Béraud A. Fonctionnalisation de transistors à effet de champ à base de graphène : vers l’assemblage d’une interface de détection biologique contrôlée. (Functionalization of graphene field-effect transistors: towards the controlled assembly of a biorecognition interface.) Master thesis, Université de Montréal, 2022

 

 

 

Abstract

Nanoscale electronics are a promising tool for biosensing as they fit their target’s size and allow for local, fast-paced measurements over long time scales. Because of their exceptional electronic properties, graphene field-effect transistors (GFETs) are excellent candidates for biosensing and studying molecular kinetics. This work discusses the analysis, measurement, and functionalization of GFETs as optimized biosensors. In the introduction, we describe the electronic properties of graphene and the main concepts related to GFETs and biodetection. We also establish the three aims of the project, elaborated in three chapters. The first chapter contains a critical literature review that uses original analyses and a thorough state-of-the-field to target statistical analysis and the biorecognition interface assembly as determining factors in sensing performance. In the second chapter, we present the practical adjustments to the experimental systems based on the review’s recommendations. First, we increase the productivity of device fabrication, then we develop a multiplexed electrical measurement setup. In the third chapter, we take advantage of these modifications to present in the second article a method for stable and controlled functionalization. Using the gate voltage, we start and stop the covalent functionalization of graphene with aryldiazonium salts to get the desired grafting level, while observing the reaction in real-time. Thus, with our advances in methodology and instrumentation, we solve a critical aspect of surface chemistry, central for biodetection performance

This content has been updated on 11 September 2025 at 17h33.