Stabilization and strengthening effects of functional groups in two-dimensional titanium carbide

MXenes公司 密度泛函理论 碳化钛 材料科学 表面改性 化学物理 电子结构 碳化物 纳米技术 复合材料 计算化学 物理化学 化学
作者
Zhongheng Fu,Qianfan Zhang,Dominik Legut,Si Chen,Timothy C. Germann,Turab Lookman,Shuo Du,Joseph S. Francisco,Ruifeng Zhang
出处
期刊:Physical review [American Physical Society]
卷期号:94 (10) 被引量:203
标识
DOI:10.1103/physrevb.94.104103
摘要

Two-dimensional (2D) materials have attracted considerable interest due to their remarkable properties and potential applications for nanoelectronics, electrodes, energy storage devices, among others. However, many well-studied 2D materials lack appreciable conductivity and tunable mechanical strength, limiting their applications in flexible devices. Newly developed MXenes open up the opportunity to design novel flexible conductive electronic materials. Here, using density functional theory (DFT), we investigate systematically the effects of several functional groups on the stabilization, mechanical properties, and electronic structures of a representative MXene. It is found that oxygen possesses the largest adsorption energy as compared to other functional groups, indicating its good thermodynamic stabilization. In comparison with bare and other functionalized titanium carbides, the oxygen functionalized one exhibits the most superior ideal strength; however, the premature softening of the long-wave phonon modes might limit the intrinsic strength for $\mathrm{T}{\mathrm{i}}_{3}{\mathrm{C}}_{2}{\mathrm{O}}_{2}$. Furthermore, the introduction of functional groups can induce a strong anisotropy under tensile loading. By analyzing the deformation paths and the electronic instability under various loadings, we demonstrate that the unique strengthening by oxygen functional groups is attributed to a significant charge transfer from inner bonds to outer surface ones after functionalization. Our results shed a novel view into exploring a variety of MXenes for their potential applications in flexible electronic and energy storage devices.
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