Strain effects on electronic and optic properties of monolayer C2N holey two-dimensional crystals

Abstract

A new two-dimensional material, the C2N holey 2D (C2N-h2D) crystal, has recently been synthesized. Here we investigate the strain effects on the properties of this new material by first-principles calculations. We show that the material is quite soft with a small stiffness constant and can sustain large strains ≥ 12\%. It remains a direct gap semiconductor under strain and the bandgap size can be tuned in a wide range as large as 1 eV. Interestingly, for biaxial strain, a band crossing effect occurs at the valence band maximum close to a 8\% strain, leading to a dramatic increase of the hole effective mass. Strong optical absorption can be achieved by strain tuning with absorption coefficient 106 cm-1 covering a wide spectrum. Our findings suggest the great potential of strain-engineered C2N-h2D in electronic and optoelectronic device applications.