The researchers fabricated and characterized three types of graphene ribbon devices with suspended silicon proof masses: two ribbons, four ribbons in a cross configuration, and four ribbons in a parallel configuration. They measured the dynamic mechanical properties of these devices, including resonance frequencies, quality factors, and spring constants, using laser Doppler vibrometry. The results showed that the four-ribbon devices generally had higher resonance frequencies and spring constants, but lower built-in stresses compared to the two-ribbon devices under otherwise identical conditions.
The researchers also performed static mechanical characterization of the four-ribbon devices using atomic force microscope (AFM) indentation experiments. They found that the graphene ribbons could withstand an indentation force of up to 5368.5 nN before rupturing. By combining the experimental data with finite element analysis simulations, the researchers were able to accurately determine the Young's modulus of the double-layer graphene to be around 0.34 TPa, which is lower than the commonly reported value of 1 TPa for monolayer graphene. They also estimated the fracture strain of the graphene ribbons to be around 1.13%.
These results provide valuable insights into the mechanical properties and fracture behavior of graphene ribbons with suspended proof masses, which are important for the development of nanoelectromechanical systems (NEMS) applications.
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arxiv.org
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by Xuge Fan, Ch... : arxiv.org 10-03-2024
https://arxiv.org/pdf/2410.01462.pdfDaha Derin Sorular