花形WO2I2/聚(1h -吡咯)纳米复合薄膜作为检测水中Cd2+离子的电位传感器

IF 3 Q2 MATERIALS SCIENCE, COMPOSITES

Journal of Composites Science Pub Date : 2023-10-16 DOI:10.3390/jcs7100439

Maha Abdallah Alnuwaiser, Mohamed Rabia

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引用次数: 0

摘要

由于用于检测重金属的传感器价格昂贵，以及与某些重金属相关的严重健康风险，迫切需要开发具有成本效益的材料，以高效地检测这些金属。通过碘氧化1-H吡咯，再与Na2WO4反应，合成了花状WO2I2-聚(1h -吡咯)(WO2I2/P1HP)纳米复合薄膜。该纳米复合材料具有独特的花状形态，平均尺寸为20nm。通过x射线光电子能谱(XPS)分析确定了元素组成和化学结构，x射线衍射分析(XRD)和傅里叶变换红外光谱(FTIR)分析进一步证明了复合材料中的晶峰和官能团。采用简单电位法(双电极电池)和循环伏安法(三电极电池)两种方法确定了纳米复合材料作为Cd2+离子传感器的电位，在10−6至10−1 M的浓度范围内，从简单电位法中可以看出，传感器在10−4至10−1 M的浓度范围内具有很强的传感能力，显示出29.7 mV/ 10年的纳恩斯特斜率。该传感器的检测限为5 × 10−5 M，能够精确灵敏地检测低浓度的Cd2+离子。使用循环伏安法，该传感器对Cd2+离子的选择性，通过循环伏安法证明了灵敏度为1.0 × 10−5 a /M，并且能够区分Cd2+离子与其他离子如Zn2+， Ni2+， Ca2+， K+， Al3+和Mg2+。这种选择性强调了它在复杂样品矩阵和不同环境中的实用性。此外，该传感器从实际样品中成功检测到Cd2+离子，巩固了其实际可行性。其在实际场景中的可靠性能使其成为跨行业和环境监测应用中Cd2+离子检测的宝贵工具。这些发现支持其在商业环境中的应用，突出了其在Cd2+离子检测中的意义。

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A Highly Promising Flower-Shaped WO2I2/Poly(1H-Pyrrole) Nanocomposite Thin Film as a Potentiometric Sensor for the Detection of Cd2+ Ions in Water

Because of the expensive nature of sensors used to detect heavy metals and the severe health risks associated with certain heavy metals, there is a pressing need to develop cost-effective materials that are highly efficient in detecting these metals. A flower-shaped WO2I2-Poly(1H-pyrrole) (WO2I2/P1HP) nanocomposite thin film is synthesized through the oxidation of 1-H pyrrole using iodine and subsequent reaction with Na2WO4. The nanocomposite exhibits a distinctive flower-like morphology with an average size of 20 nm. Elemental composition and chemical structure are confirmed via X-ray photoelectron spectroscopy (XPS) analyses, while X-Ray diffraction analysis (XRD) and Fourier-transform infrared spectroscopy (FTIR) analyses provide further evidence of crystalline peaks and functional groups within the composite. The potential of the nanocomposite as a sensor for Cd2+ ions is determined using two approaches: simple potentiometric (two-electrode cell) and cyclic voltammetric (three-electrode cell) methods, over a concentration range spanning from 10−6 to 10−1 M. From the simple potentiometric method, the sensor showcases strong sensing capabilities in the concentration span of 10−4 to 10−1 M, displaying a Nernstian slope of 29.7 mV/decade. With a detection limit of 5 × 10−5 M, the sensor proves adept at precise and sensitive detection of low Cd2+ ion concentrations. While using the cyclic voltammetric method, the sensor’s selectivity for Cd2+ ions, demonstrated through cyclic voltammetry, reveals a sensitivity of 1.0 × 10−5 A/M and the ability to distinguish Cd2+ ions from other ions like Zn2+, Ni2+, Ca2+, K+, Al3+, and Mg2+. This selectivity underscores its utility in complex sample matrices and diverse environments. Furthermore, the sensor’s successful detection of Cd2+ ions from real samples solidifies its practical viability. Its reliable performance in real-world scenarios positions it as a valuable tool for Cd2+ ion detection across industries and environmental monitoring applications. These findings advocate for its utilization in commercial settings, highlighting its significance in Cd2+ ion detection.

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