Symmetry, Vol. 16, Pages 1524: Co-Dominant Piezoelectric and Flexoelectric Effects in Twisted Double Bilayer Graphene

Symmetry, Vol. 16, Pages 1524: Co-Dominant Piezoelectric and Flexoelectric Effects in Twisted Double Bilayer Graphene

Symmetry doi: 10.3390/sym16111524

Authors: Yuanhao Wei Yuhao Li Hanhao Zhang Shengsheng Lin Takashi Taniguchi Kenji Watanabe Cun-Fa Gao Yan Shi

Controlling the balance between piezoelectric and flexoelectric effects is crucial for tailoring the electromechanical responses of a material. In twisted graphene, it is found that the electromechanical response near the domain walls (DWs) is dominated by either the flexoelectric effect as in twisted bilayer graphene (tBLG) or the piezoelectric effect as in twisted monolayer–bilayer graphene (tMBG). The codominance of both effects in a single system is rare. Here, utilizing lateral piezoresponse force microscopy (LPFM), we show that piezoelectric and flexoelectric effects can coexist and are equally important in twisted double bilayer graphene (tDBG), termed as the piezo-flexoelectric effect. Unlike tBLG and tMBG, distinctive two-step LPFM spatial profiles are captured across the moiré DWs of tDBG. By decomposing the LPFM signal into axisymmetric and antisymmetric components, we find that the angular dependence of both components satisfies sinusoidal relations. Quantitatively, the in-plane piezoelectric coefficient of DWs in tDBG is determined to be 0.15 pm/V by dual AC resonance tracking (DART) LPFM measurement. The conclusion is further supported by continuum mechanics simulations. Our results demonstrate that the stacking configuration serves as a powerful tuning knob for modulating the electromechanical responses of twisted van der Waals materials.