Mechanically Stable Ultrathin Layered Graphene Nanocomposites Alleviate Residual Interfacial Stresses: Implications for Nanoelectromechanical Systems.
Peter V CoveneyWerner A MüllerJames L SuterAravind VijayaraghavanPeter V CoveneyPublished in: ACS applied nano materials (2022)
Advanced nanoelectromechanical systems made from polymer dielectrics deposited onto 2D-nanomaterials such as graphene are increasingly popular as pressure and touch sensors, resonant sensors, and capacitive micromachined ultrasound transducers (CMUTs). However, durability and accuracy of layered nanocomposites depend on the mechanical stability of the interface between polymer and graphene layers. Here we used molecular dynamics computer simulations to investigate the interface between a sheet of graphene and a layer of parylene-C thermoplastic polymer during large numbers of high-frequency (MHz) cycles of bending relevant to the operating regime. We find that important interfacial sliding occurs almost immediately in usage conditions, resulting in more than 2% expansion of the membrane, a detrimental mechanism which requires repeated calibration to maintain CMUTs accuracy. This irreversible mechanism is caused by relaxation of residual internal stresses in the nanocomposite bilayer, leading to the emergence of self-equilibrated tension in the polymer and compression in the graphene. It arises as a result of deposition-polymerization processing conditions. Our findings demonstrate the need for particular care to be exercised in overcoming initial expansion. The selection of appropriate materials chemistry including low electrostatic interactions will also be key to their successful application as durable and reliable devices.
Keyphrases
- carbon nanotubes
- molecular dynamics
- high frequency
- reduced graphene oxide
- room temperature
- walled carbon nanotubes
- transcranial magnetic stimulation
- molecular dynamics simulations
- ionic liquid
- healthcare
- density functional theory
- magnetic resonance imaging
- low cost
- highly efficient
- palliative care
- quality improvement
- computed tomography
- mass spectrometry
- chronic pain
- high efficiency
- transition metal
- tandem mass spectrometry
- energy transfer