Auxetic two-dimensional transition metal selenides and halides-Reference-Cited by-同舟云学术

Auxetic two-dimensional transition metal selenides and halides

Published:2020-10-14 Issue:1 Volume:6 Page:
ISSN:2057-3960
Container-title:npj Computational Materials
language:en
Short-container-title:npj Comput Mater

Author:

Pan Jinbo,Zhang Yan-Fang,Zhang Jingda,Banjade Huta,Yu Jie,Yu Liping,Du Shixuan,Ruzsinszky Adrienn,Hu Zhenpeng^ORCID,Yan Qimin^ORCID

Abstract

AbstractAuxetic two-dimensional (2D) materials provide a promising platform for biomedicine, sensors, and many other applications at the nanoscale. In this work, utilizing a hypothesis-based data-driven approache, we identify multiple materials with remarkable in-plane auxetic behavior in a family of buckled monolayer 2D materials. These materials are transition metal selenides and transition metal halides with the stoichiometry MX (M = V, Cr, Mn, Fe, Co, Cu, Zn, Ag, and X = Se, Cl, Br, I). First-principles calculations reveal that the desirable auxetic behavior of these 2D compounds originates from the interplay between the buckled 2D structure and the weak metal–metal interaction determined by their electronic structures. We observe that the Poisson’s ratio is sensitive to magnetic order and the amount of uniaxial stress applied. A transition from positive Poisson’s ratio (PPR) to negative Poisson’s ratio (NPR) for a subgroup of MX compounds under large uniaxial stress is predicted. The work provides a guideline for the future design of 2D auxetic materials at the nanoscale.

Funder

U.S. Department of Energy

Publisher

Springer Science and Business Media LLC

Subject

Computer Science Applications,Mechanics of Materials,General Materials Science,Modelling and Simulation

Link

https://www.nature.com/articles/s41524-020-00424-1.pdf

Reference41 articles.

1. Evans, K. E. Auxetic polymers: a new range of materials. Endeavour 15, 170–174 (1991).

2. Scarpa, F. Auxetic materials for bioprostheses [In the Spotlight]. IEEE Signal Process. Mag. 25, 128–126 (2008).

3. Choi, J. & Lakes, R. Design of a fastener based on negative Poisson’s ratio foam. Cell. Polym. 10, 205–212 (1991).

4. Avellaneda, M. & Swart, P. J. Calculating the performance of 1–3 piezoelectric composites for hydrophone applications: an effective medium approach. J. Acoust. Soc. Am. 103, 1449–1467 (1998).

5. Liu, Q. Literature review: materials with negative Poisson’s ratios and potential applications to aerospace and defence. Air Vehicles Division Defence Science and Technology Organisation (Victoria, Australia, 2006).

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