Temporally Resolved Electrochemical Interrogation for Stochastic Collision Dynamics of Electrogenerated Single Polybromide Droplets
- Authors
- Choi, Yejin; Park, Cheonho; Kang, Yumin; Muya, Jules Tshishimbi; Jang, Dong Pyo; Chang, Jinho
- Issue Date
- Jun-2021
- Publisher
- American Chemical Society
- Citation
- Analytical Chemistry, v.93, no.23, pp 8336 - 8344
- Pages
- 9
- Indexed
- SCIE
SCOPUS
- Journal Title
- Analytical Chemistry
- Volume
- 93
- Number
- 23
- Start Page
- 8336
- End Page
- 8344
- URI
- https://scholarworks.bwise.kr/hanyang/handle/2021.sw.hanyang/141597
- DOI
- 10.1021/acs.analchem.1c01366
- ISSN
- 0003-2700
1520-6882
- Abstract
- In this article, we present electrochemical interrogation for collision dynamics of electrogenerated individual polybromide ionic liquid (PBIL) droplets through chronoamperometry combined with fast scan cyclic voltammetry (CA-FSCV). In the CA mode of CA-FSCV, a Pt ultramicroelectrode (UME) acts as the electrochemical generator for PBIL droplets by holding the oxidation potential for Br- in a given time, while FSCV is repetitively performed at a certain frequency. In the FSCV mode of CA-FSCV, a Pt UME serves as the probe to electrochemically monitor Br-3(-) reduction for an adsorbed PBIL droplet during collision with a high temporal resolution. Based on the newly introduced CA-FSCV, we can estimate the dynamic changes in the following parameters for a short collision time: the contact radius of a PBIL droplet on a Pt UME, the concentration of Br- in the droplet, and the apparent charge transfer rate constant for electro-reduction of Br(3)(- )to Br- in the droplet, k(app)(o). Moreover, a computational calculation using molecular dynamics is presented that can explain the change in k(app)(o) as a function of time for Br(-)electrolysis in a PBIL droplet. Based on the quantitative estimation of the above parameters, we suggest a more advanced mechanism for the stochastic electrochemical collision process of a PBIL droplet. These findings are important for understanding QBr(2n+1)/QBr half redox reactions in aqueous energy storage systems, such as Zn-Br redox flow batteries and Br-related redox enhanced electrochemical capacitors.
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