Elevated-temperature creep of high-entropy alloys via nanoindentation

P.H. Lin; H.S. Chou; J.C. Huang; W.S. Chuang; J.S.C. Jang; T.G. Nieh

doi:10.1557/mrs.2019.258

Elevated-temperature creep of high-entropy alloys via nanoindentation

Published online by Cambridge University Press: 06 November 2019

P.H. Lin ,

H.S. Chou ,

J.C. Huang ,

W.S. Chuang ,

J.S.C. Jang and

T.G. Nieh

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P.H. Lin: Affiliation:
Department of Materials and Optoelectronic Science, National Sun Yat-sen University, Taiwan; linnantou12345@gmail.com
H.S. Chou: Affiliation:
National Sun Yat-sen University, Taiwan; sapphirerei@gmail.com
J.C. Huang: Affiliation:
National Sun Yat-sen University, Taiwan; and City University of Hong Kong, Hong Kong; chihuang@cityu.edu.hk
W.S. Chuang: Affiliation:
National Sun Yat-sen University, Taiwan; egg037105218@yahoo.com.tw
J.S.C. Jang: Affiliation:
Institute of Materials Science and Engineering, National Central University, Taiwan; jscjang@ncu.edu.tw
T.G. Nieh: Affiliation:
The University of Tennessee, USA; and City University of Hong Kong, Hong Kong; tnieh@utk.edu

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Abstract

High-entropy alloys (HEAs) have been the focus of wide-ranging studies for their applications as next-generation structural materials. For high-temperature industrial applications, creep behavior of structural materials is critical. In addition to high-temperature tensile, compressive, and notched tests, elevated-temperature nanoindentation is a relatively new testing method for HEAs. With the high accuracy of depth-sensing technology and a stable temperature-controlling stage, elevated-temperature time-dependent mechanical behavior of HEAs can be investigated, especially at localized regions without the limitations of the standard specimen size used for traditional creep testing. Also, the creep response from each grain in polycrystalline samples with various crystalline orientations can be explored in detail. This article overviews current progress in studying creep behavior in HEAs via nanoindentation technology.

Type: High-Temperature Materials for Structural Applications
Information: MRS Bulletin , Volume 44 , Issue 11: High-temperature Materials for Structural Applications , November 2019 , pp. 860 - 866

DOI: https://doi.org/10.1557/mrs.2019.258 [Opens in a new window]
Copyright: Copyright © Materials Research Society 2019

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References

Yeh, J.-W., Chen, S.-K., Lin, S.-J., Gan, J.-Y., Chin, T.-S., Shun, T.-T., Tsau, C.-H., Chang, S.-Y., Adv. Eng. Mater. 6, 299 (2004).CrossRef Google Scholar

Otto, F., Yang, Y., Bei, H., George, E.P., Acta Mater . 61, 2628 (2013).CrossRef Google Scholar

Stepanov, N.D., Shaysultanov, D.G., Salishchev, G.A., Tikhonovsky, M.A., Mater. Lett. 142, 153 (2015).CrossRef Google Scholar

Tsao, T.-K., Yeh, A.-C., Kuo, C.-M., Kakehi, K., Murakami, H., Yeh, J.-W., Jian, S.-R., Sci. Rep. 7, 12658 (2017).CrossRef Google Scholar

Fujieda, T., Shiratori, H., Kuwabara, K., Hirota, M., Kato, T., Yamanaka, K., Koizumi, Y., Chiba, A., Watanabe, S., Mater. Lett. 189, 148 (2017).CrossRef Google Scholar

Xiao, D.H., Zhou, P.F., Wu, W.Q., Diao, H.Y., Gao, M.C., Song, M., Liaw, P.K., Mater. Des. 116, 438 (2017).CrossRef Google Scholar

Qiu, Y., Thomas, S., Gibson, M.A., Fraser, H.L., Birbilis, N., npj Mater. Degrad. 1, 15 (2017).CrossRef Google Scholar

Granberg, F., Nordlund, K., Ullah, M.W., Jin, K., Lu, C., Bei, H., Wang, L.M., Djurabekova, F., Weber, W.J., Zhang, Y., Phys. Rev. Lett. 116, 135504 (2016).CrossRef Google Scholar

Chuang, M.-H., Tsai, M.-H., Wang, W.-R., Lin, S.-J., Yeh, J.-W., Acta Mater . 59, 6308 (2011).CrossRef Google Scholar

Senkov, O.N., Wilks, G.B., Miracle, D.B., Chuang, C.P., Liaw, P.K., Intermetallics 18, 1758 (2010).CrossRef Google Scholar

Wu, Z., Bei, H., Otto, F., Pharr, G.M., George, E.P., Intermetallics 46, 131 (2014).CrossRef Google Scholar

Yao, M.J., Pradeep, K.G., Tasan, C.C., Raabe, D., Scr. Mater. 72–73, 5 (2014).CrossRef Google Scholar

Schuh, B., Mendez-Martin, F., Völker, B., George, E.P., Clemens, H., Pippan, R., Hohenwarter, A., Acta Mater . 96, 258 (2015).CrossRef Google Scholar

Miracle, B.D., Miller, D.J., Senkov, N.O., Woodward, C., Uchic, D.M., Tiley, J., Entropy 16 (2014).CrossRef Google Scholar

Praveen, S., Kim, H.S., Adv. Eng. Mater. 20, 1700645 (2018).CrossRef Google Scholar

Modlinski, R., Witvrouw, A., Ratchev, P., Puers, R., den Toonder, J.M.J., De Wolf, I., Microelectron. Eng. 76, 272 (2004).CrossRef Google Scholar

Chavoshi, S.Z., Xu, S., MRS Commun . 8, 15 (2018).CrossRef Google Scholar

Tsai, M.T., Huang, J.C., Lin, P.H., Liu, T.Y., Liao, Y.C., Jang, J.S.C., Song, S.X., Nieh, T.G., Intermetallics 103, 88 (2018).CrossRef Google Scholar

Ma, Y., Peng, G.J., Wen, D.H., Zhang, T.H., Mater. Sci. Eng. A 621, 111 (2015).CrossRef Google Scholar

Lee, D.-H., Seok, M.-Y., Zhao, Y., Choi, I.-C., He, J., Lu, Z., Suh, J.-Y., Ramamurty, U., Kawasaki, M., Langdon, T.G., Jang, J.-i., Acta Mater . 109, 314 (2016).CrossRef Google Scholar

Wang, Z., Guo, S., Wang, Q., Liu, Z., Wang, J., Yang, Y., Liu, C.T., Intermetallics 53, 183 (2014).CrossRef Google Scholar

Lee, D.-H., Choi, I.-C., Yang, G., Lu, Z., Kawasaki, M., Ramamurty, U., Schwaiger, R., Jang, J.-i., Scr. Mater. 156, 129 (2018).CrossRef Google Scholar

Jiao, Z.M., Wang, Z.H., Wu, R.F., Qiao, J.W., Appl. Phys. A 122, 794 (2016).CrossRef Google Scholar

Ma, Y., Feng, Y.H., Debela, T.T., Peng, G.J., Zhang, T.H., Int. J. Refract. Metals Hard Mater. 54, 395 (2016).CrossRef Google Scholar

Li, W.B., Henshall, J.L., Hooper, R.M., Easterling, K.E., Acta Metall. Mater. 39, 3099 (1991).CrossRef Google Scholar

He, L.Z., Zheng, Q., Sun, X.F., Guan, H.R., Hu, Z.Q., Tieu, A.K., Lu, C., Zhu, H.T., Metall. Mater. Trans. A 36, 2385 (2005).CrossRef Google Scholar

Cao, T., Shang, J., Zhao, J., Cheng, C., Wang, R., Wang, H., Mater. Lett. 164, 344 (2016).CrossRef Google Scholar

Tian, S., Su, Y., Qian, B., Yu, X., Liang, F., Li, A., Mater. Des. 37, 236 (2012).CrossRef Google Scholar

Knezevic, V., Schneider, A., Landier, C., Procedia Eng . 55, 240 (2013).CrossRef Google Scholar

Kim, W.J., Jeong, H.T., Park, H.K., Park, K., Na, T.W., Choi, E., J. Alloys Compd. 802, 152 (2019).CrossRef Google Scholar

Friedel, J., Dislocations (Pergamon Press, Oxford, UK, 1964).Google Scholar

Jeong, H.T., Park, H.K., Park, K., Na, T.W., Kim, W.J., Mater. Sci. Eng. A 756, 528 (2019).CrossRef Google Scholar

Bhattacharyya, A., Singh, G., Eswar Prasad, K., Narasimhan, R., Ramamurty, U., Mater. Sci. Eng. A 625, 245 (2015).CrossRef Google Scholar

Woo, C.H., Huang, H., Ngan, A.H.W., Yu, T., CMES Comp. Model. Eng. Sci. 6, 105 (2004).Google Scholar

Zou, Y., Wheeler, J.M., Ma, H., Okle, P., Spolenak, R., Nano Lett. 17, 1569 (2017).CrossRef Google Scholar

Yu, P.F., Cheng, H., Zhang, L.J., Zhang, H., Jing, Q., Ma, M.Z., Liaw, P.K., Li, G., Liu, R.P., Mater. Sci. Eng. A 655, 283 (2016).CrossRef Google Scholar

Ghosh, R.N., Bull. Mater. Sci. 17, 1341 (1994).CrossRef Google Scholar

Wen, Z., Zhang, D., Li, S., Yue, Z., Gao, J., J. Alloys Compd. 692, 301 (2017).CrossRef Google Scholar

Hu, T.Y., Zheng, B.L., Hu, M.Y., He, P.F., Yue, Z.F., Mater. Sci. Technol. 31, 325 (2015).CrossRef Google Scholar

Wu, Z., Gao, Y.F., Bei, H., Scr. Mater. 109, 108 (2015).CrossRef Google Scholar

Kireeva, I.V., Chumlyakov, Y.I., Pobedennaya, Z.V., Kuksgausen, I.V., Karaman, I., Mater. Sci. Eng. A 705, 176 (2017).CrossRef Google Scholar

He, J.Y., Zhu, C., Zhou, D.Q., Liu, W.H., Nieh, T.G., Lu, Z.P., Intermetallics 55, 9 (2014).CrossRef Google Scholar

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Elevated-temperature creep of high-entropy alloys via nanoindentation

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