Overcoming passivation through improved mass transport in dense ionic fluids†

IF 3.4 3区 化学 Q2 Chemistry
Evangelia Daskalopoulou, Philip Hunt, Christopher E. Elgar, Minjun Yang, Andrew P. Abbott and Jennifer M. Hartley
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Abstract

Deep Eutectic Solvents (DESs) have recently been shown to be part of a dense ionic fluid continuum between ionic liquids and concentrated aqueous brines. Charge transport was shown to be governed by fluidity, with no discontinuity between molar conductivity and fluidity irrespective of cation, charge density or ionic radius. By adjusting the activity of water and chloride ions, mass transport, speciation and reactivity can be altered. It has been shown that while brines provide a high chloride content at a lower viscosity than DESs, unlike DESs, brines are unable to prevent metal passivation due to their high water content. This results in the possibility to impart a level of selectivity towards metal dissolution (or passivation) when processing mixed metal materials. Forced convection can be used to avoid the issue of slow mass transport in viscous media, and the use of jets or targeted ultrasound are effective methods for overcoming this issue. High-powered ultrasound was applied to copper, cobalt, and aluminium electrodes undergoing anodic dissolution, and linear sweep voltammetry showed a linear current–voltage response at potentials anodic of the oxidation potential under sonication, with total charge passed being 5 to 134 times greater than under silent conditions. Application of ultrasound to silver and nickel electrodes displayed an initial linear current–voltage response, but the increased water content of the brines resulted in passivation. Mass transport throughout the bulk solution is governed by the forced convection imparted by the ultrasound and ionic species must only migrate across the electrical double layer. It is shown that the anodic dissolution of a range of metals classically expected to passivate, e.g. aluminium, can be significantly accelerated under insonation conditions.

Abstract Image

通过改善致密离子液体中的质量传输克服钝化现象
最近的研究表明,深共晶溶剂(DES)是介于离子液体和浓盐水之间的高密度离子液体连续体的一部分。电荷传输受流动性支配,无论阳离子、电荷密度或离子半径如何,摩尔电导率与流动性之间都没有不连续性。通过调整水和氯离子的活度,可以改变质量传输、离子和反应性。研究表明,与 DES 相比,盐水的粘度较低,但氯离子含量较高,与 DES 不同的是,盐水由于含水量高,无法防止金属钝化。因此,在处理混合金属材料时,可以对金属溶解(或钝化)进行一定程度的选择。强制对流可用于避免粘性介质中质量传输缓慢的问题,而使用喷流或定向超声则是克服这一问题的有效方法。将大功率超声波应用于发生阳极溶解的铜、钴和铝电极,线性扫描伏安法显示,在超声作用下,氧化电位的阳极电位出现线性电流-电压响应,通过的总电荷量是静默条件下的 5 至 134 倍。在银电极和镍电极上应用超声波可显示出最初的线性电流-电压响应,但盐水含水量的增加导致了钝化。整个溶液的质量传输受超声波所产生的强制对流控制,离子物种只能穿过电双层进行迁移。研究表明,在电离条件下,一系列通常被认为会钝化的金属(如铝)的阳极溶解会明显加快。
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来源期刊
Faraday Discussions
Faraday Discussions CHEMISTRY, PHYSICAL-
CiteScore
4.90
自引率
0.00%
发文量
259
审稿时长
2.8 months
期刊介绍: Discussion summary and research papers from discussion meetings that focus on rapidly developing areas of physical chemistry and its interfaces
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