基于金属有机框架材料的光/电化学传感器在水环境检测中的应用进展

随着人们对水环境质量的要求日益增加,开发简便、灵敏和准确的新型水环境检测技术已成为研究的热点。金属有机框架化合物(Metal-organic frameworks, MOFs)是一类由金属离子或团簇和有机配体自组装形成的多孔配位聚合物,因其具有吸附可逆、催化活性高、比表面积大、孔径可调和结构多样等特性,可作为光/电化学传感材料,在水环境检测方面表现出巨大的应用潜力。本文介绍了近年来基于MOFs的光/电化学传感器在检测水环境中阴离子、重金属离子和有机化合物等污染物的研究进展,重点介绍了比色传感器、荧光传感器、化学发光传感器、电化学传感器、电化学发光传感器和光电化学传感器,最后,对基于MOFs的光/电化学传感器在水环境检测方面的未来发展前景进行了展望。     

光电化学传感器的研究进展

光电化学传感器以光作为激发源,以光电流或光电压作为检测信号,具有响应快速、灵敏度高、设备简单等特点,目前已在环境、食品、医学等多个领域的分析测试中得到广泛应用。该文阐述了光电转换材料与光电化学传感器的制备方法,介绍了光电化学传感器的原理和分类。光电化学传感器包含光寻址电位型传感器和电流型光电化学传感器,其中,电流型光电化学传感器由于优良的光电性能、检出限低、所需材料低廉且易加工等优势而被广泛应用。文中着重介绍了电流型光电化学传感器在金属离子、有机污染物、核酸、蛋白质、细胞等方面的应用,并对光电化学传感器的发展前景进行了展望。     

光电化学传感器的构建及研究进展

光电化学传感器是以光为激发源,光电流或光电压为检测信号,通过电化学、生物识别等手段定量分析待测物与光电流或光电压之间关系的新型技术。其原理是当光照射到光电活性材料时,材料中的电子受到激发,其上面的识别探针捕获目标分析物,引起光电流或光电压变化。当目标物的浓度变化时,光电信号发生相应的变化,两者之间呈现出函数关系,因此,可以通过光电信号变化,来定量测定目标物。在光电化学传感器中,因其激发源(光)与检测信号(电流或电压)的完全分离极大地减少了背景信号的干扰;又因具有响应快速、灵敏度高、设备简单、价格低廉易于微型化等优点,使光电化学传感器在各大领域备受瞩目。本文介绍了光电化学传感器的基本原理、特点、分类及其应用,并对有代表性的研究和发展前景做了总结和评述。     

过渡金属氧化物在光电化学传感器中的应用研究进展

近年来,光电化学传感器的研究已经成为人们关注的热点。光敏材料作为光电化学传感器的关键部分,其性能对传感器的灵敏度、选择性和稳定性等特征起着决定性的作用。该文简要介绍了光电化学传感器的原理和光电材料的分类,阐述了在光电化学传感器中常见过渡金属氧化物及其复合物的光电材料的制备方法与应用,对光电化学传感器及光电化学材料的发展前景进行了展望(引用文献67篇)。     

光电化学传感材料的制备及应用进展

光电化学传感材料是光电化学传感器的核心功能材料,其结构性质决定了光电化学传感器的分析性能和应用范围。本文介绍了常用光电化学传感材料的制备方法及应用领域,综述了近年来该领域的研究进展并对光电化学传感材料未来的发展方向进行了展望。     

光致电化学鸟嘌呤传感器的制备及其应用

将硫堇电聚合在光透电极的表面,再利用壳聚糖将黄嘌呤氧化酶固定在具有光电活性的聚硫堇光透电极的表面上制备了光致电化学鸟嘌呤传感器.基于同时具有光敏和电子受体功能的聚硫堇光电界面,该传感器能与黄嘌呤氧化酶催化鸟嘌呤氧化而产生的电子供体(过氧化氢)产生光致电化学响应,通过测量光致电化学反应产生的光电流实现了对鸟嘌呤的检测.文中探讨了传感器的光致电化学响应机理,讨论了偏压、酶量、电解质溶液pH对传感器测定鸟嘌呤的影响.在优化的实验条件下,该传感器对鸟嘌呤的测定范围为1.00～200μmol/L,检出限为0.55μmol/L,9次测定的相对标准偏差小于3.92%.应用该传感器对酸解DNA脱出的鸟嘌呤基和药品阿昔洛韦进行的检测实验显示,相对标准偏差小于5.37%,加标回收率为96.8%～106%.该传感器的制备和对鸟嘌呤的检测不需要过氧化物酶,不需要除氧,有经济、简便等优点.     

基于聚硫堇/过氧化氢光电化学敏感界面的胆碱传感器

将胆碱氧化酶固定在具有光电活性的聚硫堇光透电极的表面,利用壳聚糖和戊二醛键合胆碱氧化酶制备了光致电化学胆碱传感器.此传感器基于同时具有光敏和电子受体功能的聚硫堇光电界面,能与胆碱氧化酶催化胆碱反应产生的电子供体(H2O2)发生光致电化学反应的原理,实现了对胆碱的检测.探讨了传感器的光致电化学响应机理、偏压、光强及电解质...     

光电化学型半导体生物传感器

光电化学型半导体生物传感器是一种利用半导体的光电特性来检测与光生电流或光生电压相关的待测物质浓度及生化过程参数的分析新技术。随着新兴半导体功能材料及相关加工技术的不断涌现,光电化学型半导体生物传感器已在微型化、集成化、多点及多参数测量方面显现出优势、有望在复杂体系中实现在线高灵敏、快速测定,在生物、医药、环境监测、食品等领域显示出广阔的应用前景。本文主要介绍了光电化学型半导体传感器的基本原理、特点及近几年的研究进展,并对其发展前景做了展望。     

生物电分析新方法与技术研究及仪器研制

生物电分析化学是一门利用生物分子作为识别元件、通过生物反应后电极过程产生的信号的变化对未知物质进行定性、定量分析的学科.目前常用的生物识别元件有酶、核酸(包括核酸适配体)、抗体、受体等,而可供检测的信号广义上包括电流、电阻、光电流和电化学发光等.在过去5年的工作中,我们针对生命科学、临床检验和环境监测等实际应用领域,分别研究了电化学酶传感器、光电化学核酸损伤传感器和电化学发光免疫检测的原理与技术,并研制了相应的检测仪器.     

双酚A电化学检测方法的研究进展

综述了双酚A的直接电化学检测方法(用于裸电极表面的修饰材料包括纳米材料、新型材料和生物材料)和间接电化学检测方法(包括电化学适配体传感器,电化学酶传感器和电化学分子印迹传感器)的研究进展,并对其前景进行了简要展望(引用文献54篇).     

Progress in the studies of photoelectrochemical sensors

Photoelectrochemical sensor is a new kind of developing analytical device based on the photoelectrochemical properties of materials. Because of its remarkable sensitivity, inherent miniaturization, portability and easy integration, photoelectrochemical analysis is becoming a promising analytical technique. This review focuses on the basic principles, classification, characteristics, and research progress of photoelectrochemical sensors with 94 references. The prospect of the development of photoelectrochemical sensors is also evaluated and discussed.     

Near-infrared Responsive Photoelectrochemical Biosensors

Near-infrared (NIR) light-driven photoelectrochemical (PEC) sensing is a highly promising analytical technique, especially for in situ bioanalysis, due to the deep penetration capability and minimal invasiveness of NIR light. In this mini review, we provide a brief overview of recently developed NIR PEC sensors, focusing on NIR light-responsive materials and the representative applications of this type of PEC sensor. Future perspectives for NIR PEC sensors are also described.     

Application of MXene in Electrochemical Sensors: A Review

Electroanalysis has obtained considerable progress over the past few years, especially in the field of electrochemical sensors. Broadly speaking, electrochemical sensors include not only conventional electrochemical biosensors or non-biosensors, but also emerging electrochemiluminescence (ECL) sensors and photoelectrochemical (PEC) sensors which are both combined with optical methods. In addition, various electrochemical sensing devices have been developed for practical purposes, such as multiplexed simultaneous detection of disease-related biomarkers and non-invasive body fluid monitoring. For the further performance improvement of electrochemical sensors, material is crucial. Recent years, a kind of two-dimensional (2D) nanomaterial MXene containing transition metal carbides, nitrides and carbonitrides, with unique structural, mechanical, electronic, optical, and thermal properties, have attracted a lot of attention form analytical chemists, and widely applied in electrochemical sensors. Here, we reviewed electrochemical sensors based on MXene from Nov. 2014 (when the first work about electrochemical sensor based on MXene published) to Mar. 2021, dividing them into different types as electrochemical biosensors, electrochemical non-biosensors, electrochemiluminescence sensors, photoelectrochemical sensors and flexible sensors. We believe this review will be of help to those who want to design or develop electrochemical sensors based on MXene, hoping new inspirations could be sparked.     

Ratiometric electrochemical,electrochemiluminescent, and photoelectrochemical strategies for environmental contaminant detection

Global environmental pollution issue has boosted the development of novel analytical techniques with high efficiency and accuracy for detection of hazardous contaminants. Strategies based on electrochemical, electrochemiluminescent, or photoelectrochemical analysis are among the promising detection approaches to provide rapid and sensitive analysis. Currently, combining ratiometric assay with such strategies can further promote their sensing reliability and reproducibility in complex conditions. This review highlights recent advances of ratiometric electrochemical, electrochemiluminescent, and photoelectrochemical sensors in the past 2 years. Their signal generation strategies and analysis applications, particularly for the environmental contaminant detection, are discussed in detail, and a future prospect in this area from us is also provided.     

In situ formation of p–n junction: A novel principle for photoelectrochemical sensor and its application for mercury(II) ion detection

The discovery and development of photoelectrochemical sensors with novel principles are of great significance to realize sensitive and low-cost detection. In this paper, a new photoelectrochemial sensor based on the in situ formation of p–n junction was designed and used for the accurate determination of mercury(II) ions. Cysteine-capped ZnS quantum dots (QDs) was assembled on the surface of indium tin oxide (ITO) electrode based on the electrostatic interaction between Poly(diallyldimethylammonium chloride) (PDDA) and Cys-capped ZnS QDs. The in situ formation of HgS, a p-type semiconductor, on the surface of ZnS facilitated the charge carrier transport and promoted electron-hole separation, triggered an obviously enhanced anodic photocurrent of Cys-capped ZnS QDs. The formation of p–n junction was confirmed by P–N conductive type discriminator measurements and current–voltage (I–V) curves. The photoelectrochemical method was used for the sensing of trace mercuric (II) ions with a linear concentration of 0.01 to 10.0 µM and a detection limit of 4.6 × 10⁻⁹ mol/L. It is expected that the present study can serve as a foundation to the application of p–n heterojunction to photoelectrochemical sensors and it might be easily extended to more exciting sensing systems by photoelectrochemistry.     

磁光Fe3O4@SiO2@CdS复合材料的制备及表征

采用水解三氯化铁得到Fe₃O₄磁核,然后水解四乙氧基硅烷(TEOS)得到Fe₃O₄@SiO₂,再在其表面包覆半导体CdS即可得到良好的磁性光电信标Fe₃O₄@SiO₂@CdS。材料形貌、组成分析及光电化学测试表明成功地合成了具有超顺磁性的Fe₃O₄@SiO₂@CdS纳米复合材料。该材料分散均匀、具有良好的光学性能、在光电化学传感及光电催化等领域具有良好的应用前景。     

Recent advances in photoelectrochemical sensors for detection of ions in water

Over the last 50 years, the explosive adoption of modern agricultural practices has led to an enormous increase in the emission of non-biodegradable and highly biotoxic ions into the hydrosphere. Excess intake of such ions, even essential trace elements such as Cu²⁺ and F⁻, can have serious consequences on human health. Therefore, to ensure safe drinking water and regulate wastewater discharge, photoelectrochemical (PEC) online sensors were developed, with advantages such as low energy consumption, inherent miniaturization, simple instrumentation, and fast response. However, there is no publicly available systematic review of the recent advances in PEC ion sensors available in the literature since January 2017. Thus, this review covers the various strategies that have been used to enhance the sensitivity, selectivity, and limit of detection for PEC ion sensors. The photoelectrochemically active materials, conductive substrates, electronic transfer, and performance of various PEC sensors are discussed in detail and divided into sections based on the measurement principle and detected ion species. We conclude this review by highlighting the challenges and potential future avenues of research associated with the development of novel high-performance PEC sensors.     

Substituent effects on monoboronic acid sensors for saccharides based on N-phenyl-1,8-naphthalenedicarboximides

In the course of our investigations on new monoboronic acid saccharide sensors with C(0) spacers, a series of probes 1-6 based on 1,8-naphthalenedicarboximide were synthesized. Sensor 1 displays features typical of PET monoboronic acid sensors and shows high selectivity to fructose. Sensor 2 exhibits a novel dual emission and remarkable sensitivity for glucose relative to fructose and galactose through subtle changes in pH. Sensor 3 displays significantly enhanced fluorescence in the presence of galactose at low pH. Although probes 4-6 exhibit unique properties such as high quantum yield (Phi(F) = 0.407) and excellent solubility in water, they did not show significant change in fluorescence intensity in the presence of monosaccharides. The effects of substituent on all six probes lend support to the proposed photoelectrochemical model.