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Main Authors: Tang, Haifeng, Yin, Xiaodan, Zhang, Peigen, Karpov, Victor, Borra, Vamsi, Tian, Zhihua, Zheng, Wei, Ding, Jianxiang, Sun, ZhengMing
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2506.15802
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author Tang, Haifeng
Yin, Xiaodan
Zhang, Peigen
Karpov, Victor
Borra, Vamsi
Tian, Zhihua
Zheng, Wei
Ding, Jianxiang
Sun, ZhengMing
author_facet Tang, Haifeng
Yin, Xiaodan
Zhang, Peigen
Karpov, Victor
Borra, Vamsi
Tian, Zhihua
Zheng, Wei
Ding, Jianxiang
Sun, ZhengMing
contents The exceptional synergy of ceramic and metallic properties within MAX phases positions them as highly promising for a wide array of applications. However, their stability has been threatened by the phenomenon of A-site metal whisker growth. Herein, we have significantly mitigated tin whisker growth in Ti2SnC by incorporating vanadium solutes at its M-site. With an increase in vanadium concentration, there is a marked reduction in the degree of decomposition of the M-site solid solution when subjected to the same level of externally destructive treatments, thereby inhibiting whisker proliferation. Both experimental outcomes and theoretical calculations reveal that the vanadium solid solution augments the hardness, Pughs ratio, and Poissons ratio of Ti2SnC, enhancing its mechanical strength and toughness. The incorporation of V atoms introduces stronger V C and V Sn bonds, as evidenced by its electronic density of states and bulk modulus, thus significantly bolstering the resistance of MAX phases against decomposition and effectively curtailing whisker growth. Additionally, the phenomenon reported in this paper also conforms to the electrostatic theory of whisker growth. This work for the first time achieves the suppression of A-site whisker growth through an M-site solid solution, thereby extending their potential for applications where durability and reliability are paramount.
format Preprint
id arxiv_https___arxiv_org_abs_2506_15802
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Inhibition of whisker growth by crafting more decomposition-resistant Ti2SnC MAX phase through vanadium solid solution
Tang, Haifeng
Yin, Xiaodan
Zhang, Peigen
Karpov, Victor
Borra, Vamsi
Tian, Zhihua
Zheng, Wei
Ding, Jianxiang
Sun, ZhengMing
Materials Science
The exceptional synergy of ceramic and metallic properties within MAX phases positions them as highly promising for a wide array of applications. However, their stability has been threatened by the phenomenon of A-site metal whisker growth. Herein, we have significantly mitigated tin whisker growth in Ti2SnC by incorporating vanadium solutes at its M-site. With an increase in vanadium concentration, there is a marked reduction in the degree of decomposition of the M-site solid solution when subjected to the same level of externally destructive treatments, thereby inhibiting whisker proliferation. Both experimental outcomes and theoretical calculations reveal that the vanadium solid solution augments the hardness, Pughs ratio, and Poissons ratio of Ti2SnC, enhancing its mechanical strength and toughness. The incorporation of V atoms introduces stronger V C and V Sn bonds, as evidenced by its electronic density of states and bulk modulus, thus significantly bolstering the resistance of MAX phases against decomposition and effectively curtailing whisker growth. Additionally, the phenomenon reported in this paper also conforms to the electrostatic theory of whisker growth. This work for the first time achieves the suppression of A-site whisker growth through an M-site solid solution, thereby extending their potential for applications where durability and reliability are paramount.
title Inhibition of whisker growth by crafting more decomposition-resistant Ti2SnC MAX phase through vanadium solid solution
topic Materials Science
url https://arxiv.org/abs/2506.15802