Biaxial strain enhanced piezoelectric properties in monolayer g-C3N4

Abstract

Graphite-like carbon nitride (g-C3N4) is considered as a promising candidate for energy materials. In this work, the biaxial strain (-4\%-4\%) effects on piezoelectric properties of g-C3N4 monolayer are studied by density functional theory (DFT). It is found that the increasing strain can reduce the elastic coefficient C11-C12, and increases piezoelectric stress coefficient e11, which lead to the enhanced piezoelectric strain coefficient d11. Compared to unstrained one, strain of 4\% can raise the d11 by about 330\%. From -4\% to 4\%, strain can induce the improved ionic contribution to e11 of g-C3N4, and almost unchanged electronic contribution, which is different from MoS2 monolayer (the enhanced electronic contribution and reduced ionic contribution). To prohibit current leakage, a piezoelectric material should be a semiconductor, and g-C3N4 monolayer is always a semiconductor in considered strain range. Calculated results show that the gap increases from compressive strain to tensile one. At 4\% strain, the first and second valence bands cross, which has important effect on transition dipole moment (TDM). Our works provide a strategy to achieve enhanced piezoelectric effect of g-C3N4 monolayer, which gives a useful guidence for developing efficient energy conversion devices.