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Probing Local pH Change during Electrode Oxidation of TEMPO Derivative: Implication of Redox-Induced Acidity Alternation by Imidazolium-Linker Functional Groups

Authors
Yeo, JeongminKim, KyungmiKwak, Seung JaeKim, Mi SongYang, Jung HoonLee, Won BoKim, YongJooChae, JunghyunChang, Jinho
Issue Date
Mar-2024
Publisher
American Chemical Society
Citation
Analytical Chemistry, v.96, no.14, pp 5537 - 5545
Pages
9
Indexed
SCIE
SCOPUS
Journal Title
Analytical Chemistry
Volume
96
Number
14
Start Page
5537
End Page
5545
URI
https://scholarworks.bwise.kr/hanyang/handle/2021.sw.hanyang/194714
DOI
10.1021/acs.analchem.3c05796
ISSN
0003-2700
1520-6882
Abstract
The chemical degradation of 2,2,6,6-tetramethylpiperidine-1-oxyl (TEMPO)-based aqueous energy storage and catalytic systems is pH sensitive. Herein, we voltammetrically monitor the local pH (pH(local)) at a Pt ultramicroelectrode (UME) upon electro-oxidation of imidazolium-linker functionalized TEMPO and show that its decrease is associated with the greater acidity of the cationic (oxidized) rather than radical (reduced) form of TEMPO. The protons that drive the decrease in pH arise from hydrolysis of the conjugated imidazolium-linker functional group of 4-[2-(N-methylimidazolium)acetoxy]-2,2,6,6-tetramethylpiperidine-1-oxyl chloride (MIMAcO-T), which was studied in comparison with 4-hydroxyl-TEMPO (4-OH-T). Voltammetric hysteresis is observed during the electrode oxidation of 4-OH-T and MIMAcO-T at a Pt UME in an unbuffered aqueous solution. The hysteresis arises from the pH-dependent formation and dissolution of Pt oxides, which interact with pH(local) in the vicinity of the UME. We find that electrogenerated MIMAcO-T+ significantly influences pH(local), whereas 4-OH-T+ does not. Finite element analysis reveals that the thermodynamic and kinetic acid-base properties of MIMAcO-T+ are much more favorable than those of its reduced counterpart. Imidazolium-linker functionalized TEMPO molecules comprising different linking groups were also investigated. Reduced TEMPO molecules with carbonyl linkers behave as weak acids, whereas those with alkyl ether linkers do not. However, oxidized TEMPO+ molecules with alkyl ether linkers exhibit more facile acid-base kinetics than those with carbonyl ones. Density functional theory calculations confirm that OH- adduct formation on the imidazolium-linker functional group of TEMPO is responsible for the difference in the acid-base properties of the reduced and oxidized forms.
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