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Photoswitchable Binary Nanopore Conductance and Selective Electronic Detection of Single Biomolecules under Wavelength and Voltage Polarity Control

J. T. Hagan, Alejandra Gonzalez, Yuran Shi, Grace G. D. Han, Jason R. Dwyer

2022ACS Nano14 citationsDOIOpen Access PDF

Abstract

We fabricated photoregulated thin-film nanopores by covalently linking azobenzene photoswitches to silicon nitride pores with ∼10 nm diameters. The photoresponsive coatings could be repeatedly optically switched with deterministic ∼6 nm changes to the effective nanopore diameter and of ∼3× to the nanopore ionic conductance. The sensitivity to anionic DNA and a neutral complex carbohydrate biopolymer (maltodextrin) could be photoswitched "on" and "off" with an analyte selectivity set by applied voltage polarity. Photocontrol of nanopore state and mass transport characteristics is important for their use as ionic circuit elements (e.g., resistors and binary bits) and as chemically tuned filters. It expands single-molecule sensing capabilities in personalized medicine, genomics, glycomics, and, augmented by voltage polarity selectivity, especially in multiplexed biopolymer information storage schemes. We demonstrate repeatedly photocontrolled stable nanopore size, polarity, conductance, and sensing selectivity, by illumination wavelength and voltage polarity, with broad utility including single-molecule sensing of biologically and technologically important polymers.

Topics & Concepts

NanoporePolarity (international relations)ConductanceBiomoleculeMaterials scienceNanotechnologyBinary numberWavelengthOptoelectronicsChemistryPhysicsCondensed matter physicsMathematicsArithmeticCellBiochemistryNanopore and Nanochannel Transport StudiesPhotoreceptor and optogenetics researchPhotochromic and Fluorescence Chemistry
Photoswitchable Binary Nanopore Conductance and Selective Electronic Detection of Single Biomolecules under Wavelength and Voltage Polarity Control | Litcius