Equal-channel angular pressing (ECAP) was one of severe plastic deformation method in order to increase the mechanical properties of solid metal without changing its dimension and without adding any alloy elements. The change of mechanical properties on ECAPed metals was caused by the change of lattice strain, so that the lattice strain investigation was recommended for evaluating ECAPed metals. In this study, pure titanium rod was treated by ECAP with Bc route and two passes. Before ECAPed, this titanium rod consisted of two lattice strains i.e. 0.001014 and 0.005241. After ECAPed, a lattice strain of 0.005241 reduces to 0.003205 and 0.003555 after first pass and reduces again to 0.002576 and 0.002647 after two passes. Meanwhile, a lattice strain of 0.001014 was annihilated after ECAP treatment. These results show that ECAP treatment can reduce and eliminate lattice strains on titanium rod. This study also shows that the reduction of lattice strains implicates to the increasing of its hardness value.

Kardashev, B. K., Narykova, M. V., Betekhtin, V. I., Kadomtsev, A. G. Evolution of Elastic Properties of Ti and its Alloys due to Severe Plastic Deformation. Physical Mesomechanics. 2020; 23: 193-198. doi: 10.1134/S1029959920030029.

Semenova, I. P., Polyakov, A. V., Raab, G. I., Lowe, T. C., Valiev, R. Z. Enhanced Fatigue Properties of Ultrafine-Grained Ti Rods Processed by ECAP-conform. Journal of Materials Science. 2012; 47: 7777-7781. doi: 10.1007/s10853-012-6675-9.

Manjunath, G. K., Udaya Bhat, K., Preetham Kumar, G. V., Ramesh, M. R. Microstructure and Wear Performance of ECAP Processed Cast Al-Zn-Mg Alloys. Transactions of the Indian Institute of Metals. 2018; 71: 1919-1931. doi: 10.1007/s12666-018-1328-6.

Suryanarayana, C. and Grant Norton, M. 1998. X-ray Diffraction: a Practical Approach. New York, New York: Plenum Press.

Dey, P. C., Das, R. Impact of Silver Doping on the Crystalline Size and Intrinsic Strain of MPA-Capped CdTe Nanocrystals: a Study by Williamson-Hall Method and Size-Strain Plot Method. Journal of Materials Engineering and Performance. 2021. doi: 10.1007/s11665-020-05358-9.

Erdogan, E. X-ray Line Broadening Study on Sputtered InGaN Semiconductor with Evaluation of Williamson-Hall and Size-Strain Plot Methods. Indian Journal of Physics. 2019; 93: 1313-1318. doi: 10.1007/s12648-019-01403-z.

Islam, S. A. U., Ikram, M. Structural Stability Improvement, Williamson Hall Analysis and Band-gap Tailoring through A-site Sr Doping in Rare Earth Based Double Perovskite La2NiMnO6. Rare Metals. 2019; 38: 805-813. doi: 10.1007/s12598-019-01207-4.

Kulkarni, A. B., Mathad, S. N. Synthesis and Structural Analysis of Co-Zn-Cd Ferrite by Williamson-Hall and Size-Strain Plot Methods. International Journal of Self-Propagating High-Temperature Synthesis. 2018; 27: 37-43. doi: 10.3103/S10613862180 1003X.

Madhavi, J. Comparison of Average Crystallite Size by X-ray Peak Broadening and Williamson-Hall and Size-Strain Plots for VO2+ Doped ZnS/CdS Composite Nanopowder. SN Applied Sciences. 2019; 1: 1509. doi: 10.1007/s42452-019-1291-9.

Norouzzadeh, P., Mabhouti, K., Golzan, M. M., Naderali, R. Consequence of Mn and Ni Doping on Structural, Optical and Magnetic Characteristics of ZnO Nanopowders: the Williamson-Hall Method, the Kramers-Kronig Approach and Magnetic Interactions. Applied Physics A. 2020; 126: 154. doi: 10.1007/s00339-020-3335-9.

Pushkarev, S. S., Grekhov, M. M., Zenchenko, N. V. X-ray Diffraction Analysis of Features of the Crystal Structure of GaN/Al0.32Ga0.68N HEMT-Heterostructures by the Williamson-Hall Method. Semiconductors. 2018; 52: 734-738. doi: 10.1134/S1063782618060209.

Kafashan, H. X-ray Diffraction Line Profile Analysis of Undoped and Se-Doped SnS Thin Films Using Scherrer’s, Williamson-Hall and Size-Strain Plot Methods. Journal of Electronic Materials. 2018; 48: 1294-1309. doi: 10.1007/s11664-018-6791-7.

Vajo, J. J., Adjorlolo, A. A., Graetz, J. Titanium-based Coatings and Methods for Making Coatings. EP3677705A2 (Patent). 2020.