This new platform could potentially be used for electronic fingerprinting of biomolecules, from DNA to proteins, which in turn can have important implications for the diagnosis and treatment of diseases. The research was partly funded by the Graphene Flagship.
Nanogaps separating two electrodes are envisaged as the basis for the next generation of sensing technologies. The aim is to exploit quantum electron tunneling as the sensing principle, in which the electronic structure of the target molecule trapped in the nanogap is directly probed. Graphene, a monolayer of carbon atoms in a hexagonal lattice, combines many of the requisites for an electrical sensor material: high conductivity, atomic thinness, flexibility, chemical inertness in air and liquid, and mechanical strength, as well as its compatibility with standard lithographic patterning techniques.
At the Kavli Institute of Nanoscience in Delft, a research group is developing robust graphene-based mechanically controlled break junctions (MCBJs), which allow the formation of a size-adjustable tunnelling gap at the sub-nanometre scale, i.e. the size can be tailored to the size of the biomolecule to be probed.
The MCBJ experiment is conceptually very simple. The device consists of a graphene bowtie structure supported on a flexible metal substrate. The substrate is gradually bent, causing stretching of the graphene. This graphene bridge eventually breaks and a nanoscopic gap is formed. Importantly, the junction conductance can be reversibly switched by almost six orders of magnitude during 1,000 opening-closing cycles; i.e. it acts as an electrical switch that can be turned on-off mechanically. The impressive mechanical stability allows for the collection of statistically significant data, capturing various behaviours of the junctions over time and in different environments (e.g. different molecule orientations, in air, vacuum, liquid).
In collaboration with the theory group led by Prof Jaime Ferrer at the University of Oviedo (Spain), the researchers also confirmed the interference of electron waves during measurements in air at room temperature. The findings are an important step for both fundamental physics and for future applications of graphene as an electromechanical switch or biosensing platform.
The graphene MCBJ is a unique device that is on the one hand a model system for studying quantum transport at room temperature, and on the other can be a powerful sensing tool to probe biomolecules with very high resolution. The researchers are currently exploring the potential of this platform for electronic fingerprinting of biomolecules, including amino acids and short peptides: the aim is to discriminate molecules with slight chemical difference according to their electronic structure, which can be ‘read’ when the molecules are trapped in the nanogap. This would provide the first steps into ‘tunneling-based’ biosensing with graphene, an compelling vision at the Departments of Quantum and Bionanoscience at TU Delft.
Megaohmmeters op batterijen. Het aanbod werkplaatsuitrusting van TME omvat onder meer professionele apparaten van Fluke.…
De HCX oliepeilglazen van Elesa+Ganter bieden een geavanceerde oplossing voor industrieel onderhoud en productie. Deze…
Een kleinschalig en compact apparaat, Fuze, gebouwd door de Amerikaanse startup Zap Energy heeft plasma…
Al 15 jaar is het Festo Bionic Learning Network gefascineerd door vliegen. Het team heeft…
Kwantummechanische verschijnselen zoals radioactief verval, of algemener: ‘tunnelen’, vertonen intrigerende wiskundige patronen. Twee onderzoekers aan…
Een nieuwe ultragevoelige glasvezelsensor kan deeltjes met een diameter tot 50 nanometer detecteren. In de…