主要论文
| [1]T.P. Hou, Y. Li, K.M. Wu, M.J. Peet, C.N. Hulme-Smith, L. Guo, Magnetic-field-induced magnetism and thermal stability of carbides Fe6-xMoxC in molybdenum-containing steels Acta Materialia, (2015), Accepted. http://dx.doi.org/10.1016/j.actamat.2015.09.029.
[2]T. P. Hou, K. M. Wu, G. He, Effect of tempering temperature on carbide precipitation behaviors in a high-strength low-alloy steel under high magnetic field, Materials Science and Technology, 30 (8) (2014), 900-905.
[3] T. P. Hou, G. He, K.M. Wu and Y Li, Magnetic-field-induced precipitation behavior of (Fe,Mo)6C alloy carbides in a molybdenum alloyed steel, Materials Science and Technology, Volume 30 (8) (2014), 906-910.
[4] T. P. Hou, Y Li, Y. D. Zhang and K.M. Wu, Magnetic-field-induced precipitation behaviors of alloy carbides M2C, M3C and M6C in a molybdenum-containing steel, Metallurgical and Materials Transactions A, 45(5) (2014) 2553-2561.
[5] T.P. Hou, K.M. Wu, Alloy carbide precipitation in the tempered 2.25Cr-Mo steel under high magnetic field, Acta Materialia, 61 (2013), 2016-2024.
[6] T.P. Hou, K.M. Wu, The effect of high magnetic field on metal solute substitution in M23C6 alloy carbide, Scripta Materialia, 67(2012) 609-612.
[7] T.P. Hou, Y. Li, K.M. Wu, Effect of high magnetic field on alloy carbide precipitation in an Fe-C-Mo alloy, Journal of Alloys and Compounds, 527 (2012) 240–246.
[8] T.P. Hou, Y. Li, J.J. Zhang, K.M. Wu, Effect of magnetic field on the carbide precipitation during tempering of a molybdenum-containing steel, Journal of Magnetism and Magnetic Materials, 324 (2012) 857-861.
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