电化学石英晶体微天平及其应用

本文介绍了ＥＱＣＭ的原理及其应用，探讨了ＥＱＣＭ在生物大分子，纳米技术方面的应用，详细介绍了ＥＱＣＭ在气味检测，金属电沉积、药物分析等方面研究的优点和ＥＱＣＭ的发展前景。     

石英晶体微天平（QCM）及其在电化学研究中的应用

本文文献综述近年来发展起来的石英晶体微天平(QCM)技术的理论、实验方法和它在电化学研究中应用的概况。     

电化学石英晶体微天平研究普鲁士蓝修饰电极

石英晶体徽天平(Quartz Crystal Microbalance,简称QCM)是一种非常灵敏的质量传感器,其检测能力可达ng级。QCM在化学中的早期应用是检测大气中的徽量成分,目前仍较活跃。由于石英压电晶体浸入溶液后在晶体/溶液界面存在较大的能量损失而不能够稳定振荡,致使QCM的应用较长时间局限于气相。八十年代初石英压电晶体在液相中的振荡终获成功,开辟了QCM应用的一个全新领域。液相中振荡成功后,QCM很快应用于电化学研究。目前已发展成为一种全新的电化学传感器——电化学石英晶体微天平(EQCM),并已用于金属电沉积、电化学腐蚀、电分析等方面的研究。     

电化学石英晶体微天平应用研究和背景扣除

基于用循环伏安法研究非理想可逆体系时,电极本身的氧化峰电量与还原峰电量存在一比值。据此建立了一种用于电化学石英晶体微天平应用研究的背景扣除新方法。用这种方法研究了腺嘌呤、腺苷、腺苷一磷酸在金电极上的电化学氧化行为。结果表明:3种活性分子均能在1.2V左右氧化,对应的氧化电流大小顺序为:腺嘌呤>腺苷>腺苷一磷酸,氧化过程的电子转移数为6。     

石英晶体微天平(QCM)及其在大气腐蚀研究中的应用

从石英晶体微天平的基本原理出发,结合作者的文献调查及近期利用石英晶体微天平对大气腐蚀的研究结果,综述了石英晶体微天平在金属大气腐蚀研究中的重要作用,指出石英晶体微天平在金属大气腐蚀研究中的优点,存在的问题和相应的解决办法。     

鸟嘌呤、鸟苷、鸟苷酸的电化学石英晶体微天平研究

利用电化学石英晶体微天平(EQCM)研究了鸟嘌呤、鸟苷和鸟苷酸在金电极上的电化学行为.结果表明,三种生物活性分子均能在1.1V电位被氧化,对应于它们所含的共同基团嘌呤环中CN键的氧化,根据氧化反应电量和质量的变化,求得电子转移数为4.氧化电流的大小次序为鸟苷酸>鸟苷>鸟嘌呤,这可能与三者在电极上的吸附量不同有关.     

电化学石英晶体微天平研究界面电场对DNA杂交的影响

采用电化学石英晶体微天平, 现场监测不同界面电场下完全匹配的靶标DNA和不完全匹配的靶标DNA分别与寡聚核苷酸探针分子杂交的过程. 结果表明, 电极表面荷正电时DNA表观杂交效率比电极表面荷负电时高, 但假阳性比较显著; 而电极表面荷负电时能有效地抑制错配杂交. 探讨了引入界面电场后探针分子取向和微观作用力对DNA杂交的影响.     

电化学石英晶体微天平研究高氯酸钠水溶液中活性炭电极的离子存储行为

以电化学石英晶体微天平(EQCM)为主要测试手段,在不同浓度的高氯酸钠(NaClO4)水溶液中研究了水合离子吸附到活性炭电极孔隙过程中电极的质量变化.对于每种电解液,根据Raman光谱和EQCM数据分别计算了本体溶液中和电极/溶液界面上Na+的水合数.通过比对这两组Na+水合数,探讨了Na+存储到活性炭负极过程中的去溶剂化效应.     

石英晶体微天平在手性识别中的应用

石英晶体微天平(QCM)是一类重要的质量型检测器,因具有灵敏度高、分析速度快、检测成本低等优点而具有极好的应用前景,现已广泛应用于环境监测、药物分析、食品质量控制等诸多领域。手性工程的崛起对简单、快速、在线的手性检测技术提出了挑战,QCM手性传感器就是其中一个重要的发展分支。该文简要介绍了QCM的典型实验装置和基本传感原理,详细综述了近年来QCM在手性识别领域的研究进展,包括以环糊精衍生物、分子印迹聚合物、氨基酸衍生物等为手性主体的QCM在手性识别中的应用,并对其今后的发展进行了展望。     

The study of electrochemical palladium behavior using the quartz crystal microbalance

The electrochemical quartz crystal microbalance (EQCMB) method has been used to evaluate the processes which occur in/on the palladium electrode in basic solutions. Hydrogen electrosorption in palladium is accompanied by an additional frequency shift that can be attributed to the stresses generated inside the Pd metal. A non-linear dependence between the mass change and the charge consumed during hydrogen oxidation in the Pd electrode has been found for hydrogen absorbed in the α- and β-phases. This effect precludes the objective estimation of the amount of hydrogen absorbed inside the Pd electrode. The EQCMB method has been used, however, for studying the surface electrode processes on the Pd electrode, i.e. specific anion adsorption, surface oxidation and dissolution. Also, the structure of the palladium oxide formed on the Pd surface during electrochemical oxidation is discussed in this paper and the effect of the anodic limiting potential on the oxide structure is reported. Received: 10 August 1999 / Accepted: 24 September 1999     

石英晶体微天平的新进展

石英晶体微天平（quartz crystal microbalance,QCM）是一种对界面变化敏感的仪器,它已经在物理、化学、生物学、药物学、临床医学、环境科学等学科的界面问题研究中得到了一定的应用.然而,QCM在液相下的应用和推广一直受限于QCM数据定量解释的困难.为此,科研工作者发展了多种高级的QCM,比如带阻抗分析功能的QCM（impedance QCM,i-QCM）或带能量耗散监测功能的QCM（QCM with dissipation,QCM-D）,同时还发展了许多相应的理论模型.但是,对于多数生物、化学工作者来说,这些理论过于复杂.这极大地限制了QCM的推广和潜力发挥.本文以我们小组在QCM方面的研究工作为线索,对已报道的分析方法、模型和方程按5类应用条件进行了整理,给出了明确的界定标准：它们是：1,固-气界面;2,牛顿流体;3,固-液界面的薄膜;4,固-液界面厚膜;5,固-液界面超厚膜.对于每一类情况,我们将用通俗易懂的语言描述如何对QCM数据进行简化却又保证研究精度需要的定量分析.对于液态环境下的QCM数据的分析,我们着重介绍了＂固化水层＂模型,该模型允许QCM在一定的条件下成为一把＂分子尺＂,工作范围从几个纳米到数百纳米.该分子尺在多个创新界面问题研究中得到很好的应用.最后,我们从理论上分析了QCM作为生物传感器的先天缺陷--因基于面均质量检测的原理,QCM技术对溶液中蛋白的检测下限仅在1μg mL-1数量级.进一步,我们探索了QCM的发展方向和潜在应用领域,希望籍此能进一步推广QCM在各个学科界面问题中的研究应用.     

Ion and solvent transfer discrimination at a nickel hydroxide film exposed to LiOH by combined electrochemical quartz crystal microbalance (EQCM) and probe beam deflection (PBD) techniques

A combined electrochemical quartz crystal microbalance (EQCM) and probe beam deflection (PBD) instrument was used to monitor the mobile species transfers associated with the redox processes of thin (Γ100–150 nmol cm⁻²) α- and β-nickel hydroxide films exposed to aqueous LiOH solution. A comparison of the measured PBD signal with the predicted PBD profiles, calculated by temporal convolution analysis of the current and mass responses, enabled the contributions to redox switching of anion (OH⁻) and solvent (H₂O) transfers to be discriminated quantitatively. The responses from the combined instrument are reconciled in terms of H⁺ deintercalation/intercalation within the nickel hydroxide structure as OH⁻ ions enter/exit the film. Hydroxide ion movement is associated with a counterflux of water. Thin nickel hydroxide films show a gradual α→β phase transformation with continuous voltammetric cycling, especially when the films are exposed to high concentrations of electrolyte. α-Films are characterised by OH⁻ transfers that dominate the H⁺ and H₂O movements; β-films are characterised by an increased participation of water and protons to the exchange dynamics.     

Tin corrosion in highly acidic solutions containing ethylene glycol oligomers and halides: An electrochemical quartz crystal microbalance study

Tin corrosion in 1 M H₂SO₄ solutions containing 0.01 M Sn(II), 0.01 M ethylene glycol or its oligomers, and 30 μM of various halides is studied by the electrochemical quartz crystal microbalance method. The current density of the tin electrode corrosion is found to approach a few tens of μA cm^?2. In the presence of Sn(II), the current density is nearly half that in its absence. The corrosion potential steadily increases with time, approaching a certain limit. In solutions containing Sn(II), the limit practically corresponds to the equilibrium potential of the Sn/Sn²⁺ electrode. The corrosion rate barely depends on the oligomer nature even up to tetraethylene glycol. Halides accelerate the corrosion process. Their action intensifies at initial time instants (up to 15–20 min) in the series Cl^? < Br^? < I^?. The corrosion impedance equals ～1000 ohm cm². It may be ignored when analyzing the overall impedance of the tin electrode in the frequency region extending from 0.1 Hz to 50 kHz.     

Study of hydrogen electrosorption in Pd-Ni alloys by the quartz crystal microbalance

The electrochemical quartz crystal microbalance (EQCMB) method has been used to study the processes of hydrogen absorption/desorption in Pd-Ni alloy electrodes. It was found that hydrogen electrosorption is accompanied by an additional frequency shift, attributed to the stresses generated inside the alloy. The influence of stresses on the EQCMB response depends on the amount of absorbed hydrogen and the alloy composition. From the comparison of the EQCMB results with Pd-Ni alloy absorption capabilities data, it was concluded that the decrease of the hydrogen sorption capacity at a Ni content of ca. 25–30 at% is due to an excessive generation of stresses in the alloy lattice. Also, a dependency of the rate of hydrogen absorption in Pd-Ni alloys on potential is reported. Electronic Publication     

Palladium and the electrochemical quartz crystal microbalance: a new method for the in situ analysis of the precious metal in aqueous solutions

A new method for the quantitative determination of palladium(II) by the electrochemical quartz crystal microbalance (EQCM) technique has been developed. Using a bare carbon-coated quartz crystal, Pd(II) ions are directly deposited from aqueous solution as palladium metal onto the crystal surface, and the Pd(II) concentration is determined with a detection limit of 0.0156 mM, or 1.66 ppm. No complexing agent or preconcentration of palladium is required for the analysis. The palladium is stripped from the crystal through its electrochemical oxidation, regenerating the crystal for subsequent multi-cycle palladium analyses. A conventional gold-coated quartz crystal was incapable of carrying out the same measurements. The EQCM technique presented is simple, sensitive, and reproducible for the detection of this widely used precious metal.     

Electrochemical quartz crystal microbalance study of ion transport accompanying charging-discharging of poly(pyrrole) films

Electrochemical quartz crystal microbalance studies on poly(pyrrole) electrodes revealed a complex nature of the potential-dependent sorption of ionic substances. It is found that the relative contribution of anions and cations to the overall charge transport process depends upon several factors, such as the oxidation state of the polymer, the composition of the supporting electrolyte as well as on the film thickness. The phenomena observed are discussed in terms of morphological transformations arising as a result of interactions between the polymer and the mobile substances. Received: 21 August 1998 / Accepted: 21 October 1998     

Preparation of solid surfaces for native chemical ligation in the quartz crystal microbalance

The preparation of a nonporous solid surface for native chemical ligation is described. A cysteine residue is covalently attached to the surface by means of a series of reactions. In a reaction analogous to that used for native chemical ligation, the surface‐attached cysteine residue reacts with a thioester to form an amide linkage. All of the reaction steps except the derivatization of the nonporous solid surface with amino‐ended silane are conducted within the flow cell of a quartz crystal microbalance with dissipation monitoring. This sensitive instrument allows each reaction step to be followed in real time, with simultaneous quantification of the mass added and removed in different steps. The number of protected cysteine residues attached per square nanometer is consistent with the number of protecting groups removed in each deprotection step and also with the number of thioesters reacting with the deprotected cysteine. Copyright © 2013 John Wiley & Sons, Ltd.     

Electrochemical quartz crystal microbalance analysis of the cathodic process in a lithium-ion battery

The surface processes at carbon and platinum electrodes have been studied using the electrochemical quartz crystal microbalance technique in organic electrolyte solutions for lithium ion batteries. The changes in resonance frequency were analyzed as a function of the electrode potential, indicating that the process depended not only on the electrode material but also on the cathode potential. In the solution containing LiBF₄ as the electrolyte, the main product at the platinum surface was Li₂CO₃ and LiF, whereas formation of lithium alkylcarbonates was the primary process at the platinum and carbon electrodes in LiPF₆ solution.     

A review of monolithic multichannel quartz crystal microbalance: a review

Monolithic multichannel quartz crystal microbalance (MQCM) is an emerging technology for advanced sensing and measurement applications. In this report, a comprehensive review of MQCM technology is presented. Firstly, basic MQCM's design, simulation and characterization with emphasis on acoustic interference are described. Next, various MQCM schemes to minimize interference and enhance sensitivity of conventional MQCM devices based on modification of quartz substrate structure are digested. These include mesa, convex and x-axis inversion structures. Three important MQCM sensing platforms and their application areas are then discussed. These comprise MQCM as a static multichannel detector, series MQCM as a multichannel detector for the flow injection analysis and multi-frequency QCM for multi-sensitivity/multi-dynamic range detection. Finally, potential MQCM applications including electronic noses, bio-sensor arrays, and photocatatalytic measurement are illustrated and prospective MQCM applications including electronic tongues and electrochemical measurement are suggested.