[1] Zhang T , Lu K , Katsuyama J , et al. Stress intensity factor solutions for surface cracks with large aspect ratios in cylinders and plates [J]. International Journal of Pressure Vessels and Piping, 2021, 189, 104262 (SCI, IF 2.23, WOS:000614145400011).
[2] Zhang T, Wang S, Wang W. An energy-based method for flow property determination from a single-cycle spherical indentation test (SIT)[J]. International Journal of Mechanical Sciences, 2020, 171, 105369. (SCI, IF 4.631, WOS:000525417400005)
[3] Zhang T, Wang S, Wang W. A comparative study on fracture toughness calculation models in spherical indentation tests (SITs) for ductile metals[J]. International Journal of Mechanical Sciences, 2019, 160: 114-128. (SCI, IF 4.631, WOS:000485209700010)
[4] Zhang T, Wang S, Wang W. A unified energy release rate based model to determine the fracture toughness of ductile metals from unnotched specimens[J]. International Journal of Mechanical Sciences, 2019, 150: 35-50. (SCI, IF 4.631, WOS:000458597800005)
[5] Zhang T, Wang S, Wang W. A constitutive model independent analytical method in determining the tensile properties from incremental spherical indentation tests (ISITs)[J]. International Journal of Mechanical Sciences, 2018, 148: 9-19. (SCI, IF 4.631, WOS:000448097900002)
[6] Zhang T, Wang S, Wang W. A comparative study on uniaxial tensile property calculation models in spherical indentation tests (SITs)[J]. International Journal of Mechanical Sciences, 2019, 155: 159-169. (SCI, IF 4.631, WOS:000468721800013)
[7] Zhang T, Wang S, Wang W. Method to determine the optimal constitutive model from spherical indentation tests[J]. Results in physics, 2018, 8: 716-727. (SCI, IF 4.019, WOS:000428027700100)
[8] Zhang T, Guo J, Wang W. A strain-pattern-based spherical indentation method for simultaneous uniaxial tensile residual stress and flow property determination[J]. The Journal of Strain Analysis for Engineering Design, 2020. (SCI, IF 1.63, WOS:000537816700001)
[9] Zhang T, Wang S, Wang W. A study on determination of tensile properties of metals at elevated temperatures from spherical indentation tests[J]. The Journal of Strain Analysis for Engineering Design, 2019, 54(5-6): 331-347. (SCI, IF 1.63, WOS:000489390000001)
[10] Zhang T, Wang S, Wang W. Determination of the proof strength and flow properties of materials from spherical indentation tests: an analytical approach based on the expanding cavity model[J]. The Journal of Strain Analysis for Engineering Design, 2018, 53(4): 225-241. (SCI, IF 1.63, WOS:000432135300004)
[11] Zhang T, Wang S, Wang W. Improved methods to determine the elastic modulus and area reduction rate in spherical indentation tests[J]. Materials Testing, 2018, 60(4): 355-362. (SCI, IF 0.799, WOS:000429292400003)
[12] Zhang T, Wang W. Li A, The spherical indentation approach for fracture toughness evaluation: A study based on the energy release rate [C], ASME 2018 Pressure Vessels and Piping Conference. Prague, 2018. (EI, Accession number: 20184706125668)
[13] Zhang T, Wang W. Li A, A Study on the Ball Indentation Test for Linear Hardening Metals [C], ASME 2017 Pressure Vessels and Piping Conference. Hawaii, 2017. (EI, Accession number: 20174704421825)