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Fatigue Behavior of A Minor Yttrium Doped ZrCuNi-Based Metallic Glass Alloy Fabricated by Industrial Grade Raw Material

  • Shichao Zhou (a1), Tao Zhang (a2), Min Zhang (a3) and Yong Zhang (a1)

Abstract

The fatigue behavior of a low-cost Zr52.1Ti5Cu17.9Ni14.6Al10Y0.4 (at%) (ZrCuNi-based) bulk-metallic glass (BMG) prepared by industrial-grade material was investigated under three-point bending loading modes. In order to obtain the fatigue stress-life (S-N) data, stress-controlled experiments were conducted using a computer-controlled material test system electrohydraulic testing machine at 60 Hz with a 0.1 R ratio in the air at room temperature. The fatigue limit (∼174 MPa) in stress amplitude and fatigue ratio (∼0.14) of this BMG is comparative to the similar BMG (Vit-105) prepared by high pure raw materials. The crack initiated from inclusions near the rectangular corners at the outer surface of the rectangular beam due to stress concentration. The striations and vein-like patterns were observed in the crack propagation region and fast fracture region, respectively.

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Corresponding author

*Corresponding author: Yong Zhang (drzhangy@ustb.edu.cn)

References

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[1]Sun, B. A. and Wang, W. H., Progress in Materials Science 74, 211 (2015).
[2]Scully, J. R. and Gebert, A. and Payer, J. H., Journal of Materials Research 22, 302 (2006).
[3]Jia, H., Wang, G., Chen, S., Gao, Y., Li, W., and Liaw, P. K., Progress in Materials Science 98, 168 (2018).
[4]Jiang, F., Wang, Z. J., Zhang, Z. B., and Sun, J., Scripta Materialia 53, 487 (2005).
[5]Yong Zhang, M. X. P. D., Materials Transactions 11, 1410 (2000).
[6]Zhang Yong, Z. Y. H. X., Science in China Series G: Physics, Mechanics & Astronomy 4, 427 (2008).
[7]Zhang, Y., Chen, J., Chen, G. L., and Liu, X. J., Applied Physics Letters 89, 131904 (2006).
[8]Zhang, T., Meng, X., Wang, C., Li, L., Yang, J., Li, W., Li, R., and Zhang, Y., Journal of Alloys and Compounds 792, 851 (2019).
[9]Gilbert, C. J. and Lippmann, J. M. and Ritchie, R. O., Scripta Materialia 38, 537 (1998).
[10]Wang, X. D., Qu, R. T., Wu, S. J., Liu, Z. Q., and Zhang, Z. F., Materials Science and Engineering: A 717, 41 (2018).
[11]Wang, X. D., Qu, R. T., Liu, Z. Q., and Zhang, Z. F., Journal of Alloys and Compounds 695, 2016 (2017).
[12]Launey, M. E., Hofmann, D. C., Johnson, W. L., and Ritchie, R. O., Proceedings of the National Academy of Sciences of the United States of America 106, 4986 (2009).
[13]Morrison, M. L., Buchanan, R. A., Liaw, P. K., Green, B. A., Wang, G. Y., Liu, C. T., and Horton, J. A., Materials Science and Engineering: A 467, 190 (2007).
[14]Naleway, S. E., Greene, R. B., Gludovatz, B., Dave, N.K.N., Ritchie, R. O., and Kruzic, J.J., Metallurgical and Materials Transactions A 44A, 5688 (2013).
[15]Gilbert, C. J. and Schroeder, V. and Ritchie, R. O., Metallurgical and Materials Transactions A 30, 1739 (1999).
[16]Ritchie, R. O. and Schroeder, V. and Gilbert, C. J., Intermetallics 8, 469 (2000).
[17]Qiao, S. G. M. G. J. W., Metallurgical and Materials Transactions A 42, 2530 (2011).
[18]Zhang, L. K., Chen, Z. H., Chen, D., Zhao, X. Y., and Zheng, Q., Journal of Non-Crystalline Solids 370, 31 (2013).
[19]Wang, G. Y., Qiao, D. C., Yokoyama, Y., Freels, M., Inoue, A., and Liaw, P. K., Journal of Alloys and Compounds 483, 143 (2009).
[20]Wang, G. Y., Liaw, P. K., Peter, W. H., Yang, B., Freels, M., Yokoyama, Y., Benson, M. L., Green, B. A., Saleh, T. A., McDaniels, R. L., Steward, R. V., Buchanan, R. A., Liu, C. T., and Brooks, C. R., Intermetallics 12, 1219 (2004).
[21]Wang, G. Y., Liaw, P. K., Peter, W. H., Yang, B., Yokoyama, Y., Benson, M. L., Green, B. A., Kirkham, M. J., White, S. A., Saleh, T. A., McDaniels, R. L., Steward, R. V., Buchanan, R. A., Liu, C. T., and Brooks, C. R., Intermetallics 12, 885 (2004).
[22]Yue, Y., Wang, R., Ma, D. Q., Tian, J. F., Zhang, X. Y., Jing, Q., Ma, M. Z., and Liu, R. P., Intermetallics 60, 86 (2015).
[23]Wang, X. D., Qu, R. T., Liu, Z. Q., and Zhang, Z. F., Materials Science and Engineering: A 627, 336 (2015).
[24]Wang, X. D., Qu, R. T., Liu, Z. Q., and Zhang, Z. F., Materials Science and Engineering: A 696, 267 (2017).
[25]Qu, R. T., Wang, S. G., Wang, X. D., Liu, Z. Q., and Zhang, Z. F., Scripta Materialia 133, 24 (2017).
[26]Wang, X. D., Qu, R. T., Wu, S. J., Zhu, Z. W., Zhang, H. F., and Zhang, Z. F., Materialia 7, 100407 (2019).
[27]Wang, G. Y., Liaw, P. K., Peker, A., Yang, B., Benson, M. L., Yuan, W., Peter, W. H., Huang, L., Freels, M., Buchanan, R. A., Liu, C. T., and Brooks, C. R., Intermetallics 13, 429 (2005).
[28]Schroeder, V. and Ritchie, R. O., Acta Materialia 54, 1785 (2006).
[29]Wang, G., Liaw, P. K., Yokoyama, Y., Freels, M., and Inoue, A., Advanced Engineering Materials 10, 1030 (2008).
[30]Qiao, D. C., Liaw, P. K., Fan, C., Lin, Y. H., Wang, G. Y., Choo, H., and Buchanan, R. A., Intermetallics 14, 1043 (2006).

Keywords

Fatigue Behavior of A Minor Yttrium Doped ZrCuNi-Based Metallic Glass Alloy Fabricated by Industrial Grade Raw Material

  • Shichao Zhou (a1), Tao Zhang (a2), Min Zhang (a3) and Yong Zhang (a1)

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