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Tuning the work functions via topology and halogen element adsorbates: A first-principles investigation on MBene nanoribbons

[Display omitted] •Theoretical assessment on chirality-, width- and functionalization-dependent work function of Ti2B (MBene) nanoribbon is performed by DFT study.•The work function of Ti2B nanoribbons has been discussed in terms of the non-equivalent edges and the halogen termination.•The work func...

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Published in:Materials science & engineering. B, Solid-state materials for advanced technology Solid-state materials for advanced technology, 2024-07, Vol.305, p.117421, Article 117421
Main Authors: Zhang, Shuai, Ling, Yiyun, Zhang, Yu, Wang, Weiliang, Zhang, Shaolin, Huang, Haiming
Format: Article
Language:English
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Summary:[Display omitted] •Theoretical assessment on chirality-, width- and functionalization-dependent work function of Ti2B (MBene) nanoribbon is performed by DFT study.•The work function of Ti2B nanoribbons has been discussed in terms of the non-equivalent edges and the halogen termination.•The work function variation of the Ti2B nanoribbons has been explained by the edge dipole moments caused by the edge’s charge redistribution, halogen electronegativity, and edge reconstruction. One-dimensional nanoribbons have foreshadowed potential applications in nanoelectronics due to their fascinating quantum confinement effects. We present theoretical assessment from first-principles calculations to explore the work functions of Ti2B-based MBene nanoribbons, focusing on the size, edge, and functionalization dependencies. We found that the bare and halogen-functionalized Ti2B nanoribbons exhibit metallic properties and chemical stability. The work function of both bare and halogen-terminated armchair Ti2B nanoribbons tends to saturate as width. In contrast, the work function of zigzag Ti2B nanoribbons varies complexly with width and has been discussed in terms of the non-equivalent edges and halogen termination. The work functions of halogen-terminated Ti2B nanoribbons have been found to be significantly affected by the edge dipole moments, which are determined by three factors: functionalization-induced electron redistribution at the edge, the electronegativity of halogen functional groups, and the edge reconstruction. These findings provide valuable insights for designing, characterizing, and utilizing the proposed nanostructures.
ISSN:0921-5107
1873-4944
DOI:10.1016/j.mseb.2024.117421