Potential-Controlled Adsorption, Separation, and Detection of Redox Species in Nanofluidic Devices | Zendy

Jin Cui | Zendy; Klaus Mathwig | Zendy; Dileep Mampallil | Zendy; Serge G. Lemay | Zendy

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Potential-Controlled Adsorption, Separation, and Detection of Redox Species in Nanofluidic Devices

Author(s) -

Jin Cui,

Klaus Mathwig,

Dileep Mampallil,

Serge G. Lemay

Publication year - 2018

Publication title -

analytical chemistry

Language(s) - English

Resource type - Journals

SCImago Journal Rank - 2.117

H-Index - 332

eISSN - 1520-6882

pISSN - 0003-2700

DOI - 10.1021/acs.analchem.8b01719

Subject(s) - chemistry , redox , adsorption , electrochemistry , electrode , confined space , microfluidics , nanoscopic scale , volume (thermodynamics) , nanotechnology , chemical physics , analytical chemistry (journal) , chromatography , inorganic chemistry , thermodynamics , materials science , organic chemistry , physics

Nanoscale channels and electrodes for electrochemical measurements exhibit extreme surface-to-volume ratios and a correspondingly high sensitivity to even weak degrees of surface interactions. Here, we exploit the potential-dependent reversible adsorption of outer-sphere redox species to modulate in space and time their concentration in a nanochannel under advective flow conditions. Induced concentration variations propagate downstream at a species-dependent velocity. This allows one to amperometrically distinguish between attomole amounts of species based on their time-of-flight. On-demand concentration pulse generation, separation, and detection are all integrated in a miniaturized platform.

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