Refereed journal articles

1. P Thamburaja and L Anand (2001). Polycrystalline shape-memory alloys: Effect of crystallographic texture. Journal of the Mechanics and Physics of Solids 49, 709-737. (ISI Q1) [link] 

2. P Thamburaja and L Anand (2002). Superelastic behavior in tension-torsion of an initially-textured Ti-Ni shape-memory alloy. International Journal of Plasticity 18, 1607-1617. (ISI Q1) [link] 

3. P Thamburaja and L Anand (2003). Thermo-mechanically coupled superelastic response of initially-textured Ti-Ni sheet. Acta Materialia 51, 325-338. (ISI Q1) [link] 

4. P Thamburaja (2005). Constitutive equations for martensitic reorientation and detwinning in shape-memory alloys. Journal of the Mechanics and Physics of Solids 53, 825-856. (ISI Q1) [link] 

5. P Thamburaja, H Pan and FS Chau (2005). Martensitic reorientation and shape-memory effect in initially-textured polycrystalline Ti-Ni sheet. Acta Materialia 53, 3821-3831. (ISI Q1) [link] 

6. H Pan, P Thamburaja and FS Chau (2007). Multi-axial behavior of shape-memory alloys undergoing martensitic reorientation and detwinning. International Journal of Plasticity 23, 711-732. (ISI Q1) [link] 

7. P Thamburaja and R Ekambaram (2007). Coupled thermo-mechanical modelling of bulk-metallic glasses: Theory, finite-element simulations and experimental verification. Journal of the Mechanics and Physics of Solids 55, 1236-1273. (ISI Q1) [link] 

8. H Pan, P Thamburaja and FS Chau (2007). An isotropic-plasticity-based constitutive model for martensitic reorientation and shape-memory effect in shape-memory alloys. International Journal of Solids and Structures 44, 7688-7712. (ISI Q1) [link] 

9. R Ekambaram, P Thamburaja and N Nikabdullah (2008). On the evolution of free volume during the deformation of metallic glasses at high homologous temperatures. Mechanics of Materials 40, 487-506. (ISI Q1) [link] 

10. P Thamburaja and N Nikabdullah (2009). A macroscopic constitutive model for shape-memory alloys: Theory and finite-element simulations. Computer Methods in Applied Mechanics and Engineering 198, 1074-1086. (ISI Q1) [link] 

11. P Thamburaja, H Pan and FS Chau (2009). The evolution of microstructure during twinning: Constitutive equations, finite-element simulations and experimental verification. International Journal of Plasticity 25, 2141-2168. (ISI Q1) [link] 

12. R Ekambaram, P Thamburaja, H Yang, Y Li and N Nikabdullah (2010). The multi-axial deformation behavior of bulk-metallic glasses at high homologous temperatures. International Journal of Solids and Structures 47, 678-690.  (ISI Q1) [link] 

13. P Thamburaja (2010). A finite-deformation-based phenomenological theory for shape-memory alloys. International Journal of Plasticity 26, 1195-1219. (ISI Q1) [link] 

14. R Ekambaram, P Thamburaja and N Nikabdullah (2009). Shear localization and damage in metallic glasses at high homologous temperatures. International Journal of Structural Changes in Solids 1, 15-29. (Inaugural issue) [link] 

15. P Thamburaja (2011). Length scale effects on the shear localization process in metallic glasses: A theoretical and computational study. Journal of the Mechanics and Physics of Solids 59, 1552-1575. (ISI Q1) [link] 

16. P Thamburaja and N Nikabdullah (2011). The transition from homogeneous flow to fracture in metallic glasses at high-homologous temperatures. Scripta Materialia 65, 751-754. (ISI Q1) [link] 

17. P Thamburaja and M Jamshidian (2014). A multiscale Taylor model-based constitutive theory describing grain growth in polycrystalline cubic metals. Journal of the Mechanics and Physics of Solids 63, 1-28. (ISI Q1) [link] 

18. K Marandi, P Thamburaja and VPW Shim (2014). Constitutive description of bulk metallic glass composites at high homologous temperatures. Mechanics of Materials 75, 151-164. (ISI Q1) [link] 

19. P Thamburaja and J Liu (2014). Effects of microscopic boundary conditions on the deformation behavior of small-volume metallic glasses. International Journal of Solids and Structures 51, 4580-4595. (ISI Q1) [link] 

20. P Thamburaja, B Klusemann, S Adibi and S Bargmann (2015). The plastic yield and flow behavior in metallic glasses. Applied Physics Letters 106, 051903. (ISI Q1) [link] 

21. M Jamshidian, P Thamburaja and T Rabczuk (2015). A continuum state variable theory to model size-dependent surface energy of nanostructures. Physical Chemistry Chemical Physics 17, 25494-25498. (ISI Q1) [link] 

22. M Jamshidian, P Thamburaja and T Rabczuk (2016). Modeling the effect of surface energy on stressed grain growth in cubic polycrystalline bodies. Scripta Materialia 113, 209-213. (ISI Q1) [link] 

23. M Jamshidian, P Thamburaja and T Rabczuk (2016). A multiscale coupled finite-element and phase-field framework to modeling stressed grain growth in polycrystalline thin films. Journal of Computational Physics 327, 779-798. (ISI Q1) [link] 

24. AH Sakhaei and P Thamburaja (2017). A finite-deformation-based constitutive model for high-temperature shape-memory alloys. Mechanics of Materials 109, 114-134. (ISI Q1) [link] 

25. R Idris, S Abdullah, P Thamburaja and MZ Omar (2017). Evaluation of fatigue crack growth rate for iron-carbon metals based on degradation-entropy generation theorem. Journal of Fundamental and Applied Sciences 9(5s), 526-541. [link] 

26. T Dutta, A Chauniyal, I Singh, R Narasimhan, P Thamburaja and U Ramamurty (2018). Plastic deformation and failure mechanisms in nano-scale notched metallic glass specimens under tensile loading. Journal of the Mechanics and Physics of Solids 111, 393-413. (ISI Q1) [link] 

27. R Idris, S Abdullah, P Thamburaja, MZ Omar (2018). The need to generate entropy characteristics for fatigue life prediction in low carbon steel. Journal of the Brazilian Society of Mechanical Sciences and Engineering 40, 409. (ISI Q3) [link] 

28. R Idris, S Abdullah, P Thamburaja, MZ Omar (2018). An experimental investigation of tensile properties and fatigue crack growth behavior for dual-phase steel. Journal of Mechanical Engineering 15, 155-167. [link] 

29. R Idris, S Abdullah, P Thamburaja, MZ Omar (2018). Entropy-based approach for fatigue crack growth rate of dual-phase steel. International Journal of Integrated Engineering 10, 1-7. [link] 

30. F Mozafari, P Thamburaja, A Srinivasa and N Moslemi (2019). A rate independent inelasticity model with smooth transition for unifying low-cycle to high-cycle fatigue life prediction. International Journal of Mechanical Sciences 159, 325-335. (ISI Q1) [link] 

31. P Thamburaja, K Sarah, A Srinivasa and JN Reddy (2019). Fracture of viscoelastic materials: FEM implementation of a non-local & rate form-based finite-deformation constitutive theory. Computer Methods in Applied Mechanics and Engineering 354, 871-903. (ISI Q1) [link] 

32. R Idris, S Abdullah, P Thamburaja and MZ Omar (2020). Prediction of fatigue crack growth rate based on entropy generation. Entropy 22, 9. (ISI Q2) [link] 

33. F Mozafari, P Thamburaja, A Srinivasa and S Abdullah (2020). Fatigue life prediction under variable amplitude loading using a microplasticity-based constitutive model. International Journal of Fatigue 134, 105477. (ISI Q1) [link] 

34. K Sarah, P Thamburaja, A Srinivasa and JN Reddy (2020). Numerical simulations of damage & fracture in viscoelastic solids using a non-local fracture criterion. Mechanics of Advanced Materials and Structures 27, 1085-1097. (ISI Q1) [link] 

35. S Deka, P Thamburaja and A Mallick (2021). Thermal stresses in a functionally graded rotating disk: an approximate closed form solution. Journal of Thermal Stresses 40, 20-50. (ISI Q2) [link] 

36. F Mozafari, P Thamburaja, N Moslemi and A Srinivasa (2021). Finite-element simulation of multi-axial fatigue loading in metals based on a novel experimentally-validated microplastic hysteresis-tracking method. Finite Elements in Analysis and Design 187, 103481. (ISI Q1) [link] 

37. A Srinivasa, HY Shin, P Thamburaja and JN Reddy (2021). Multiple cracking model in a 3D GraFEA framework. Continuum Mechanics and Thermodynamics 33, 1409-1428. (ISI Q1) [link] 

38. R Idris, S Abdullah, P Thamburaja and MZ Omar (2021). Temperature evolution of dual-phase- steel in predicting fatigue crack growth rate under block spectrum loading. International Journal of Fracture 228, 145-158. (ISI Q2) [link] 

39. P Thamburaja, K Sarah, A Srinivasa and JN Reddy (2021). Fracture modeling of plain concrete using nonlocal fracture mechanics and a graph-based computational framework. Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences 477, 20210398. (ISI Q2) [link]

40. HY Shin, P Thamburaja, A Srinivasa and JN Reddy (2022). On simulating impact fracture in high-strength concrete using GraFEA. Extreme Mechanics Letters 52, 101618. (ISI Q1) [link]

41. HY Shin, C Lawrence, K Raj Kota,  P Thamburaja, A Srinivasa, TE Lacy Jr. and JN Reddy (2022). Experimental, theoretical & numerical studies on plain concrete fracture in the low-strain rate regime - A state-of-the-art review.  Mechanics of Advanced Materials and Structures 29, 7115-7159. (ISI Q1) [link]

42.  HY Shin, P Thamburaja, A Srinivasa and JN Reddy (2023). Modeling impact fracture in a quasi-brittle solid using a 3D non-local graph-based finite element analysis: Theory, finite element simulations and experimental verification. Journal of the Mechanics and Physics of Solids 170, 105097. (ISI Q1) [link]

43. R Alebrahim, P Thamburaja, A Srinivasa and JN Reddy (2023). A robust Moore-Penrose pseudoinverse-based static finite-element solver for simulating non-local fracture in solids. Computer Methods in Applied Mechanics and Engineering 403, 115727. (ISI Q1) [link]

44. K Sarah and  P Thamburaja (2023). Efficient neighbor search algorithm for nonlocal-based simulations: Application to failure mechanics. Journal of Failure Analysis and Prevention 23, 540-547. [link]

45. AE Roslee, NAN Mohamed, P Thamburaja and J Rajan (2023). A generalized thermophysical model for materials from molecular clusters to bulk crystals. Physica B: Condensed Matter 659, 414877. (ISI Q3) [link] 

46.  S Deka, F Mozafari, A Mallick, P Thamburaja and M Gupta (2023). Development of high-performance nanostructured aluminum and its constitutive modeling. Mechanics of Advanved Materials and Structures. Accepted.  DOI:10.1080/15376494.2023.2262733. [link]

47. SH Moghtaderi, A Jedi, AK Ariffin and P Thamburaja (2024) Application of machine learning in fracture analysis of edge crack semi-infinite elastic plate. Frattura ed Integrita Strutturale 18, 197-208. [link]

48. C Lawrence, P Thamburaja, A Srinivasa JN Reddy and TE Lacy Jr. (2024) Determination of total crack free surface area creation and failure in quasi-brittle microcracking solids using 2D GraFEA simulations. Mechanics of Materials 191, 104946. (ISI Q1) [link]

Refereed conference proceedings

• B Zhao, AAO Tay, P Thamburaja (2006). A hybrid equivalent-layer model for analysis of solder joint reliability of ultra-fine pitch packages. Proceedings of the 8th Electronics Packaging Technology Conference 8, 220-226.

• H Pan, P Thamburaja and FS Chau (2007). Variant reorientation in single-crystal shape-memory alloys. Australasian Congress on Applied Mechanics 5, 652-658. [link]

• P Thamburaja and N Nikabdullah (2008). A coupled thermo-mechanical theory for polycrystalline SMAs. American Institute of Physics Workshop on Smart Devices: Modeling of Material Systems 1029, 27-49. [link]

• AH Sakhaei, KM Lim and P Thamburaja (2013). A link between the phenomenological and physical modelling of transformation-induced plasticity. Proceedings of the 12th International Conference on Computational Plasticity-Fundamentals and Applications, COMPLAS 2013, 1403-1414. [link]

Reports

• P Thamburaja, S Gao, Y Sung and L Anand (2002). Anisotropic superelasticity of textured Ti-Ni sheet. Advanced Materials for Micro- and Nano-Systems: Singapore-MIT Alliance.

Book chapters

• L Anand and P Thamburaja (2003). Superelasticity of shape-memory materials. IUTAM Symposium on Solid Mechanics of Solid Materials at Large Strains 118, 103-114. Editor: Christian Miehe. Publisher: Springer. 

Thesis

• P Thamburaja (2000). Shape-memory materials: Crystallographic texture and its consequences. SM Thesis. Advisor: Prof. Lallit Anand.

• P Thamburaja (2002). Constitutive equations for superelasticity in crystalline shape-memory materials. PhD Thesis. Advisor: Prof. Lallit Anand.

Citation analysis & information

• ResearcherID webpage: [link]

Invited presentations

• European Congress on Advanced Materials and Processes (2005). Prague, Czech Republic.

• World Conference on Computational Mechanics (2006). Los Angeles, U.S. Keynote.

• International Conference on Plasticity and its Applications (2007).  Anchorage, U.S.

• 5th Australasian Congress on Applied Mechanics (2007). Brisbane, Australia.

• International Workshop on Smart Devices - Modeling of Material Systems (2008). Chennai, India.

• The 13th International Conference on Applied Mechanics and Mechanical Engineering (2008). Cairo, Egypt.

• International Conference on Plasticity and its Applications (2009). St. Thomas, U.S. Virgin Islands.

• Special Workshop on Shape Memory Alloys (2010).  Istanbul, Turkey.

• Special Workshop on Recent Advances in Mechanics (2010). Chennai, India.

• International Conference on Plasticity and its Applications (2011).  Puerto Vallarta, Mexico. Keynote.

• International Conference on Computational and Experimental Engineering and Sciences (2011). Nanjing, China.

• The 2nd International Conference on Material Modelling (2011). Paris, France.

• The 11th US National Congress on Computational Mechanics (2011). Minneapolis, U.S.

• The International Symposium on Robotics and Intelligent Systems (2012). Kuching, Malaysia. Keynote.

• Institute of Continuum and Materials Mechanics, Technical University of Hamburg-Harburg (2013). Germany. Special Invitation.

• Department of Engineering Design, Indian Institute of Technology, Madras (2014). India. Special Invitation.

• Faculty of Engineering, Monash Malaysia University (2014). Bandar Sunway, Malaysia. Special Invitation.

• SES Conference, Texas A&M University (2015). College Station, Texas, U.S.