Electrochemical and density functional simulation studies of a cobalt(ii) imidazolate framework for the real-time sensing of atrazine

IF 2.7 3区 化学 Q2 CHEMISTRY, MULTIDISCIPLINARY
Simranjeet Singh, Pavithra N, S.K Behera, Radhika Varshney, Joginder Singh and Praveen C Ramamurthy
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Abstract

Atrazine, a human-made herbicide, is infamous for its endocrine-disrupting properties, with adverse consequences on the immune, reproductive, and nervous systems. Consequently, effective recognition of atrazine in various environments, such as water, is critically important. This work presents a precise and efficient method for detecting atrazine across various environments, utilizing a well-established electrochemical technique. A metal organic framework (MOF) ZIF-67 has been synthesized and employed as a catalyst for the electrochemical detection of the triazine herbicide atrazine. Structural, morphological, and chemical analyses were conducted to evaluate the sensing material and to elucidate the interactions between the sensor and the analyte. The ZIF-67 was then integrated on the surface of the working electrode (carbon paste electrode (CPE)) to form a ZIF-67 modified-CPE (ZIF-67/MCPE). The ZIF-67/MCPE was utilized to detect atrazine by electrochemical techniques including differential pulse voltammetry (DPV) and cyclic voltammetry (CV). The sensor demonstrated excellent sensitivity and was effective in detecting atrazine. The modified sensor demonstrated a lower limit of detection (LLOD) of 3.7 μM within a linear concentration range of 4–44 μM and exhibited a strong linear correlation efficiency of 0.97. Computational results corroborated the experimental findings, revealing that the combination of ZIF-67 with atrazine forms minor triangular structures and exhibits enhanced dynamics compared to the pristine MOF. This improvement in the crystallinity of the ZIF-67 MOF with atrazine is attributed to the negative binding energy and reduced energy gap at the interface between the MOF and atrazine. Additionally, the sensor's practical application was evaluated by testing it on sewage water and fresh liquid milk. The sensor demonstrated an exceptional ability to detect atrazine, with a recovery rate ranging from 96% to 99%. This approach holds promise for developing electrochemical or solid-state devices for real-time atrazine monitoring.

Abstract Image

用于阿特拉津实时传感的咪唑酸钴(ii)框架的电化学和密度泛函模拟研究
阿特拉津是一种人造除草剂,因其干扰内分泌的特性而臭名昭著,会对免疫、生殖和神经系统造成不良后果。因此,有效识别水等各种环境中的阿特拉津至关重要。本研究利用一种成熟的电化学技术,提出了一种在各种环境中检测阿特拉津的精确而高效的方法。我们合成了一种金属有机框架(MOF)ZIF-67,并将其用作电化学检测三嗪类除草剂阿特拉津的催化剂。通过结构、形态和化学分析对传感材料进行了评估,并阐明了传感器与分析物之间的相互作用。然后将 ZIF-67 集成到工作电极(碳浆电极 (CPE))表面,形成了 ZIF-67 修饰型碳浆电极(ZIF-67/MCPE)。利用 ZIF-67/MCPE 通过电化学技术(包括差分脉冲伏安法 (DPV) 和循环伏安法 (CV))检测阿特拉津。该传感器灵敏度极高,能有效地检测阿特拉津。改进后的传感器在 4-44 μM 的线性浓度范围内的检测下限(LLOD)为 3.7 μM,线性相关效率高达 0.97。计算结果证实了实验结果,显示 ZIF-67 与阿特拉津的结合形成了小三角形结构,与原始 MOF 相比,显示出更强的动态性。ZIF-67 MOF 与阿特拉津结晶度的提高归因于 MOF 与阿特拉津界面的负结合能和能隙的减小。此外,通过在污水和新鲜液态奶中进行测试,对传感器的实际应用进行了评估。该传感器显示出卓越的阿特拉津检测能力,回收率在 96% 到 99% 之间。这种方法为开发用于实时监测阿特拉津的电化学或固态装置带来了希望。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
New Journal of Chemistry
New Journal of Chemistry 化学-化学综合
CiteScore
5.30
自引率
6.10%
发文量
1832
审稿时长
2 months
期刊介绍: A journal for new directions in chemistry
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