{112} 〈111〉 Twins or Twinned Variants Induced by Martensitic Transformation?

doi:10.1007/s40195-022-01470-y

Abstract

Abstract:

Twinned substructure in lath martensite was induced in the interstitial free (IF) steel via a high pressure thermal cycle (heating up to 1100 ℃ and holding for 30 min, cooling at 10 ℃/s to room temperature under a pressure of 4 GPa). Experimental observations and theoretical simulation confirm that the twinned substructure has the origin related to the twinned variants rather than the bcc {112} 〈111〉 twins, while extra diffraction spots were caused by crystal overlapping rather than any extra phase. The differences in crystallography and electron diffraction behavior between twinned variants and {112} 〈111〉 twins were discussed in detail.

Key words: Twinned variants, {112}?〈111〉?twins, Martensitic transformation, Crystal overlapping, Electron diffraction

Zuohua Wang, Haidong Sun, Peng Wang, Ning Liu, Pinwen Zhu, Dongli Yu, Hongwang Zhang. {112} 〈111〉 Twins or Twinned Variants Induced by Martensitic Transformation?[J]. Acta Metallurgica Sinica (English Letters), 2023, 36(1): 133-140.

Figures/Tables 4

Fig. 1 The bright field image a, the SAED pattern b, the dark field images c-e, the HRTEM image f and the overlap of inverse fast Fourier transform (IFFT) image and simulation f1 of the thermally processed IF steel under high pressure of 4 GPa. Black circle in a indicates the area where the SAED pattern was obtained, while the arrows in b indicates the diffraction spots used for dark field imaging

Fig. 2 The bright field image a, the SAED pattern b, the dark field images c-e, the HRTEM image f, the overlap of IFFT image and simulation f1; the bright field image g, the SAED pattern and Kikuchi diffraction pattern of V1 and V2 h, the HRTEM image i, and the overlap of IFFT image and simulation i1 [8] of the thermally processed IF steel under high pressure of 4 GPa. Black circle in a indicates the area where the SAED pattern in b was obtained, the arrows in b indicates the diffraction spots used for dark field imaging, and black circle in g indicates the area where the SAED pattern in h was obtained

Fig. 3 3D models of twinned variants V1 (red) and V2 (yellow) a, full-overlap projection b, part-overlap projection c, none-overlap projection d; 3D models of {112}?〈111〉?twins (blue) and matrix (red) e, none-overlap projection f, part-overlap projection g, and full-overlap projection h

Fig. 4 The (011)V1,V2 stereo-net projection of V1 (red) and V2 (blue) a; the (011)M and (0-1-1)T stereo-net projection of matrix (red) and twin (blue) b; where the dots are the zone axes and the dashed lines are the crystallographic planes

References 23

[1]	G. Krauss, Mater. Sci. Eng. A 273-275, 40 (1999)
[2]	P.M. Kelly, A. Jostsons, R.G. Blake, Acta. Metall. Mater. 38, 1075 (1990) DOI URL
[3]	T. Maki, K. Tsuzaki, I. Tamura, ISIJ Int. 20, 207 (1980) DOI URL
[4]	P. Zhang, Y.L. Chen, W.L. Xiao, D.H. Ping, X.Q. Zhao, Prog. Nat. Sci. 26, 169 (2016) DOI URL
[5]	H.D. Sun, Y.H. Wang, Z.H. Wang, N. Liu, Y. Peng, X.J. Zhao, R.M. Ren, H.W. Zhang, J. Mater. Sci. Technol. 49, 126 (2020) DOI URL
[6]	H.D. Sun, Z.H. Wang, S. Zhang, N. Liu, P.W. Zhu, D.L. Yu, H.W. Zhang, Acta Metall. Sin. -Engl. Lett. 35, 1157 (2022)
[7]	H.W. Zhang, Y.H. Wang, Y. Peng, P.W. Zhu, J.H. Liu, Z.Q. Feng, G.L. Wu, X.X. Huang, Mater. Res. Lett. 7, 354 (2019) DOI URL
[8]	Z.H. Wang, H.D. Sun, C.J. Li, N. Liu, S. Zhang, P.W. Zhu, D.L. Yu, H.W. Zhang, Acta Mater. 214, 116978 (2021) DOI URL
[9]	Y. Li, Z.H. Wang, S. Zhang, N. Liu, Y.H. Wang, P.W. Zhu, D.L. Yu, Y. Peng, H.W. Zhang, Scr. Mater. 187, 163 (2020) DOI URL
[10]	B.B. Jiang, A.D. Tu, H. Wang, H.C. Duan, S.Y. He, H. Ye, K. Du, Acta Mater. 155, 56 (2018) DOI URL
[11]	J. Gates, A. Atrens, I. Smith, Z. Werkstofftech. 18, 344 (1987) DOI URL
[12]	R. Padmanabhan, W.E. Wood, Mater. Sci. Eng. A 66, 1 (1984)
[13]	T. Liu, D. Zhang, Q. Liu, Y. Zheng, Y. Su, X. Zhao, J. Yin, M. Song, D. Ping, Sci. Rep. 5, 1 (2015)
[14]	G.V. Kurdjumow, G. Sachs, Z. Med, Phys. 64, 325 (1930)
[15]	S. Morito, H. Tanaka, R. Konishi, T. Furuhara, T. Maki, Acta Mater. 51, 1789 (2003) DOI URL
[16]	T.W. Liu, D.H. Ping, T. Ohmura, M. Ohnuma, J. Mater. Sci. 53, 2976 (2017) DOI URL
[17]	C.C. Kinney, K.R. Pytlewski, A.G. Khachaturyan, J.W. Morris, Acta Mater. 69, 372 (2014) DOI URL
[18]	L. Qi, A.G. Khachaturyan, J.W. Morris, Acta Mater. 76, 23 (2014) DOI URL
[19]	X. Wang, J. Wang, Y. He, C. Wang, L. Zhong, S.X. Mao, Nat. Commun. 11, 2497 (2020) DOI URL
[20]	A. Hosokawa, S. Ii, K. Tsuchiya, Mater. Trans. 55, 1097 (2014) DOI URL
[21]	C.Q. Chen, J.N. Florando, M. Kumar, K.T. Ramesh, K.J. Hemker, Acta Mater. 69, 114 (2014) DOI URL
[22]	L.M. Hsiung, D.H. Lassila, Acta Mater. 48, 4851 (2000) DOI URL
[23]	A. Stormvinter, G. Miyamoto, T. Furuhara, P. Hedström, A. Borgenstam, Acta Mater. 60, 7265 (2012) DOI URL