Garcia-Sanchez D, van der Zande A M, Paulo A San, Lassagne B, McEuen P L, Bachtold A
CIN2 Barcelona, Campus UAB, E-08193 Bellaterra, Spain.
Nano Lett. 2008 May;8(5):1399-403. doi: 10.1021/nl080201h. Epub 2008 Apr 11.
We carried out measurements on nanoelectromechanical systems based on multilayer graphene sheets suspended over trenches in silicon oxide. The motion of the suspended sheets was electrostatically driven at resonance using applied radio frequency voltages. The mechanical vibrations were detected using a novel form of scanning probe microscopy, which allowed identification and spatial imaging of the shape of the mechanical eigenmodes. In as many as half the resonators measured, we observed a new class of exotic nanoscale vibration eigenmodes not predicted by the elastic beam theory, where the amplitude of vibration is maximum at the free edges. By modeling the suspended sheets with the finite element method, these edge eigenmodes are shown to be the result of nonuniform stress with remarkably large magnitudes (up to 1.5 GPa). This nonuniform stress, which arises from the way graphene is prepared by pressing or rubbing bulk graphite against another surface, should be taken into account in future studies on electronic and mechanical properties of graphene.
我们对基于悬浮在氧化硅沟槽上的多层石墨烯片的纳米机电系统进行了测量。使用施加的射频电压在共振时静电驱动悬浮片的运动。使用一种新型扫描探针显微镜检测机械振动,该显微镜能够识别机械本征模的形状并进行空间成像。在多达一半的测量谐振器中,我们观察到一类新的奇异纳米级振动本征模,这是弹性梁理论未预测到的,其振动幅度在自由边缘处最大。通过用有限元方法对悬浮片进行建模,这些边缘本征模被证明是具有非常大的量级(高达1.5吉帕斯卡)的非均匀应力的结果。这种非均匀应力源于通过将块状石墨压在或摩擦另一个表面来制备石墨烯的方式,在未来关于石墨烯的电子和机械性能的研究中应予以考虑。