Understanding dynamic voltammetry in a dissolving microdroplet

Droplet evaporation and dissolution phenomena are pervasive in both natural and artificial systems, playing crucial roles in various applications. Understanding the intricate processes involved in the evaporation and dissolution of sessile droplets is of paramount importance for applications such as...

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Bibliographic Details
Published in:Analyst (London) 2024-07, Vol.149 (15), p.3939-395
Main Authors: Rana, Ashutosh, Renault, Christophe, Dick, Jeffrey E
Format: Article
Language:English
Subjects:
Chemistry
Dichloroethane
Dissolution
Droplets
Electric contacts
Electrochemistry
Electrodes
Evaporation rate
Finite element method
Impact analysis
Inkjet printing
Voltammetry
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Summary:Droplet evaporation and dissolution phenomena are pervasive in both natural and artificial systems, playing crucial roles in various applications. Understanding the intricate processes involved in the evaporation and dissolution of sessile droplets is of paramount importance for applications such as inkjet printing, surface coating, and nanoparticle deposition, etc . In this study, we present a demonstration of electrochemical investigation of the dissolution behaviour in sub-nL droplets down to sub-pL volume. Droplets on an electrode have been studied for decades in the field of electrochemistry to understand the phase transfer of ions at the oil-water interface, accelerated reaction rates in microdroplets, etc . However, the impact of microdroplet dissolution on the redox activity of confined molecules within the droplet has not been explored previously. As a proof-of-principle, we examine the dissolution kinetics of 1,2-dichloroethane droplets (DCE) spiked with 155 μM decamethylferrocene within an aqueous phase on an ultramicroelectrode ( r = 6.3 μm). The aqueous phase serves as an infinite sink, enabling the dissolution of DCE droplets while also facilitating convenient electrical contact with the reference/counter electrode (Ag/AgCl 1 M KCl). Through comprehensive voltammetric analysis, we unravel the impact of droplet dissolution on electrochemical response as the droplet reaches minuscule volumes. We validate our experimental findings by finite element modelling, which shows deviations from the experimental results as the droplet accesses negligible volumes, suggesting the presence of complex dissolution modes. We quantified the dissolution rate of sub-nL oil microdroplets in a bulk aqueous phase based on the evolution of cyclic voltammograms recorded for a redox mediation confined in the microdroplet.
ISSN:0003-2654
1364-5528
1364-5528
DOI:10.1039/d4an00299g