利用石英音叉（QTF）传感器技术研究伽马射线照射对水溶液中二价 Ca2+ 和 Pb2+ 离子的吸附和去除作用

IF 5.8 2区化学 Q1 CHEMISTRY, MULTIDISCIPLINARY

Journal of Saudi Chemical Society Pub Date : 2024-10-02 DOI:10.1016/j.jscs.2024.101947

Reem Alanazi , Shofiur Rahman , Mahmoud Al-Gawati , Khalid E. Alzahrani , Nahed Alarifi , Nadyah Alanazi , Abdullah N. Alodhayb

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引用次数: 0

摘要

在这项研究中，利用吸附行为和辐射效应，使用了金涂层石英音叉（QTFs）传感装置，该传感装置具有下缘功能化钙[4]炔甲氧基酯自组装单层（SAM），用于检测水溶液中的二价钙[4]炔和铅[4]炔离子。金涂层 QTF 功能化钙[4]烯甲氧基酯传感装置通过测量两种不同浓度（10-6 M 和 10-4 M）的氯化铅水溶液小样本（60 µL）获得的各自频移进行了测试。对于 10-4 M 的氯化铅溶液，结果显示共振频率偏移 Δf = 317 Hz，从 32,867 Hz (fCalix) 到 32、550 Hz (fCalix⊃Pb2+)，这是由于 QTF 传感层上的 Calixl[4]arene 甲氧基酯受体分子吸收了来自水溶液的铅（Pb2+）离子（10-4 M），形成了（[Calix ⊃Pb2+]）复合物。在浓度为 10-6 M CaCl2 时，频率变化最为明显，CaCl2 的频率变化最大，从 32,893 Hz（fCalix）变为 32,537 Hz（fCalix⊃Ca2+），达到 356 Hz，而 PbCl2（10-4 M）的频率变化为 317 Hz。CaCl2的检测限为100飞摩尔（fM），PbCl2的检测限为245飞摩尔。然后，我们用来自铯-137 源的 7.5 至 50 µGy 伽马射线辐照 QTF 传感层上含有 Pb2+ 离子复合物（[calix ⊃Pb2+]）的受体分子 30 分钟。有趣的是，共振频率（Δf = 54 Hz）从 32,550 Hz（f(calix⊃Pb2+)）回落到 32,604 Hz，这有力地表明由于伽马辐射剂量，Pb2+ 离子从 QTF 传感层上的（[calix⊃Pb2+]）复合物中移除。为了跟踪（[calix ⊃Pb2+]）对 QTF 传感层的辐射效应，我们停止了伽马辐射源，并继续保持 10 分钟，以观察是否存在共振频率。结果发现，在停止伽马辐射源 10 分钟后，共振频率从 32,604 Hz 变回了 32,637 Hz（Δf = 33 Hz）。我们假定络合物（[calix ⊃Pb2+]）吸收了伽马射线，并继续从传感层上的络合物中清除 Pb2+ 离子。QTF 传感层上的钙[4]炔甲氧基酯受体分子从水溶液中吸收铅（Pb2+）离子（10-6 M），形成（[钙钛矿 ≌ Pb2+]）络合物，也观察到类似的现象。由于 QTF 传感层上的钙[4]炔甲氧基酯受体分子从水溶液中吸收了铅（Pb2+）离子（10-6 M），形成了（[Calix ⊃Pb2+]）复合物，共振频率从 32 706 Hz（fCalix）移动到 32 564 Hz（fCalix⊃Pb2+），共振频率Δf = 142 Hz。随后，铯-137 辐射源将伽马射线照射 30 分钟，剂量从 7.5 到 50 µGy 不等，这促使共振频率从 32,564 Hz（f(Calix⊃Pb2+)）回落到 32,606 Hz（Δf = 37 Hz）。这一变化强烈表明，由于伽马辐射剂量的作用，Pb2+ 离子从 QTF 传感层上的（[calix ⊃Pb2+]）复合物中移除。X 射线光电子能谱（XPS）分析证实了 Pb2+ 离子在金涂层 QTF 功能化 calix[4]arene 吸附传感层表面的化学吸附。因此，钙[4]烯功能化传感装置的基础技术有望应用于多种工业领域，并通过所提出的吸附和辐照机理支持水污染减缓方面的潜在进步。

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Investigating adsorption and removal of divalent Ca2+ and Pb2+ ions from aqueous solutions by gamma-irradiation using quartz tuning fork (QTF) sensor technique

In this study, gold-coated quartz tuning forks (QTFs) sensing devices functionalized with self-assembled monolayers (SAM) of a lower-rim functionalized calix[4]arene methoxy ester were used for the detection of divalent Ca²⁺ and Pb²⁺ ions in aqueous solutions by utilizing adsorption behavior and the radiative effect. The gold-coated QTF functionalized calix[4]arene methoxy ester sensing device was tested by measuring the respective frequency shifts obtained using small (60 µL) samples of aqueous PbCl₂ at two different concentrations (10⁻⁶ and 10⁻⁴ M). For 10⁻⁴ M solutions of PbCl₂, results showed that the resonance frequency shift Δf = 317 Hz, from 32,867 Hz (f_Calix) to 32,550 Hz (f_{Calix⊃Pb²⁺}) due to the absorption of lead (Pb²⁺) ions (10^-4 M) by calixl[4]arene methoxy ester receptor molecules on the QTF sensing layer from the aqueous solution to forming the ([Calix ⊃ Pb²⁺]) complex. The most significant frequency changes were observed at a concentration of 10⁻⁶ M CaCl₂, where CaCl₂ exhibited the biggest change of 356 Hz, from 32,893 Hz (f_Calix) to 32,537 Hz (f_{Calix⊃Ca²⁺}), compared to 317 Hz for PbCl₂ (10⁻⁴ M). The limit of detection was 100 femtomolar (fM) for CaCl₂ and 245 fM for PbCl₂. After that, we irradiated the receptor molecules which was holding Pb²⁺ ions in the complex ([calix ⊃ Pb²⁺]) on the QTF sensing layer with a radiation dose ranging from 7.5 to 50 µGy of gamma rays from the Cesium-137 source for 30 min. Interestingly, it was observed that the resonance frequency shift (Δf = 54 Hz) back to 32,604 Hz from 32,550 Hz (f_{(Calix⊃Pb²⁺)}), which strongly suggests that the Pb²⁺ ion removed from ([calix ⊃ Pb²⁺]) complex on the QTF sensing layer due to gamma radiation dose. To follow up on the radiation effect of the ([calix ⊃ Pb²⁺]) on the QTF sensing layer, we stopped the gamma radiation source and kept it for an additional 10 min to see if there was any resonance frequency. It was noticed that an additional resonance frequency shifted (Δf = 33 Hz) back to 32,637 Hz from 32,604 Hz after stopping the gamma radiation source for 10 min. We assume that the complex ([calix ⊃ Pb²⁺]) absorbs the gamma radiation and continues the removal of Pb²⁺ ions from the complex on the sensing layer. A similar phenomenon was also observed for the absorption of lead (Pb²⁺) ions (10^-6 M) by calix[4]arene methoxy ester receptor molecules on the QTF sensing layer from the aqueous solution to forming the ([Calix ⊃ Pb²⁺]) complex. The resonance frequency shift Δf = 142 Hz, from 32,706 Hz (f_Calix) to 32,564 Hz (f_{Calix⊃Pb²⁺}) due to the absorption of lead (Pb²⁺) ions (10^-6 M) by calix[4]arene methoxy ester receptor molecules on the QTF sensing layer from the aqueous solution to forming the ([Calix ⊃ Pb²⁺]) complex. Subsequent exposure to gamma radiation, with doses ranging from 7.5 to 50 µGy from a Cesium-137 source over 30 min, prompted a resonance frequency shift (Δf = 37 Hz) back to 32,606 Hz from 32,564 Hz (f_{(Calix⊃Pb²⁺)}). This shift strongly suggests the removal of Pb²⁺ ions from the ([calix ⊃ Pb²⁺]) complex on the QTF sensing layer due to gamma radiation dose. X-ray photoelectron spectroscopy (XPS) analysis confirmed the chemical adsorption of Pb²⁺ ions onto the gold-coated QTFs functionalized calix[4]arene adsorbent sensing layer surface. Therefore, the technology underlying the calix[4]arene-functionalized sensing device holds promise for diverse industrial applications, supporting potential advancements in water pollution mitigation through the proposed adsorption and irradiation mechanism.

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来源期刊

Journal of Saudi Chemical Society CHEMISTRY, MULTIDISCIPLINARY-

CiteScore

8.90

自引率

1.80%

发文量

120

审稿时长

38 days

期刊介绍： Journal of Saudi Chemical Society is an English language, peer-reviewed scholarly publication in the area of chemistry. Journal of Saudi Chemical Society publishes original papers, reviews and short reports on, but not limited to: •Inorganic chemistry •Physical chemistry •Organic chemistry •Analytical chemistry Journal of Saudi Chemical Society is the official publication of the Saudi Chemical Society and is published by King Saud University in collaboration with Elsevier and is edited by an international group of eminent researchers.