Abstract
This paper investigates the mechanical behaviors of few-layer black phosphorus (FLBP) by using molecular dynamics simulations. Results show that both tensile and compressive behaviors are strongly anisotropic in the armchair and zigzag directions due to the unidirectional puckers in each atomic layer, and that the compressive behavior is dependent on the number of atomic layers. In particular, the compressive and buckling strengths of FLBP can be significantly enhanced by stacking more atomic layers together, while this has little influence on both Young’s modulus and tensile strength. It is interesting to found that increasing the number of atomic layers in FLBP or the dimension ratio can lead to a drastically reduced flexibility in armchair direction, showing that both compressive and buckling strengths become higher than those in zigzag direction. It is also demonstrated that the reorientation of FLBP’s atomic configuration occurs under certain conditions. The mechanism of deformation underlying the mechanical behaviors of FLBP is also discussed, suggesting that changing the number of atomic layers is an effective way to engineer two-dimensional materials for desired material properties.
Highlights
Black phosphorus (BP) has been rediscovered from the perspective of a two-dimensional (2D) material and rapidly attracted tremendous interests due to its unique and superior electrical, optical and thermal properties[1,2,3,4,5,6,7,8,9,10,11,12]
The present paper investigates how the tensile and compressive behaviors of few-layer black phosphorus (FLBP) are influenced by the total number of atomic layers NL via MD simulations
Considering the fact that FLBP-based electronic devices are fabricated in various geometric dimensions, it is essential to understand how the compressive and buckling strengths of FLBP are affected by its dimensions
Summary
This paper investigates the mechanical behaviors of few-layer black phosphorus (FLBP) by using molecular dynamics simulations Results show that both tensile and compressive behaviors are strongly anisotropic in the armchair and zigzag directions due to the unidirectional puckers in each atomic layer, and that the compressive behavior is dependent on the number of atomic layers. BP possesses intrinsic direct bandgap[3,4,5] which is unavailable in graphene Such bandgap can be modified in a range of ~0.3 eV-2.0 eV by changing the number of atomic layers[6,7] and/or sustained strains of the structure[8,9]. The reorientation emerges in FLBP before yielding during compression in the armchair direction while tensile behavior is not influenced by the number of atomic layers. The thermal environment condition is considered to be a range from 1 K to 400 K simulated by a Nosé-Hoover[22,23] thermostat
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