Graphene is an extraordinary two dimensional (2D) material with superior electronic and mechanical properties. Due to its exceptional physical properties, graphene became a building block in different applications, such as nano-electronics, electro-mechanical sensors, and switches. Nano- and atomic-scale devices need high precision in material maneuvering. In this regard, helium ion milling (HIM)with a beam diameter of 0.25 nm is a promising fabrication technology for precisely controlled Graphene-based nano- and atomic-scale devices.
Despite its great advantage, imaging effect (due to He⁺ ions interaction with graphene sheet) and substrate effect (due to He⁺ ion interaction with substrate) are the main challenges facing the use of HIM technology for nano-scale graphene devices. Substrate effects such as ion forward scattering, backscattering, substrate swelling possibly can be mitigated to some extent by suspending graphene before milling. However, the minimum non-destructive dose for imaging is challenging due to the trade-off between the signal to noise ratio [1]. In this work, we investigate the imaging induced defects in by studying the evolution of stress-induced in graphene cantilever.