Detection of nucleotides via (recognition) tunneling with noble metal break junctions show promising results; however, the bulky nature and a range of physical and chemical instabilities of the electrodes prevent advancing toward long-read sequencing with single base-calling accuracy. Graphene edges as tunnel electrodes may overcome these limitations, with the possibility to reach true single-molecule readout, thanks to their 2D-nature. Currently, the development of graphene tunnel sequencers face challenges in terms of targeted chemical functionalization of the graphene edge, to enable recognition tunneling, and the eventual integration in a nanopore configuration to realize long-read sequencing of biopolymers. The dissertation tackles the possibility of achieving targeted chemical functionalization in a device architecture suitable for recognition tunneling and investigates the ability to characterize molecules attached on graphene through surface-enhanced Raman spectroscopy.

• chemistry
• graphene
• materials science
• nanotechnology
• raman
• tunneling

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