic deformation in TiAl polycrystals. International Journal of Plasticity 19:10, pages 1749-1772.
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F.D. Fischer, T. Schaden, F. Appel & H. Clemens. (2003) Mechanical twins, their development and growth. European Journal of Mechanics - A/Solids 22:5, pages 709-726.
Crossref
Jun Yang, Gengkai Hu, Yonggang Zhang & Jilong Su. (2003) An analytical dislocation multiple-pile-up model for the yield stress of fully lamellar TiAl alloys. Modelling and Simulation in Materials Science and Engineering 11:4, pages 627-634.
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G.J Frank, S.E Olson & R.A Brockman. (2003) Numerical models of orthotropic and lamellar grain structures. Intermetallics 11:4, pages 331-340.
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F.D. Fischer, F. Appel & H. Clemens. (2003) A thermodynamical model for the nucleation of mechanical twins in TiAl. Acta Materialia 51:5, pages 1249-1260.
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W.T. Marketz, F.D. Fischer & H. Clemens. (2003) Deformation mechanisms in TiAl intermetallics—experiments and modeling. International Journal of Plasticity 19:3, pages 281-321.
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W.T. Marketz, F.D. Fischer, F. Kauffmann, G. Dehm, T. Bidlingmaier, A. Wanner & H. Clemens. (2002) On the role of twinning during room temperature deformation of γ-TiAl based alloys. Materials Science and Engineering: A 329-331, pages 177-183.
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Dennis M. Dimiduk, Tiplicane A. Parthasarathy & Peter M. Hazzledine. (2001) Design-tool representations of strain compatibility and stress-strain relationships for lamellar gamma titanium aluminides. Intermetallics 9:10-11, pages 875-882.
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Jun Yang, Gengkai Hu & Yonggang Zhang. (2001) Prediction of yield stress for polysynthetically twinned TiAl crystals. Scripta Materialia 45:3, pages 293-299.
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W. T. Marketz, A. Chatterjee, F. D. Fischer & H. Clemens. 2001. IUTAM Symposium on Creep in Structures. IUTAM Symposium on Creep in Structures 17 30 .
M. Werwer & A. Cornec. (2000) Numerical simulation of plastic deformation and fracture in polysynthetically twinned (PST) crystals of TiAl. Computational Materials Science 19:1-4, pages 97-107.
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Alexander V. Idesman, Valery I. Levitas & Erwin Stein. (2000) Structural changes in elastoplastic material. International Journal of Plasticity 16:7-8, pages 893-949.
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F.D. Fischer, G. Reisner, E. Werner, K. Tanaka, G. Cailletaud & T. Antretter. (2000) A new view on transformation induced plasticity (TRIP). International Journal of Plasticity 16:7-8, pages 723-748.
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M. Yamaguchi, H. Inui & K. Ito. (2000) High-temperature structural intermetallics. Acta Materialia 48:1, pages 307-322.
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H.-P. Gänser, F.D. Fischer & E.A. Werner. (1998) Large strain behavior of two-phase materials with random inclusions. Computational Materials Science 11:3, pages 221-226.
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H. Heinrich, V. Abbächerdi, D. J.G. Kostorz. (2011) High-Temperature Deformation of Uniaxially Aligned Lamellar TiAl/Ti3Al. MRS Proceedings 552.
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M.A. Morris, H. Clemens & S.M. Schlög. (1998) Influence of texture on deformed microstructures of rolled TiAl alloys: Simulation versus experimental observations. Intermetallics 6:6, pages 511-521.
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S.M. Schlögl & F.D. Fischer. (1997) Numerical simulation of yield loci for PST crystals of TiAl. Materials Science and Engineering: A 239-240, pages 790-803.
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Ji Young Kim, E. S. Park, Taegu Lee, Seunghwa Ryu, Seung-Eon Kim & Seong-Woong Kim. (2021) Origin of Enhanced Room Temperature Ductility in Tial Alloys: Reducing Activation Difference of Deformation Mechanism of γ Phase. SSRN Electronic Journal.
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