Phase Transformation Induced Plastic Deformation Mechanism in α2-Ti3Al

Linfeng Qiu , Shiping Wang , Xiong Zhou , Zhongtao Lu , Xiege Huang , Xiaobin Feng , Bo Duan , Wenjuan Li , Pengcheng Zhai , Guodong Li , Yang Chen , Zhixiang Qi , Guang Chen

Interdisciplinary Materials ›› 2025, Vol. 4 ›› Issue (3) : 524 -534.

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Interdisciplinary Materials ›› 2025, Vol. 4 ›› Issue (3) : 524 -534. DOI: 10.1002/idm2.12246
RESEARCH ARTICLE

Phase Transformation Induced Plastic Deformation Mechanism in α2-Ti3Al

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Abstract

TiAl plays a crucial role in the field of aero-engine as a new lightweight high-temperature alloy. The γ/α2 lamellar TiAl single crystals exhibit the highest recorded plasticity, much higher than the soft phase γ-TiAl. This suggests that the hard phase α2-Ti3Al may have a unique plastic deformation mechanism, which is important for essentially understanding the origin of unusual plasticity and further improving the mechanical properties of TiAl. Here, we found the dynamic sequential phase transformation between HCP and FCC under shear loading in α2-Ti3Al, which is a novel plastic deformation mechanism comparable to twinning. We attribute this to the bond-breaking formation process called “catching bond”, which is the origin of atomic mechanism of phase transformation occurrence. This “catching bond” process is an effective way of energy dissipation that can release the internal stress while maintaining the integrity of structure. The higher cleavage energy than the generalized stacking fault energy (GSFE) guarantees the continuity of phase transformation during shearing. Moreover, the γ/α2 coherent interface can reduce the GSFE, thus decreasing the critical resolved shear stress (CRSS) of the phase transformation by 35%, which suggests that the phase transformation induced plastic mechanism easily occurs in the lamellar structure. This study reveals the plastic deformation mechanism of α2-Ti3Al and explores the role of γ/α2 coherent interface on the plasticity, which is expected to provide guidance for further improving the mechanical properties of TiAl alloys.

Keywords

α2-Ti3Al / coherent interface / phase transformation / plasticity

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Linfeng Qiu, Shiping Wang, Xiong Zhou, Zhongtao Lu, Xiege Huang, Xiaobin Feng, Bo Duan, Wenjuan Li, Pengcheng Zhai, Guodong Li, Yang Chen, Zhixiang Qi, Guang Chen. Phase Transformation Induced Plastic Deformation Mechanism in α2-Ti3Al. Interdisciplinary Materials, 2025, 4(3): 524-534 DOI:10.1002/idm2.12246

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References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]

Q. Zeng and X. Chen, “Combustor Technology of High Temperature Rise for Aero Engine,” Progress in Aerospace Sciences 140 (2023): 100927.
[2]

N. P. Padture, “Advanced Structural Ceramics in Aerospace Propulsion,” Nature Materials 15, no. 8 (2016): 804-809.
[3]

J. A. Lemberg and R. O. Ritchie, “Mo-Si-B Alloys for Ultrahigh-Temperature Structural Applications,” Advanced Materials 24, no. 26 (2012): 3445-3480.
[4]

A. Gloria, R. Montanari, M. Richetta, and A. Varone, “Alloys for Aeronautic Applications: State of the Art and Perspectives,” Metals 9, no. 6 (2019): 662.
[5]

T. M. Pollock and S. Tin, “Nickel-Based Superalloys for Advanced Turbine Engines: Chemistry, Microstructure and Properties,” Journal of Propulsion and Power 22, no. 2 (2006): 361-374.
[6]

E. S. Huron, “Serrated Yielding in a Nickel-Base Superalloy,” Superalloys 1992 (1992): 675-684.
[7]

T. M. Pollock, “Alloy Design for Aircraft Engines,” Nature Materials 15, no. 8 (2016): 809-815.
[8]

G. Gudivada and A. K. Pandey, “Recent Developments in Nickel-Based Superalloys for Gas Turbine Applications: Review,” Journal of Alloys and Compounds 963 (2023): 171128.
[9]

R. Schafrik and R. Sprague, “Superalloy Technology—A Perspective on Critical Innovations for Turbine Engines,” Key Engineering Materials 380 (2008): 113-134.
[10]

Z. Wang, G. Zheng, Z. Qi, et al., “Structures, Microstructures, Properties, and Applications of TiAl Alloys,” Chinese Science Bulletin 68, no. 25 (2023): 3259-3274.
[11]

X. Zhang, Y. Chen, and J. Hu, “Recent Advances in the Development of Aerospace Materials,” Progress in Aerospace Sciences 97 (2018): 22-34.
[12]

A. K. Gogia, “High-Temperature Titanium Alloys,” Defence Science Journal 55, no. 2 (2005): 149-173.
[13]

G. Chen, Y. Peng, G. Zheng, et al., “Polysynthetic Twinned TiAl Single Crystals for High-Temperature Applications,” Nature Materials 15, no. 8 (2016): 876-881.
[14]

W. Wang, W. Zeng, Y. Liu, G. Xie, and X. Liang, “Microstructural Evolution and Mechanical Properties of Ti-22Al-25Nb (At.%) Orthorhombic Alloy With Three Typical Microstructures,” Journal of Materials Engineering and Performance 27, no. 1 (2018): 293-303.
[15]

Q. Wang, H. Ding, H. Zhang, R. Chen, J. Guo, and H. Fu, “Variations of Microstructure and Tensile Property of γ-TiAl Alloys With 0-0.5at% C Additives,” Materials Science and Engineering: A 700 (2017): 198-208.
[16]

L. Song, F. Appel, L. Wang, et al., “New Insights Into High-Temperature Deformation and Phase Transformation Mechanisms of Lamellar Structures in High Nb-Containing TiAl Alloys,” Acta Materialia 186 (2020): 575-586.
[17]

A. Lasalmonie, “Intermetallics: Why Is it so Difficult to Introduce Them in Gas Turbine Engines?,” Intermetallics 14, no. 10-11 (2006): 1123-1129.
[18]

M. H. Yoo, C. L. Fu, and J. K. Lee, “Deformation Twinning in Metals and Ordered Intermetallics-Ti and Ti-Aluminides,” Journal de Physique III 1 (1991): 1065-1084.
[19]

F. Appel, J. D. H. Paul, and M. Oehring, Gamma Titanium Aluminide Alloys: Science and Technology. Weinheim (Wiley-VCH, 2011).
[20]

D. M. Heyes, “Pressure Tensor of Partial-Charge and Point-Dipole Lattices With Bulk and Surface Geometries,” Physical Review B 49, no. 2 (1994): 755-764.
[21]

S. Plimpton, “Fast Parallel Algorithms for Short-Range Molecular Dynamics,” Journal of Computational Physics 117, no. 1 (1995): 1-19.
[22]

R. R. Zope and Y. Mishin, “Interatomic Potentials for Atomistic Simulations of the Ti-Al System,” Physical Review B 68, no. 2 (2003): 024102.
[23]

A. Neogi and R. Janisch, “Twin-Boundary Assisted Crack Tip Plasticity and Toughening in Lamellar γ-TiAl,” Acta Materialia 213 (2021): 116924.
[24]

H. N. Wu, D. S. Xu, H. Wang, and R. Yang, “Molecular Dynamics Simulation of Tensile Deformation and Fracture of γ-TiAl With and Without Surface Defects,” Journal of Materials Science & Technology 32, no. 10 (2016): 1033-1042.
[25]

S. Nosé, “A Unified Formulation of the Constant Temperature Molecular Dynamics Methods,” Journal of Chemical Physics 81, no. 1 (1984): 511-519.
[26]

A. Stukowski, “Visualization and Analysis of Atomistic Simulation Data With OVITO-The Open Visualization Tool,” Modelling and Simulation in Materials Science and Engineering 18 (2010): 015012.
[27]

A. Stukowski and K. Albe, “Extracting Dislocations and Non-Dislocation Crystal Defects From Atomistic Simulation Data,” Modelling and Simulation in Materials Science and Engineering 18, no. 8 (2010): 085001.
[28]

A. Stukowski, V. V. Bulatov, and A. Arsenlis, “Automated Identification and Indexing of Dislocations in Interfaces,” Modelling and Simulation in Materials Science and Engineering 20 (2012): 085007.
[29]

G. Kresse and J. Furthmüller, “Efficient Iterative Schemes for Ab Initio Total-Energy Calculations Using a Plane-Wave Basis Set,” Physical Review B 54, no. 16 (1996): 11169-11186.
[30]

J. P. Perdew, K. Burke, and M. Ernzerhof, “Generalized Gradient Approximation Made Simple,” Physical Review Letters 77, no. 18 (1996): 3865-3868.
[31]

H. J. Monkhorst and J. D. Pack, “Special Points for Brillouin-Zone Integrations,” Physical Review B 13, no. 12 (1976): 5188-5192.
[32]

Y. L. Liu, L. M. Liu, S. Q. Wang, and H. Q. Ye, “First-Principles Study of Shear Deformation in TiAl and Ti3Al,” Intermetallics 15, no. 3 (2007): 428-435.
[33]

L. Zhang, W. Mao, M. Liu, and Y. Shibuta, “Mechanical Response and Plastic Deformation of Coherent Twin Boundary With Perfect and Defective Structures,” Mechanics of Materials 141 (2020): 103266.
[34]

T. Fu, H. Hu, S. Hu, et al., “Twin Boundary Migration and Reactions With Stacking Fault Tetrahedron in Cu and Cocrcufeni High-Entropy Alloy,” Journal of Materials Research and Technology 17 (2022): 282-292.
[35]

D. Xu, H. Wang, R. Yang, and P. Veyssière, “Molecular Dynamics Investigation of Deformation Twinning in γ-TiAl Sheared Along the Pseudo-Twinning Direction,” Acta Materialia 56, no. 5 (2008): 1065-1074.
[36]

M. Kanani, A. Hartmaier, and R. Janisch, “Stacking Fault Based Analysis of Shear Mechanisms at Interfaces in Lamellar TiAl Alloys,” Acta Materialia 106 (2016): 208-218.
[37]

G. Li, S. I. Morozov, Q. Zhang, Q. An, P. Zhai, and G. J. Snyder, “Enhanced Strength Through Nanotwinning in the Thermoelectric Semiconductor InSb,” Physical Review Letters 119, no. 21 (2017): 215503.
[38]

Z. Lu, B. Huang, G. Li, et al., “Shear Induced Deformation Twinning Evolution in Thermoelectric InSb,” npj Computational Materials 7, no. 1 (2021): 111.
[39]

M. Huang, P. Zhai, G. Li, et al., “Nanotwin-Induced Ductile Mechanism in Thermoelectric Semiconductor PbTe,” Matter 5, no. 6 (2022): 1839-1852.
[40]

H. Ma, X. Huang, Z. Lu, et al., “Origin of Shear Induced ‘Catching Bonds’ on Half Heusler Thermoelectric Compounds XFeSb (X = Nb, Ta) and SnNiY (Y = Ti, Zr, Hf),” npj Computational Materials 10, no. 1 (2024): 61.
[41]

G. Yang and J.-K. Kim, “Hierarchical Precipitates, Sequential Deformation-Induced Phase Transformation, and Enhanced Back Stress Strengthening of the Micro-Alloyed High Entropy Alloy,” Acta Materialia 233 (2022): 117974.
[42]

A. A. Lebedev and V. V. Kosarchuk, “Influence of Phase Transformations on the Mechanical Properties of Austenitic Stainless Steels,” International Journal of Plasticity 16, no. 7 (2000): 749-767.
[43]

L. Huang, W. Lin, Y. Zhang, et al., “Generalized Stability Criterion for Exploiting Optimized Mechanical Properties by a General Correlation Between Phase Transformations and Plastic Deformations,” Acta Materialia 201 (2020): 167-181.
[44]

N. Tsuji, S. Ogata, H. Inui, et al., “Strategy for Managing Both High Strength and Large Ductility in Structural Materials-Sequential Nucleation of Different Deformation Modes Based on a Concept of Plaston,” Scripta Materialia 181 (2020): 35-42.
[45]

A. K. Chandan, P. T. Hung, K. Kishore, M. Kawasaki, J. Chakraborty, and J. Gubicza, “On Prominent TRIP Effect and Non-Basal Slip in a TWIP High Entropy Alloy During High-Pressure Torsion Processing,” Materials Characterization 178 (2021): 111284.
[46]

V. K. Sutrakar and D. R. Mahapatra, “Superplasticity in Intermetallic Nial Nanowires via Atomistic Simulations,” Materials Letters 64, no. 7 (2010): 879-881.
[47]

V. K. Sutrakar and D. Roy Mahapatra, “Asymmetry in Structural and Thermo-Mechanical Behavior of Intermetallic Nial Nanowire Under Tensile/Compressive Loading: A Molecular Dynamics Study,” Intermetallics 18, no. 8 (2010): 1565-1571.
[48]

V. K. Sutrakar and D. R. Mahapatra, “Stress-Induced Martensitic Phase Transformation in Cu-Zr Nanowires,” Materials Letters 63, no. 15 (2009): 1289-1292.
[49]

C. Herrera, D. Ponge, and D. Raabe, “Design of a Novel Mn-Based 1GPa Duplex Stainless Trip Steel With 60% Ductility by a Reduction of Austenite Stability,” Acta Materialia 59, no. 11 (2011): 4653-4664.
[50]

A. Liens, H. Reveron, T. Douillard, et al., “Phase Transformation Induces Plasticity With Negligible Damage in Ceria-Stabilized Zirconia-Based Ceramics,” Acta Materialia 183 (2020): 261-273.
[51]

J. Cho, Q. Li, H. Wang, et al., “High Temperature Deformability of Ductile Flash-Sintered Ceramics via In-Situ Compression,” Nature Communications 9, no. 1 (2018): 2063.
[52]

K. Edalati, S. Toh, Y. Ikoma, and Z. Horita, “Plastic Deformation and Allotropic Phase Transformations in Zirconia Ceramics During High-Pressure Torsion,” Scripta Materialia 65, no. 11 (2011): 974-977.
[53]

R. H. J. Hannink, P. M. Kelly, and B. C. Muddle, “Transformation Toughening in Zirconia-Containing Ceramics,” Journal of the American Ceramic Society 83, no. 3 (2000): 461-487.
[54]

A. G. Evans and A. H. Heuer, “REVIEW—Transformation Toughening in Ceramics: Martensitic Transformations in Crack-Tip Stress Fields,” Journal of the American Ceramic Society 63, no. 5-6 (1980): 241-248.
[55]

L. Wang, J.-X. Shang, F.-H. Wang, and Y. Zhang, “First Principles Study of α2-Ti3Al(0001) Surface and γ-TiAl(111)/α2-Ti3Al(0001) Interfaces,” Applied Surface Science 276 (2013): 198-202.
[56]

X. Li, F.-R. Chen, and Y. Lu, “Ductile Inorganic Semiconductors for Deformable Electronics,” Interdisciplinary Materials 3, no. 6 (2024): 835-846.

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2025 The Author(s). Interdisciplinary Materials published by Wuhan University of Technology and John Wiley & Sons Australia, Ltd.

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