拓扑指数法研究稀土显色剂结构与钇显色反应灵敏度的关系

本文计算了二十种不对称色酸双偶氮膦酸型显色剂的Am指数, 并将其与钇进行显色反应的灵敏度进行相关性研究, 讨论了显色剂结构对显色反应灵敏度的影响,预报了几种显色剂与钇显色反应的灵敏度, 取得较为满意的结果。     

阴离子显色剂偶氮染料异方酸二酰胺与含氧酸根离子的作用机理

提出了1,3-N,N′-双-[4-(4′-硝基苯偶氮)苯基]异方酸二酰胺(BNBPS)与阴离子的作用模型,运用AM1法研究了BNBPS与部分含氧酸根离子的作用,阐明了显色反应的机理,解释了HCO3-,CO23-, NO3-, NO2-等与BNBPS作用是否显色的原因,从理论上预测了BNBPS可作为SO24-的显色剂.     

TMB目视比色法检测水中余氯的改进

为解决GB/T 5750.11-2006生活饮用水标准检验方法中的3,3',5,5'-四甲基联苯胺(TMB)目视比色法检测余氯时出现的评价方法准确性欠佳、TMB显色剂发黄、显色体系偏绿等问题,对TMB目视比色法的评价方法、TMB显色剂的配制条件和水样的检测条件进行了研究。结果表明,次氯酸钠不宜作为余氯标准物质来评价TMB目视比色法的改进效果,而通过检测显色体系的A450和目视比色值相结合的方法来判断方法改进效果更为准确。采用优级纯浓盐酸和无氯纯水室温搅拌溶解,可使显色剂无色透明,从而解决TMB显色剂发黄的问题,符合国标要求。将显色剂配制用酸(盐酸)的浓度由国标中0.1mol/L变更为0.6 mol/L,可解决余氯显色体系偏绿的问题。显色体系pH变化后,显色时间、显色温度、显色剂用量可仍按照国标方法的要求进行操作。通过以上改进措施,进一步提高了余氯检测结果的准确度。     

十二烷基硫酸钠对酶抑制光度法测定农药残留的增敏作用

采用植物酯酶抑制法测定了蔬菜中农药的残留,研究了阴离子表面活性剂十二烷基硫酸钠对显色体系的作用.结果表明,十二烷基硫酸钠具有显著的增敏效果,其增敏幅度达到70%,同时对显色剂有增稳作用.用所建立的方法测定蔬菜中残留的敌敌畏,线性范围为0.11 mg/L~1.6 mg/L,最低检出限0.04 mg/L.     

拓扑指数法研究显色剂结构与反应性能关系

本文讨论了２９个不对称色酸双偶氮膦酸型显色剂的分子联接性指数，并将其与结构选择性因子相结合，用于偶氮类剂结构与铈显色反应灵敏度的相关性研究，讨论了显色剂结构对显色反应灵敏度的影响。     

离子型-非离子型混合表面活性剂对显色反应作用的研究及其应用 Ⅲ.显色剂在胶束相的分配系数

我们曾研究了离子型-非离子型混合表面活性剂对显色反应的作用.本文通过测定显色剂在表面活性剂胶束相和水相中的分配系数,考察了分配系数和显色反应灵敏度的关系,进一步探讨了阳离子型-非离子型混合表面活性剂对显色反应协同增敏作用的机理. 根据析相模型,显色剂(配位体)在胶束相和水相中的分配系数可表示如下:     

水-乙醇介质中稀土元素-6,8-二磺酸基萘偶氮氯膦-溴化十六烷基(羧甲基)二甲胺多元络合物显色反应的研究及应用

武汉大学合成了新显色剂6.8-二磺酸基萘偶氮氯膦(曾用名氨基G酸偶氮氯膦),其结构式如下:並研究了在阳离子表面活性剂(TPC)存在下与稀土元素形成多元络合物的显色反应。我们比较研究十多种阳离子、阴离子、非离子及两性表面活性剂后,于水乙醇介质中,研究了稀土元素6,8-二磺酸基萘偶氮氯膦-两性表面活性剂溴化十六烷基(羧甲基)二甲铵(CCDMAB)多元络合物的显色反应,在0.3N盐酸酸度下,络合物的最大吸收波长λ_(max)=692.5nm,     

拓扑指数法研究稀土显色剂结构与铈显色反应对比度的关系

计算了４３种不对称变色酸双偶氮膦酸型显色剂的Ａｍ拓扑指数，并将其与结构选择性因子相结合，用于偶氮类显色剂结构与铈显色反应对比度的相关性研究，讨论了显色剂结构对拓扑指数有译比度的影响。     

高灵敏度显色剂在分光光度法测定铅中的应用

综述了近年来国内各类高灵敏度的显色剂,包括卟啉类、变色酸双偶氮试剂、甲基百里香酚蓝等显色剂的显色原理及其在分光光度法测定铅离子中的应用(综述文献46篇)。     

PNPAR—CTMAB光度法测定水中痕量阴离子表面活性剂

本文研究了对硝基偶氮间苯二酚（ＰＮＰＡＲ）与溴化十六烷基三甲铵（ＣＴＭＡＢ）形成的离子缔合物ＰＮＰＡＲ－ＣＴＭＡＢ作显色剂与阴离子表面活性剂（ＡＳ）的显色反应，发现在ｐＨ１３．０的ＮａＯＨ介质中，ＡＳ能定量置换出ＰＮＰＡＲ－ＣＴＭＡＢ中的ＰＮＰＡＲ，而使其最大吸收波长６３０ｎｍ处吸光度下降，阴离子表面活性十二烷基苯磺酸钠（ＳＤＢＳ）和十二烷基磺酸钠（ＳＤＳ）的ε值分别为３．５×１０＾４，５．８×１     

Ratiometric dual fluorescent receptors for anions under intramolecular charge transfer mechanism

A series of the intramolecular charge transfer (ICT) dual fluorescent receptors with anion binding site in the electron acceptor were designed and synthesized. These receptors exhibited dual fluorescence in acetonitrile and the charge transfer (CT) emission energy was found to correlate linearly with the Hammett constant of the substituent existing in the electron acceptor, which is the basis for anion sensing. Dual fluorescence of these receptors was found to be sensitive to the presence of anions such as fluoride and acetate and the receptors can be employed as ratiometric fluorescent sensors for anions.     

Enhanced gas sensing by assembling Pd nanoparticles onto the surface of SnO2 nanowires

SnO₂ nanowires with an average 0.6 μm in length and about 25 nm in diameter were prepared by a hydrothermal method. The sensors were fabricated using SnO₂ nanowires assembled with Pd nanocrystals. The sensing properties of the sensors such as selectivity, response-recovery time and stability were tested at 290 °C. After assembling Pd nanocrystals onto the surface of SnO₂ nanowires, the gas sensing properties of the sensors toward H₂S were improved. The sensors based on Pd nanoparticle@SnO₂ nanowires exhibit high stability owing to stable single crystal structure. The mechanism of promoting sensing properties with Pd nanoparticles is discussed.     

Designing State-of-the-Art Gas Sensors: From Fundamentals to Applications

Gas sensors are crucial in environmental monitoring, industrial safety, and medical diagnostics. Due to the rising demand for precise and reliable gas detection, there is a rising demand for cutting-edge gas sensors that possess exceptional sensitivity, selectivity, and stability. Due to their tunable electrical properties, high-density surface-active sites, and significant surface-to-volume ratio, nanomaterials have been extensively investigated in this regard. The traditional gas sensors utilize homogeneous material for sensing where the adsorbed surface oxygen species play a vital role in their sensing activity. However, their performance for selective gas sensing is still unsatisfactory because the employed high temperature leads to the poor stability. The heterostructures nanomaterials can easily tune sensing performance and their different energy band structures, work functions, charge carrier concentration and polarity, and interfacial band alignments can be precisely designed for high-performance selective gas sensing at low temperature. In this review article, we discuss in detail the fundamentals of semiconductor gas sensing along with their mechanisms. Further, we highlight the existed challenges in semiconductor gas sensing. In addition, we review the recent advancements in semiconductor gas sensor design for applications from different perspective. Finally, the conclusion and future perspectives for improvement of the gas sensing performance are discussed.     

Calix[4]arenes containing ferrocene amide as carboxylate anion receptors and sensors

Calix[4]arene derivatives containing amide ferrocene units at the wide rim and ethyl ester groups at the narrow rim, L1-L3, were synthesized and their anion binding and sensing properties were investigated. It was found from (1)H NMR titrations that L1-L3 were able to bind selectively with carboxylate anions. Moreover, cyclic voltammetry and square wave voltammetry showed that L1-L3 were able to act as electrochemical sensors for carboxylate anions. [structure: see text]     

Versatile fullerenes as sensor materials

The last century outstanding discovery of fullerenes (or C₆₀), as they are popularly called ‘buckyball’ structured molecules with icosahedral spherical structure, consists of 60 sp^2-hybridized carbon atoms. These fullerenes have created immense applications in various fields, such as catalysts, sensors, photocatalysts, energy production, and storage materials. Fullerenes because of their improved conductivity, charge transfer, and photophysical properties have gained considerable attention, particularly in sensor area. The activity of sensors depends upon the interactions between fullerene and the sensing material. Among all the types of fullerenes, C₆₀ has been extensively used. This review is an attempt to cover different aspects of fullerene-based sensing devices, wherein fullerenes act as important component (s) of the sensor device because of their electron-accepting properties. We will discuss the fullerene-based sensors for diverse applications as strain/gas sensors, electrochemical sensors, and optical sensors as much effort has been recently made to detect different analytes such as gases, volatile organic compounds, metal ions, anions, and biomolecules.     

The sensing mechanism of fluoride anion for a novel molecule D2: Desilylation and intramolecular charge transfer

In this work, the sensing mechanism of a new fluoride chemosensor 12‐([tert‐butyldiphenylsilyl]oxy)‐8a,13a‐dihydro‐7H‐benzo[de]benzo[4,5]imidazo[2,1‐a]‐isoquinolin‐7‐one (abbreviated as D2) is investigated using density functional theory (DFT) and time‐dependent DFT (TDDFT) methods. The theoretical electronic spectra (vertical excitation energies and fluorescence peak) reproduced previous experimental results (D. Li et al., Spectrochim. Acta A Mol. Biomol. Spectrosc. 2017 , 185, 173), which confirms the rationality of the theoretical level used in this work. The constructed potential energy curve of the desilylation process suggests that the low barrier could be responsible for the rapid response to fluoride anions. Analyses of the binding energies show that only fluoride anion can be detected by D2 chemosensor in dimethylsulfoxide (DMSO). In view of the excitation process, the strong intramolecular charge transfer (ICT) process of the S₀ → S₁ transition explains the red shift of the absorption peak of the D2 sensor with the addition of fluoride anions. This work not only presents a straightforward sensing mechanism of sensing of the fluoride anion by the D2 chemosensor but should also play an important role in the synthesis and design of fluorescent sensors in future.     

Ion recognition properties of self-assembled monolayers (SAMs)

In the search for new sensors, self-assembled monolayers (SAMs) have gained intensive interest due to their nanometre size, highly-ordered structures, and molecular recognition properties. This article presents an overview of ion recognition at SAM-modified surface/solution interfaces, and brings up to date the most notable examples for the sensing of cations and anions. Sensing is achieved with SAMs containing redox active and inactive receptors using techniques such as fluorescence spectroscopy, cyclic voltammetry and electrochemical impedance spectroscopy.     

1,10-邻菲啰啉并咪唑衍生物阴离子受体的合成及识别性能

设计合成了2个1,10-邻菲啰啉并咪唑衍生物阴离子受体2-(2-羟基苯基)-1H-咪唑[4,5-f][1,10]邻菲啰啉(1)和2-(2-羟基-5-溴苯基)-1H-咪唑[4,5-f][1,10]邻菲啰啉(2), 受体2的结构由X射线单晶衍射分析确证. 通过紫外-可见光谱滴定及 ¹H NMR滴定研究了这2个受体对F^-, Cl^-, Br^-, I^-, H₂PO₄^-和AcO^- 6种阴离子的识别传感作用及作用机理. 结果表明, 受体对AcO^-, F^-和H₂PO₄^-有较强的传感作用, 溶液颜色由淡黄色变为黄色; 对Cl^-的作用较弱; 而对Br^-和I^-则无明显作用. 通过机理研究发现, 受体与F^-, H₂PO₄^-和AcO^-形成1: 1的氢键超分子, 当阴离子的量超过受体的1倍以后, 咪唑氮上的氢转移到阴离子; 受体与Cl^-以氢键形成超分子复合物, 而与Br^-和I^-作用很弱.