期刊
ACS APPLIED MATERIALS & INTERFACES
卷 15, 期 40, 页码 46812-46828出版社
AMER CHEMICAL SOC
DOI: 10.1021/acsami.3c08271
关键词
electrochemical deionization; MnO x; cation selectivity; time-dependent; hydrated radius; charge density
This study investigates the ion-selective behavior of manganese oxide (MnOx) and proposes a time-dependent multimechanism for ion selectivity. The proposed mechanisms are supported by electrochemical evidence, and an overall ion selectivity sequence is determined.
Manganese oxide is an effective active material in several electrochemical systems, including batteries, supercapacitors, and electrochemical deionization (ECDI). This work conducts a comprehensive study on the ion-selective behavior of MnOx to fulfill the emptiness in the energy and environmental science field. Furthermore, it broadens the promising application of MnOx in the ion-selective ECDI system. We propose a time-dependent multimechanism ion-selective behavior with the following guidelines by utilizing a microfluidic cell and the electrochemical quartz crystal microbalance (EQCM) analysis. (1) Hydrated radius is the most critical factor for ions with the same valence, and MnO(x )tends to capture cations with a small hydrated radius. (2) The importance of charge density rises when comparing cations with different valences, and MnOx prefers to capture divalent cations with a strong electrostatic attraction at prolonged times. Under this circumstance, ion swapping may occur where divalent cations replace monovalent cations. (3) NH4 (+) triggers MnOx dissolution, leading to performance and stability decay. The EQCM evidence has directly verified the proposed mechanisms, and these data provide a novel but simple method to judge ion selectivity preference. The overall ion selectivity sequence is Ca2+ > Mg2+ > K+ > NH4 +> Na+ > Li+ with the highest selectivity values of beta(Ca//Li) and beta(Ca//Na) around 3 at the deionization time = 10 min.
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