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All Outputs (3)

A label-free aptamer-based nanogap capacitive biosensor with greatly diminished electrode polarization effects (2019)
Journal Article
Ghobaei Namhil, Z., Kemp, C., Verrelli, E., Iles, A., Pamme, N., Adawi, A. M., & Kemp, N. (2019). A label-free aptamer-based nanogap capacitive biosensor with greatly diminished electrode polarization effects. Physical chemistry chemical physics : PCCP, 21(2), 681-691. https://doi.org/10.1039/c8cp05510f

A significant impediment to the use of impedance spectroscopy in bio-sensing is the electrode polarization effect that arises from the movement of free ions to the electrode-solution interface, forming an electrical double layer (EDL). The EDL screen... Read More about A label-free aptamer-based nanogap capacitive biosensor with greatly diminished electrode polarization effects.

Nanogap capacitive biosensor for label-free aptamer-based protein detection (2018)
Thesis
Namhil, Z. G. (2018). Nanogap capacitive biosensor for label-free aptamer-based protein detection. (Thesis). University of Hull. Retrieved from https://hull-repository.worktribe.com/output/4220514

Recent advances in nanotechnology offer a new platform for the label free detection of biomolecules at ultra-low concentrations. Nano biosensors are emerging as a powerful method of improving device performance whilst minimizing device size, cost and... Read More about Nanogap capacitive biosensor for label-free aptamer-based protein detection.

Surface enhanced Raman spectroscopy for single molecule detection and biosensing (2017)
Thesis
Marshall, A. R. L. (2017). Surface enhanced Raman spectroscopy for single molecule detection and biosensing. (Thesis). University of Hull. Retrieved from https://hull-repository.worktribe.com/output/4220864

The aim of this thesis is to design plasmonic nano-gaps capable of detecting materials down to sufficiently low concentrations such that single molecule characteristics are observed. We begin first, by discussing the theory of plasmonics. Then, we as... Read More about Surface enhanced Raman spectroscopy for single molecule detection and biosensing.