Strong electron-phonon coupling and predicted highest known Tc of MXenes revealed in 2H-Mo2N under biaxial stress
Abstract
This letter reports the unexpectedly strong electron-phonon coupling (EPC) and the highest Tc record (≈ 38 K) among the MXenes revealed in the 2H-Mo2N under biaxial stress. At first, its excellent mechanical properties are demonstrated with ideal strength of 37 GPa and elastic modulus of 438 GPa. Subsequently, EPC and corresponding Tc are elucidated upon the dynamically stable range of strain. For strain-free 2H-Mo2N, the EPC constant (λ) and Tc are 1.3 and 22.7 K, respectively. This Tc is higher than those of 2H-Mo2C (4.3 K), 1T-Mo2N (16.8 K), and other pristine MXenes. The material exhibits remarkable enhancement in λ and Tc when subject to compressive and tensile stresses. The obvious strong EPC with λ over 2.0 occurs at strains of -4%, -2.5%, and 5%, yielding Tcs of 37.8, 35.4, and 28.9 K, respectively. Our findings suggest that the strain-dependent feature and energy levels of electronic bands play an essential role in enhancing EPC. Moreover, the stronger EPC in Mo2N compared with Mo2C is clarified based on lattice vibrations. Therefore, this work paves a practical way for designing 2D superconducting materials using tuning atomic recipes and strain-dependent engineering.
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