Extraction of hydrophobic analytes from organic solution into a titanate 2D-nanosheet host: Electroanalytical perspectives

IF 2.5 Q1 Chemistry Analytica Chimica Acta: X Pub Date : 2019-03-01 DOI:10.1016/j.acax.2018.100001
Wulan Tri Wahyuni , Budi Riza Putra , Christian Harito , Dmitry V. Bavykin , Frank C. Walsh , Philip J. Fletcher , Frank Marken
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引用次数: 5

Abstract

Titanate nanosheets (single layer, typically 200 nm lateral size) deposited from aqueous colloidal solution onto electrode surfaces form lamellar hosts that bind redox active molecular redox probes. Here, hydrophobic redox systems such as anthraquinone, 1-amino-anthraquinone, deca-methylferrocene, 5,10,15,20-tetraphenyl-21H,23H-porphine manganese (III) chloride (TPPMnCl), and α-tocopherol are shown to bind directly from cyclopentanone solution (and from other types of organic solvents) into the titanate nanosheet film. For anthraquinone derivatives, stable voltammetric responses are observed in aqueous media consistent with 2-electron 2-proton reduction, however, independent of the pH of the outside solution phase environments. For decamethylferrocene a gradual decay of the voltammetric response is observed, but for TPPMnCl a more stable voltammetric signal is seen when immersed in chloride containing (NaCl) electrolyte. α-Tocopherol exhibits chemically irreversible oxidation and is detected with 1 mM–20 mM linear range and approximately 10−3 M concentration limit of detection. All redox processes exhibit an increase in current with increasing titanate film thickness and with increasing external electrolyte concentration. This and other observations suggest that important factors are analyte concentration and mobility within the titanate host, as well as ion exchange between titanate nanosheets and the outside electrolyte phase to maintain electroneutrality during voltammetric experiments. The lamellar titanate (with embedded tetrabutyl-ammonium cations) behaves like a hydrophobic host (for hydrophobic redox systems) similar to hydrophobic organic microphase systems. Potential for analytical applications is discussed.

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从有机溶液中提取疏水分析物到钛酸盐2d纳米片宿主:电分析的观点
钛酸盐纳米片(单层,横向尺寸通常为200 nm)从水性胶体溶液沉积到电极表面,形成层状宿主,结合氧化还原活性分子氧化还原探针。研究表明,蒽醌、1-氨基蒽醌、十甲基二茂铁、5,10,15,20-四苯基- 21h、23h -卟啉锰(III)氯(TPPMnCl)和α-生育酚等疏水氧化还原体系可以直接从环戊酮溶液(以及其他类型的有机溶剂)中结合到钛酸盐纳米片薄膜中。对于蒽醌衍生物,在水介质中观察到稳定的伏安反应,符合2电子2质子还原,但与外部溶液环境的pH无关。对于十甲基二茂铁,观察到伏安响应逐渐衰减,但对于TPPMnCl,当浸入含氯(NaCl)电解质时,可以看到更稳定的伏安信号。α-生育酚表现为化学不可逆氧化,检测范围为1 mM - 20 mM,检测浓度限约为10−3 M。随着钛酸盐膜厚度的增加和外部电解质浓度的增加,所有氧化还原过程都表现出电流的增加。这和其他观察结果表明,重要的因素是分析物浓度和钛酸盐宿主体内的迁移率,以及钛酸盐纳米片与外部电解质相之间的离子交换,以在伏安实验中保持电中性。层状钛酸盐(带有嵌入的四丁基铵阳离子)的行为类似于疏水有机微相系统的疏水宿主(用于疏水氧化还原系统)。讨论了分析应用的潜力。
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来源期刊
Analytica Chimica Acta: X
Analytica Chimica Acta: X Chemistry-Analytical Chemistry
自引率
0.00%
发文量
3
审稿时长
16 weeks
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Editorial Board Outside Front Cover Reconciling the pHe measurements of bioethanol: pHabs measurements of buffered 50-50 wt% water-ethanol mixtures Outside Front Cover Editorial Board
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