二甲基甲酰胺-二氧六环混合溶剂中KBr,KSCN及KClO_4的电导研究

本文报告了KBr、KSC N、KClO_4和KI在二甲基甲酰胺(DMF)和1,4-二氧六环混合溶剂中的电导测定值、溶剂的粘度和溶液的密度,按Pitts,Fuoss1978和Lee-Wheaton电导方程拟合实验数据得出溶液的无限稀释摩尔电导A_o,离子缔合常数K_α和正负离子间的距离参数R。对三个方程的适用性和溶液中离子-离子-溶剂分子间的相互作用作了初步讨论。     

新型微型电导池的研制及其地效应的消除

使用简便的方法制作了电极面积大、无死体积、分辨率高、检测限低的微型电导池;较好地消除了毛细管电泳ＣＥ）在柱 存在的共地效应,排除了在线检测时高压分离回路对电导检测回路的干扰。并对制作的躲开电导池的性能进行了测试。     

纳米晶（CeO2）1—x（BiO1.5）x固溶体的水热合成与离子输运性 …

在２４０℃水热体系中首次合成出系列纳米晶固溶体（ＣｅＯ２）１－ｘ（ＢｉＯ１．５）ｘ（ｘ＝０．０￣０．５０）。产物采用Ｘ射线衍射,扫描电子显微镜和Ｘ射线光电子能谱仪进行表征。Ｂｉ２Ｏ３在ＣｅＯ２中的固溶限约为５０％。所有固溶体结晶属立方萤石结构,粒度范围为１０￣１８ｎｍ。当Ｂｉ２Ｏ３掺杂量小于固溶限时,于８００℃烧结不会导致结构转变。而对于（ＣｅＯ２）０．５（ＢｉＯ１．５）０．５,于８００℃在空气中     

电导法确定二元体系中离子的浓度

本文从电化学基本原理出发,推导出稀溶液中二元混合组分的电导与各组分当量浓度的关系,并通过测定纯组分的电导－当量浓度标准曲线,来确定二元混合组分的标准曲线在对其中一组分浓度确定的基础上,可很容易计算另一组分的浓度。该法简便、快速,有望成为化学分析和仪器分析的一个很好的补充。     

快速测定难熔碳化物中的游离碳

研究了难熔化合物中游离碳的分析方法,利用重铬酸钾和硫酸在≤110℃条件下氧化游离碳,用电导仪测定二氧化碳吸收液的电导,经标准碳酸钙进行校正,换算求得游离碳的含量。方法可快速、较准确地测定碳化硅、碳化硼、碳化铬等难熔碳化物中的游离碳含量。     

新型微型电导池的研制及共地效应的消除

使用简便的方法制作了电极面积大、无死体积、分辨率高、检测限低的微型电导池;较好地消除了毛细管电泳(CE)在柱电导检测装置中存在的共地效应,排除了在线检测时高压分离回路对电导检测回路的干扰.并对制作的微型电导池的性能进行了测试.     

毛细管电泳及芯片毛细管电泳的电容耦合非接触电导检测

综述了毛细管电泳(CE)及芯片毛细管电泳(MCE)的电容耦合非接触电导检测(Capacitively Coupled Contactless Conductivity detection,C4D)的研究状况;并分别对其装置、检测的影响因素及其应用进行了评述。引用文献81篇。     

毛细管电泳法快速测定琥乙红霉素的含量

建立了毛细管电泳高频电导法测定琥乙红霉素的方法。探讨了缓冲溶液、有机溶剂添加剂以及分离电压和进样条件等因素对分离检测的影响。在电泳介质为2.0mmol/L柠檬酸-20.0?H5OH,分离电压20.0kV的优化条件下,在7min内即可实现琥乙红霉素的分离检测,线性范围为3.0μg/mL-150.0μg/mL,检出限为1.0μg/mL。方法简便、快速,可检测制剂中琥乙红霉素的含量。     

镁掺杂对In2O3电导和气敏性能的影响

用共沉淀法制备了Mg2+掺杂的In2O3纳米粉,研究了镁掺杂对In2O3电导和气敏性能的影响.结果表明:MgO和In2O3间可形成有限固溶体In2-xMgxO3(0≤x≤0.40);MgIn×电离的空穴对材料导带电子的湮灭,使掺镁纳米粉的电导变得很小;n(Mg2+):n(In3+)=1:2共沉淀物于900℃下热处理4 h,用所得的纳米粉制作的传感器在320～370℃下,对45μmol/L C2H5OH的灵敏度达102.5,为相同浓度干扰气体Petrol的12倍多.     

毛细管电泳高频电导法测定制剂中卡托普利

建立了制剂中卡托普利毛细管电泳高频电导分析法,并用于卡托普利片、复方卡托普利片中卡托普利含量的测定。对电泳介质的种类、浓度以及操作电压和进样量等影响因素进行了优化。试验采用3.0 mmol.L-1环己胺+5.0 mmol.L-1H3BO3+0.50 mol.L-1乙醇作为电泳介质,20.0 kV为分离电压,可在8min内实现对卡托普利的分离检测。卡托普利的线性范围为5.0~550 mg.L-1,检出限为0.8 mg.L-1,回收率达95.5%~102.0%。     

基于裂结技术的单分子尺度化学反应研究进展

分子电子学是研究单分子器件的构筑、性质以及功能调控的一门新兴学科。其中,金属/分子/金属结的构筑和表征是现阶段分子电子学的主要研究内容。裂结技术是当前分子电子学研究的主要实验方法,主要包括机械可控裂结技术和扫描隧道显微镜裂结技术。本文对裂结技术进行了介绍,并对近年来利用这些技术,在单分子尺度化学反应的检测和动力学研究,以及将这些技术与溶液环境、静电场、电化学门控等方法相结合,调控单分子器件的电输运性质等方面所取得的进展进行了概述。     

基于电化学方法研究以铜和银为电极的对苯二甲酸单分子结电导

利用基于电化学跳跃接触的扫描隧道显微镜裂结法(ECSTM-BJ), 通过现场形成金属电极, 对以Cu和Ag为电极的对苯二甲酸单分子结电导进行了测量. 研究结果表明: 利用该方法对所有数据直接线性统计即可得到很好结果; 两种电极下都存在两套高和低电导值, 其中以Cu为电极的单分子结电导高低值分别为11.5和4.0 nS, 而以Ag为电极的单分子结电导分别为10.3和3.8 nS, 高值都约为低值的3倍, 且以Cu为电极的单分子结电导要略大于以Ag为电极的电导, 可归结于电极和分子的耦合不同造成的. 与同样条件下测量得到的烷基链羧酸单分子结电导只存在一套值相比,对苯二甲酸表现出两套电导值, 反应了分子内主链对分子结电导的影响.     

Analytical modeling of the junction evolution in single-molecule break junctions: towards quantitative characterization of the time-dependent process

The conductance through single-molecule junctions characterized by the break junction techniques consists of the through-space tunneling and through-molecule tunneling conductance, and the existence of through-space tunneling between the electrodes makes the quantitative extraction of the intrinsic molecular signals of single-molecule junctions challenging. Here, we established an analytic model to describe the evolution of the conductance of a single molecule in break junction measurements. The experimental data for a series of oligo(aryleneethynylene) derivatives validate the proposed model, which provides a modeling insight into the conductance evolution for the opening process in a "real" break junction experiment. Further modulations revealed that the junction formation probability and rupture distance of the molecular junction, which reflect the junction stability, will significantly influence the amplitude and position of the obtained conductance peak. We further extend our model to a diffusion and a chemical reaction process, for which the simulation results show that the break junction technique offers a quantitative understanding of these time-dependent systems, suggesting the potential of break junction techniques in the quantitative characterization of physical and chemical processes at the single-molecule scale.     

Achieving Efficient Multichannel Conductance in Through-Space Conjugated Single-Molecule Parallel Circuits

Constructing single-molecule parallel circuits with multiple conduction channels is an effective strategy to improve the conductance of a single molecular junction, but rarely reported. We present a novel through-space conjugated single-molecule parallel circuit (f-4Ph-4SMe) comprised of a pair of closely parallelly aligned p-quaterphenyl chains tethered by a vinyl bridge and end-capped with four SMe anchoring groups. Scanning-tunneling-microscopy-based break junction (STM-BJ) and transmission calculations demonstrate that f-4Ph-4SMe holds multiple conductance states owing to different contact configurations. When four SMe groups are in contact with two electrodes at the same time, the through-bond and through-space conduction channels work synergistically, resulting in a conductance much larger than those of analogous molecules with two SMe groups or the sum of two p-quaterphenyl chains. The system is an ideal model for understanding electron transport through parallel π-stacked molecular systems and may serve as a key component for integrated molecular circuits with controllable conductance.     

Quantum interference effect in the charge transport through single-molecule benzene dithiol junction at room temperature: An experimental investigation

The electrical characterization on single-molecule benzene dithiols with different connectivities showed that the meta-BDT has the lowest conductance, which suggested that there is destructive quantum.     

电化学门控调节具有平行路径的单分子电路中电子传输

电化学门控已成为一种可行且高效调节单分子电导的方法。在本研究中,我们证实了具有两个平行苯环的单分子电路中电子传输可以通过电化学门控控制。首先,我们利用STM-BJ技术以金为电极构筑了具有两条平行路径的单分子结。与单条路径的单分子结相比,两条路径的分子结由于具有增强性量子干涉效应,具有2.82倍的电导值。进一步地,我们利用电化学门控对具有两个平行苯环的单分结的电导进行调控,获得了333%·V^-1调节比。结合DFT计算,发现在E=E_F附近的V形透射系数谱图导致了实验观测的电导门控行为。本研究揭示了具有平行路径的单分子电路的电化学门控行为,并为设计高性能分子器件的分子材料提供了新的途径。     

Achieving Efficient Multichannel Conductance in Through‐Space Conjugated Single‐Molecule Parallel Circuits

Constructing single‐molecule parallel circuits with multiple conduction channels is an effective strategy to improve the conductance of a single molecular junction, but rarely reported. We present a novel through‐space conjugated single‐molecule parallel circuit (f‐4Ph‐4SMe) comprised of a pair of closely parallelly aligned p‐quaterphenyl chains tethered by a vinyl bridge and end‐capped with four SMe anchoring groups. Scanning‐tunneling‐microscopy‐based break junction (STM‐BJ) and transmission calculations demonstrate that f‐4Ph‐4SMe holds multiple conductance states owing to different contact configurations. When four SMe groups are in contact with two electrodes at the same time, the through‐bond and through‐space conduction channels work synergistically, resulting in a conductance much larger than those of analogous molecules with two SMe groups or the sum of two p‐quaterphenyl chains. The system is an ideal model for understanding electron transport through parallel π‐stacked molecular systems and may serve as a key component for integrated molecular circuits with controllable conductance.     

Using Weakly Supervised Deep Learning to Classify and Segment Single-Molecule Break-Junction Conductance Traces

In order to design molecular electronic devices with high performance and stability, it is crucial to understand their structure-to-property relationships. Single-molecule break junction measurements yield a large number of conductance-distance traces, which are inherently highly stochastic. Here we propose a weakly supervised deep learning algorithm to classify and segment these conductance traces, a method that is mainly based on transfer learning with the pretrain-finetune technique. By exploiting the powerful feature extraction capabilities of the pretrained VGG-16 network, our convolutional neural network model not only achieves high accuracy in the classification of the conductance traces, but also segments precisely the conductance plateau from an entire trace with very few manually labeled traces. Thus, we can produce a more reliable estimation of the junction conductance and quantify the junction stability. These findings show that our model has achieved a better accuracy-to-manpower efficiency balance, opening up the possibility of using weakly supervised deep learning approaches in the studies of single-molecule junctions.     

Measurement and statistical analysis of single-molecule current-voltage characteristics, transition voltage spectroscopy, and tunneling barrier height

We report on the measurement and statistical study of thousands of current-voltage characteristics and transition voltage spectra (TVS) of single-molecule junctions with different contact geometries that are rapidly acquired using a new break junction method at room temperature. This capability allows one to obtain current-voltage, conductance voltage, and transition voltage histograms, thus adding a new dimension to the previous conductance histogram analysis at a fixed low-bias voltage for single molecules. This method confirms the low-bias conductance values of alkanedithiols and biphenyldithiol reported in literature. However, at high biases the current shows large nonlinearity and asymmetry, and TVS allows for the determination of a critically important parameter, the tunneling barrier height or energy level alignment between the molecule and the electrodes of single-molecule junctions. The energy level alignment is found to depend on the molecule and also on the contact geometry, revealing the role of contact geometry in both the contact resistance and energy level alignment of a molecular junction. Detailed statistical analysis further reveals that, despite the dependence of the energy level alignment on contact geometry, the variation in single-molecule conductance is primarily due to contact resistance rather than variations in the energy level alignment.     

Removing the Destructive Quantum Interference in Cross Conjugation System by Structural Restraint

Understanding the quantum effect in the cross-conjugated system is of fundamental significance in molecular electronics. In this study, four molecules Xa-O, Xa, BP and BP-O were synthesized to investigate the destructive quantum interference(DQI) of a carbonyl bridge. The single-molecule conductance measured by the scanning tunneling microscope break junction(STM-BJ) technique demonstrates an increase in the conductance from molecule BP-O to molecule Xa-O as the cross-conjugated system is extended. Theoretical calculations show that the explicit DQI feature is presented in BP-O but absent in Xa-O, which indicates the removal of DQI in the restrained structures and results in the conductance enhancement in Xa-O.