Multiscale Molecular Dynamics and Quantum–Electrostatic Modelling of Graphene Electric Double-Layer Transistors for β2-Microglobulin Biosensing
Ghassem Baridi, Arslan Liaquat, Leonardo Martini, Federico Rapuzzi, Herath Mudiyanselage Kasun Gayanga Anuradha Herath, El Hadj Abidi, Maria Celeste Maschio, Vito Clericò, Yahya Moubarak Meziani, Mario Amado, Enrique Diez, Stefano Corni, Giorgia Brancolini, Luigi Rovati, Francesco RossellaBiosensors are rapidly emerging as a pivotal technology with far-reaching implications in fields such as medical diagnostics, environmental analysis and pharmaceutical research. Among the various biosensing platforms, Graphene Field-Effect Transistor (GFET) biosensors have attracted considerable interest due to their exceptional sensitivity, potential for cost-efficient fabrication, and compatibility with scalable manufacturing processes. This work computationally addresses sensing mechanisms and design strategies associated with GFET-based biosensors, with a focus on the influence of electrolyte gating on device performance, tackling the role of graphene’s quantum capacitance and testing the electrical detection of β2-microglobulin as a case study. Molecular dynamics is used to rationalize the details of the physisorption of a single biomolecule onto the graphene surface, while finite element method simulations are employed to evaluate device sensitivity and figure of merit. Results reveal that incorporating quantum capacitance into the model leads to a Sensitivity-over-FWHM_min figure of merit exceeding 100 L/g being achievable for a β2-microglobulin concentration of 0.001 g/L. These computational outcomes highlight the relevance of quantum-electrostatic effects in GFET biosensor performance and suggest potential routes towards the optimization of graphene-based electronic biodetector engineering.