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Investigation of 2D Boridene from First Principles and Experiments

Pernilla Helmer, Joseph Halim, Jie Zhou, Roopathy Mohan, Björn Wickman, Jonas Björk, Johanna Rosén

2022Advanced Functional Materials76 citationsDOIOpen Access PDF

Abstract

Abstract Recently, a 2D metal boride – boridene – has been experimentally realized in the form of single‐layer molybdenum boride sheets with ordered metal vacancies, through selective etching of the nanolaminated 3D parent borides (Mo 2/3 Y 1/3 ) 2 AlB 2 and (Mo 2/3 Sc 1/3 ) 2 AlB 2 . The chemical formula of the boridene was suggested to be Mo 4/3 B 2‐ x T z , where T z denotes surface terminations. Here, the termination composition and material properties of Mo 4/3 B 2‐ x T z from both theoretical and experimental perspectives are investigated. Termination sites are considered theoretically for termination species T = O, OH, and F, and the energetically favored termination configuration is identified at z = 2 for both single species terminations and binary termination mixes of different stoichiometries in ordered and disordered configurations. Mo 4/3 B 2‐ x T z is shown to be dynamically stable for multiple termination stoichiometries, displaying semiconducting, semimetallic, or metallic behavior depending on how different terminations are combined. The approximate chemical formula of a freestanding film of boridene is attained as Mo 1.33 B 1.9 O 0.3 (OH) 1.5 F 0.7 from X‐ray photoelectron spectroscopy (XPS) analysis which, within error margins, is consistent with the theoretical results. Finally, metallic and additive‐free Mo 4/3 B 2‐ x T z shows high catalytic performance for the hydrogen evolution reaction, with an onset potential of 0.15 V versus the reversible hydrogen electrode.

Topics & Concepts

X-ray photoelectron spectroscopyMaterials scienceStoichiometryBorideMetalMolybdenumHydrogenCrystallographyAnalytical Chemistry (journal)Physical chemistryMetallurgyNuclear magnetic resonanceChemistryPhysicsOrganic chemistryMXene and MAX Phase Materials2D Materials and ApplicationsGraphene research and applications