酚酸基纳米金修饰电极检测食品中的亚硝酸盐和亚硫酸盐

基于酚酸良好的还原性和无污染性建立酚酸基纳米金传感体系,以实现亚硝酸盐和亚硫酸盐的灵敏检测。采用不同酚酸还原氯金酸制备纳米金(Gold nanoparticles,AuNPs),通过紫外光谱和交流阻抗法获得还原效果最佳的酚酸为没食子酸(Gallic acid,GA)。利用电沉积法制备GA@AuNPs@Au电极,并由线性扫描伏安法(Linear scanning voltammetry,LSV)表征亚硝酸盐和亚硫酸盐的电化学行为。优化体系条件为:GA浓度1 mmol/L、孵育温度70℃、反应时间60 min、pH6.0磷酸盐缓冲溶液浓度0.15 mol/L。亚硝酸盐和亚硫酸盐浓度在0.001~7 mmol/L范围内与氧化峰电流分别呈良好的线性关系(R2>0.994),检出限分别为0.20μmol/L和0.24μmol/L(S/N=3)。该修饰电极的重现性和稳定性良好,可用于实际样品中亚硝酸盐和亚硫酸盐的同时测定。

High‑Entropy Electrode Materials:Synthesis,Properties and Outlook

High-entropy materials represent a new category of high-performance materials,first proposed in 2004 and extensively investigated by researchers over the past two decades.The definition of high-entropy materials has continuously evolved.In the last ten years,the discovery of an increasing number of high-entropy materials has led to significant advancements in their utilization in energy storage,electrocatalysis,and related domains,accompanied by a rise in techniques for fabricating high-entropy electrode materials.Recently,the research emphasis has shifted from solely improving the performance of high-entropy materials toward exploring their reaction mechanisms and adopting cleaner preparation approaches.However,the current definition of high-entropy materials remains relatively vague,and the preparation method of high-entropy materials is based on the preparation method of single metal/low-or medium-entropy materials.It should be noted that not all methods applicable to single metal/low-or medium-entropy materials can be directly applied to high-entropy materials.In this review,the definition and development of high-entropy materials are briefly reviewed.Subsequently,the classification of high-entropy electrode materials is presented,followed by a discussion of their applications in energy storage and catalysis from the perspective of synthesis methods.Finally,an evaluation of the advantages and disadvantages of various synthesis methods in the production process of different high-entropy materials is provided,along with a proposal for potential future development directions for high-entropy materials.

Advances in Graphene‑Based Electrode for Triboelectric Nanogenerator

With the continuous development of wearable electronics,wireless sensor networks and other micro-electronic devices,there is an increasingly urgent need for miniature,flexible and efficient nanopower generation technology.Triboelectric nanogenerator(TENG)technology can convert small mechanical energy into electricity,which is expected to address this problem.As the core component of TENG,the choice of electrode materials significantly affects its performance.Traditional metal electrode materials often suffer from problems such as durability,which limits the further application of TENG.Graphene,as a novel electrode material,shows excellent prospects for application in TENG owing to its unique structure and excellent electrical properties.This review systematically summarizes the recent research progress and application prospects of TENGs based on graphene electrodes.Various precision processing methods of graphene electrodes are introduced,and the applications of graphene electrode-based TENGs in various scenarios as well as the enhancement of graphene electrodes for TENG performance are discussed.In addition,the future development of graphene electrode-based TENGs is also prospectively discussed,aiming to promote the continuous advancement of graphene electrode-based TENGs.

Gradient‑Layered MXene/Hollow Lignin Nanospheres Architecture Design for Flexible and Stretchable Supercapacitors

With the rapid development of flexible wearable electronics,the demand for stretchable energy storage devices has surged.In this work,a novel gradient-layered architecture was design based on single-pore hollow lignin nanospheres(HLNPs)-intercalated two-dimensional transition metal carbide(Ti_(3)C_(2)T_(x) MXene)for fabricating highly stretchable and durable supercapacitors.By depositing and inserting HLNPs in the MXene layers with a bottom-up decreasing gradient,a multilayered porous MXene structure with smooth ion channels was constructed by reducing the overstacking of MXene lamella.Moreover,the micro-chamber architecture of thin-walled lignin nanospheres effectively extended the contact area between lignin and MXene to improve ion and electron accessibility,thus better utilizing the pseudocapacitive property of lignin.All these strategies effectively enhanced the capacitive performance of the electrodes.In addition,HLNPs,which acted as a protective phase for MXene layer,enhanced mechanical properties of the wrinkled stretchable electrodes by releasing stress through slip and deformation during the stretch-release cycling and greatly improved the structural integrity and capacitive stability of the electrodes.Flexible electrodes and symmetric flexible all-solid-state supercapacitors capable of enduring 600%uniaxial tensile strain were developed with high specific capacitances of 1273 mF cm^(−2)(241 F g^(−1))and 514 mF cm^(−2)(95 F g^(−1)),respectively.Moreover,their capacitances were well preserved after 1000 times of 600%stretch-release cycling.This study showcased new possibilities of incorporating biobased lignin nanospheres in energy storage devices to fabricate stretchable devices leveraging synergies among various two-dimensional nanomaterials.

Laser‑Induced Highly Stable Conductive Hydrogels for Robust Bioelectronics

Despite the promising progress in conductive hydrogels made with pure conducting polymer,great challenges remain in the interface adhesion and robustness in longterm monitoring.To address these challenges,Prof.Seung Hwan Ko and Taek-Soo Kim’s team introduced a laserinduced phase separation and adhesion method for fabricating conductive hydrogels consisting of pure poly(3,4-ethylenedioxythiophene):polystyrene sulfonate on polymer substrates.The laser-induced phase separation and adhesion treated conducting polymers can be selectively transformed into conductive hydrogels that exhibit wet conductivities of 101.4 S cm^(−1)with a spatial resolution down to 5μm.Moreover,they maintain impedance and charge-storage capacity even after 1 h of sonication.The micropatterned electrode arrays demonstrate their potential in long-term in vivo signal recordings,highlighting their promising role in the field of bioelectronics.

电解水制氢技术:进展、挑战与未来展望

实现全球碳中和是各国在2050年制定的重要目标之一,旨在减缓气候变化的不良影响.氢能作为一种极具潜力的清洁能源,凭借其高能量密度、零碳排放、可再生性强等特性,被视为实现能源转型与应对气候变化的重要载体.为了实现这些目标,利用电解水制取氢气已经成为解决全球碳中和问题的重要关键方案之一.本文综述了碱性电解水、质子交换膜电解水、阴离子交换膜电解水和固体氧化物电解水制氢技术的最新进展,并对这四种电解水技术的工作原理、结构特点以及优缺点进行了详尽比较.此外,总结了电解水制氢催化剂材料的研究进展,尤其是新型材料的开发与结构优化,旨在提升材料的催化活性与稳定性.讨论了海水电解制氢和耦合制氢等新兴技术,强调通过电解质组成优化、高效双功能催化剂开发及利用小分子氧化反应热力学优势,可有效提升电解水制氢效率和系统稳定性.最后,提出了电解水制氢技术的发展趋势与未来研究方向,包括提升催化剂性能、降低电解过程能耗、开发新型电解设备等,旨在促进电解水制氢技术的进步,助力全球碳中和目标的实现,并为未来的研究提供参考与指导.

沿温度梯度热解钒多酸制备染料敏化太阳能电池V_(2)O_(3)@C对电极催化剂

以钒多酸为V源,乙二醇为C源,采用溶剂热法制备前驱体,沿温度梯度500,600,700,800,900℃热解前驱体,得到5种不同组成和形貌的V_(2)O_(3)@C复合材料,并分别将其作为染料敏化太阳能电池(DSSCs)对电极.结果显示,700℃下所制备的V_(2)O_(3)@C复合材料电催化性能最优,能量转换效率(PCE)最高,为5.57%.这归因于V_(2)O_(3)和C之间的协同作用增强了催化剂的导电性,增大了材料的比表面积而产生大量的催化活性位点.

具有新型低损耗电极PIN光探测器的研究

基于一种具有微孔-槽结构的PIN光探测器结构,设计了一种低损耗电极并与之进行联合优化。该方法不但为制备低损耗电极提供了有效的解决方案,还进一步提升了光探测器的3 dB带宽。首先,通过优化电极衬底与厚度、引入绝缘层、增加金属材料以及在衬底中加入矩形槽结构等方式,设计了一款新型低损耗的光探测器电极,降传输损耗降至-1.15 dB。然后,将新型电极与PIN光探测器的等效电路进行联合设计优化。结果表明,与未使用该新型电极相比,光探测器的3 dB带宽提升了近32%。该新型电极的设计可以为不同结构及不同波段光探测器的性能改进提供参考。

Electrode/Electrolyte Optimization‑Induced Double‑Layered Architecture for High‑Performance Aqueous Zinc‑(Dual)Halogen Batteries

Aqueous zinc-halogen batteries are promising candidates for large-scale energy storage due to their abundant resources,intrinsic safety,and high theoretical capacity.Nevertheless,the uncontrollable zinc dendrite growth and spontaneous shuttle effect of active species have prohibited their practical implementation.Herein,a double-layered protective film based on zinc-ethylenediamine tetramethylene phosphonic acid(ZEA)artificial film and ZnF2-rich solid electrolyte interphase(SEI)layer has been successfully fabricated on the zinc metal anode via electrode/electrolyte synergistic optimization.The ZEA-based artificial film shows strong affinity for the ZnF2-rich SEI layer,therefore effectively suppressing the SEI breakage and facilitating the construction of double-layered protective film on the zinc metal anode.Such double-layered architecture not only modulates Zn2+flux and suppresses the zinc dendrite growth,but also blocks the direct contact between the metal anode and electrolyte,thus mitigating the corrosion from the active species.When employing optimized metal anodes and electrolytes,the as-developed zinc-(dual)halogen batteries present high areal capacity and satisfactory cycling stability.This work provides a new avenue for developing aqueous zinc-(dual)halogen batteries.

电聚合苯胺改性碳纤维海洋电极电化学性能及其电场响应研究

本文应用碳酸氢铵弱碱性溶液作为电解质电化学原位聚合苯胺制备聚丙烯腈基碳纤维海洋电极,研究其电化学性能与电场响应性能。结果表明,碳纤维表面生成还原态聚苯胺并出现特征氧化还原峰;交流阻抗谱表明改性电极表面等效电路增加了膜电容和膜电阻,电场响应由纯电容耦合改变为电容电阻共同作用的混合机制,有利于低频低强度信号的响应。在电场响应测试中,改性电极电位漂移量达0.66 mV/d;能够较好响应10 mV,10 mHz的低频率低强度电场信号;线性度最小值为0.072%。水流冲刷4h后聚苯胺膜质量损失为6.30%,相比于盐酸溶液电聚合制得的聚苯胺膜(质量损失7.55%)具有更好的结合力。该海洋电极可望成为新一代低成本、高性能电场传感器。

不同厂家热电池FeS_(2)-CoS_(2)复合正极材料的比较研究

为了加快热电池FeS_(2)-CoS_(2)复合正极材料的优化及应用,采用两种不同厂家生产的CoS_(2)作为导电剂添加到FeS_(2)中,制备出FeS_(2)-CoS_(2)复合正极材料及其单体电池,并对两种CoS_(2)原材料、FeS_(2)-CoS_(2)复合正极材料的微观形貌、粒度分布、X射线衍射分析以及单体电池的放电性能进行了研究。结果表明,广东产的FeS_(2)-CoS_(2)正极材料具有更均匀的微观分布和较少的小粒度粒子,湖南产的FeS_(2)-CoS_(2)正极材料更适合小电流放电应用,而广东产的FeS_(2)-CoS_(2)正极材料更适合于高功率放电。此外,将两种FeS_(2)-CoS_(2)正极材料应用于某型号热电池并进行高低温放电测试,结果表明广东产的FeS_(2)-CoS_(2)正极材料在放电性能上优于湖南产的FeS_(2)-CoS_(2)正极材料。

热电池FeS_(2)-CoS_(2)复合正极材料利用率的影响因素

采用高能球磨和磁悬浮筛分法制备了不同粒径的FeS_(2)-CoS_(2)复合正极材料,并通过单体电池放电试验研究了LiB/LiCl-LiBr-KBr/FeS_(2)-CoS_(2)热电池中正极材料粒径、正负极质量比和放电温度对正极材料利用率的影响。结果表明:在450℃条件下,当FeS_(2)粒径为7.85~59.12μm时,正极材料利用率随FeS_(2)粒径的减小而增大;当FeS_(2)粒径为3.30~7.85μm时,正极材料利用率随FeS_(2)粒径的减小而减小。FeS_(2)(7.85μm)-CoS_(2)(8.06μm)复合正极单体电池的放电性能最佳,截止电压1.5 V时,其放电比容量为342.4 mA·h·g^(-1),正极材料利用率为48.8%。随着单体电池工作时间的延长,其放电比容量随正负极质量比的减小而增大,在正负极质量比为1.67时,450℃条件下的FeS_(2)-CoS_(2)复合正极单体电池的放电比容量高于400℃和500℃,截止电压1.5 V时,其放电比容量为389.2 mA·h·g-1,正极材料利用率高达55.5%。

利用溅射ITO层增强钙钛矿太阳电池的稳定性研究

为增强以银为背电极的正置结构有机-无机金属卤化物钙钛矿太阳电池(PSCs)的长期稳定性,研究利用射频磁控溅射技术在氧化钼层与银背电极之间沉积一层铟锡氧化物(ITO)来对PSCs进行内封装的技术。为防止ITO层溅射对下方已沉积的钙钛矿层和有机空穴传输层造成损伤,研究ITO层溅射功率和厚度对PSCs光伏性能的影响,获得优化的ITO层制备工艺,发现在ITO层溅射功率为30 W、厚度为40 nm时所制备的PSCs光伏性能最优。为进一步提升PSCs性能,对比溅射法和热蒸发法沉积银背电极对PSCs性能的影响,发现与蒸发法相比,采用溅射银背电极的PSCs光伏性能更佳,其光电转换效率可达到17.86%。PSCs光伏性能的长期稳定性测试和X射线衍射结果分析表明,溅射ITO阻隔层的插入可有效抑制钙钛矿层中的卤素离子与银背电极之间的扩散反应,在不降低PSCs效率的同时可显著改善PSCs稳定性,所制备的PSCs在干燥空气中存放4500h后仍能保持初始效率的95%。

棒电极直径和端部形状对短空气间隙交流击穿电压的影响研究

空气间隙交流击穿特性试验常采用棒棒、棒板电极作为试验电极,目前棒电极直径、棒端部形状对空气间隙交流击穿电压的影响尚不清晰。为此,用直径2 cm、1 cm的圆棒和直径1 cm的尖棒搭建棒棒、棒板电极,开展5~40 cm短空气间隙下的交流击穿试验,研究棒电极直径和端部形状对空气间隙交流击穿电压的影响。结果表明:在试验棒电极直径和端部形状范围内,空气间隙距离5~20 cm时,各棒棒或棒板电极空气间隙击穿电压相对偏差在5.93%~33%之间,随着空气间隙距离增大,棒电极直径和端部形状对棒棒、棒板空气间隙击穿电压的影响逐渐减弱;空气间隙距离大于20 cm时,各棒棒或棒板电极空气间隙击穿电压相对偏差均小于5%。研究认为,空气间隙距离超过20 cm时,棒电极直径和端部形状对棒棒、棒板空气间隙击穿电压无影响。

羧基化多壁碳纳米管修饰电极测定左氧氟沙星

探究了左氧氟沙星在羧基化多壁碳纳米管(c-MWCNTs)修饰电极上的电化学行为,并采用循环伏安法对左氧氟沙星含量进行了测定.结果表明,c-MWCNTs修饰电极对左氧氟沙星有明显的电催化作用;在pH值为5.0的NaH_(2)PO_(4)Na_(2)HPO_(4)缓冲溶液中,左氧氟沙星溶液的氧化峰电流与浓度在1×10^(-5)~4×10^(-4)mol/L范围内呈良好线性关系,相关系数为0.998,检出限为2.87×10^(-6)mol/L;在最优测试条件下,左氧氟沙星片剂的加标回收率为98.7%~103.0%,相对标准偏差为1.31%~3.99%(n=5);羧基化多壁碳纳米管修饰玻碳电极(c-MWCNTs/GCE)对左氧氟沙星有较好的电化学响应,灵敏度高,可用于药品中左氧氟沙星测定.

V_(1)导联r'波振幅结合阻抗变化评价左束支区域起搏电极植入深度的研究

目的:探讨左束支区域起搏时,V_(1)导联r’波振幅结合阻抗变化判断电极植入的合适深度。方法:纳入2019年1月1日至2021年12月31日于南昌大学第二附属医院就诊的心脏结构正常、有起搏器植入指征并行左束支区域起搏的住院患者78例,收集患者基线数据、术中数据和影像学资料,以及术后3、6、9和12个月的随访情况。将起搏时V_(1)导联r’波振幅、阻抗、电极植入深度进行线性相关性及回归分析。结果:78例患者中70例(89.7%)起搏时V_(1)导联QRS波末端出现r’波,8例(10.3%)QRS波表现为r S、RS型或终末端无r’波。线性相关性分析显示,r’波振幅与电极植入深度呈正相关(r=0.424,P<0.01),与阻抗呈负相关(r=-0.256,P=0.03);电极植入深度与阻抗无明显相关性(r=-0.132,P=0.27)。回归分析显示,电极植入深度是r’波振幅的重要影响因素(回归系数=0.056,P=0.000)。结合建立的回归模型和阻抗大小显示,V_(1)导联r’波振幅在0.24~0.69 mV范围内,阻抗在648.30~828.90Ω之间,电极植入深度6~11 mm最合适,穿孔风险小,且能较大概率成功夺获左束支,起搏参数满意,起搏QRS波时限较窄。在术中、术后48 h及12个月随访期间内,患者均未出现电极穿孔、血栓栓塞、心脏填塞、感染、导线脱位等并发症。结论:左束支区域起搏是一种安全可行的起搏方式。在左束支区域起搏时,V_(1)导联r’波振幅在一定合适范围内,并结合阻抗变化可指导左束支区域起搏,有助于降低电极穿孔的风险。

基于融雪效果的导电沥青路面电极优化设计

导电沥青混凝土结构设计过程中,电极的设计与优化是关键工作,决定着导电沥青路面的导电效率,影响路面融冰雪的效果。在前期试验研究的基础上,选择两种最具代表性的电极形式进行影响因素分析及优化方案设计,分别改变电极的间距、长度、材质进行实验,对比导电沥青试件的融雪效果。优化结果显示,选择铜作为电极材料,并综合考虑成本及后期对路面使用性能的影响,推荐最佳电极形式为单束铜电极,且间距为4 cm时沥青路面性价比及升温效果最佳。

基于2.5D有限元的高密度电法不同装置勘探效果研究

高密度电法是一种适用性广泛的电阻率勘探方法,拥有多种电极排列装置选择。不同装置由于电极分布方式的差异,在针对不同地质目标和测区环境时往往表现出明显不同的探测能力。为探究各排列装置的特点及其适用情况,推导了2.5D电位的变分问题,采用Delaunay三角化算法实现了非结构化网格剖分,进而实现了有限元正演模拟。结合实践,对常见地质情况进行建模,分别使用温纳α、温纳β、施伦贝谢尔、偶极-偶极4种装置开展正反演对比研究。研究发现:(1)在探测未知区域单个异常体时,温纳β、施伦贝谢尔2种排列的效果更好;(2)在探测相邻较近的多个异常体时,应优先采用具有更高水平分辨率的施伦贝谢尔和偶极-偶极排列;(3)对于低阻破碎带的勘探,温纳β和偶极-偶极排列更为适用;(4)当地层具有较好分层界限时,4种排列均可体现良好的分层效果。因此,高密度电法勘探实践中应综合考虑不同排列装置的特点,根据具体情况选用合适的多种排列方式进行测量,并对采集数据进行综合对比分析,以获得更为准确的解释结果。

负载型三维电极-电Fenton法处理活性艳橙X-GN废水

三维电极-电Fenton法是一种在电Fenton的基础上引入三维电极电催化技术的新型高级氧化法,在水处理中得到了广泛的应用。用过量浸渍煅烧法制备负载型三维电极,以采用该电极的三维电极-Fenton法处理活性艳橙X-GN废水。通过试验研究了pH、电压、Na_(2)SO_(4)投加量、Fe^(2+)投加量对处理效果的影响,并采用响应曲面法最优化实验条件。结果表明,当试验pH=4.7,电压为20.39 V,Na_(2)SO_(4)投加量为2.13 g/L,Fe^(2+)投加量为2.5 mmol/L时,COD和色度去除率可以达到85.41%和92.18%。负载型三维电极-电Fenton法对活性艳橙X-GN废水的色度和COD均具有较理想的处理效果。

基于电介质薄膜的器件自愈性能的研究现状

随着能源与电力技术的不断发展,对电容器的需求越来越大,而各种资源的稀缺强调了利用各种能源的必要性,对于各种储能器件如金属化薄膜电容器以及基于电活性聚合物(electroactive polymers,EAP)的能量转换装置提出了更高的要求。然而这两类装置却极易发生电击穿,在工作循环中有着极高的故障率,因此器件的自愈性具有十分重要的意义。文中综述了金属化薄膜电容器和EAP能量转换装置自愈性能的国内外研究现状,首先重点关注了金属化薄膜电容器中自愈理论发展以及各种关键参数对自愈的影响,其自愈最为稳定且研究相对完善。随着介电弹性体的兴起,想要其拥有自愈性能,参考金属化薄膜电容器的结构是一个可行的思路。但如何使得金属电极满足大应力大形变的需求成为一种柔性电极是一个很大的挑战。碳电极是弹性体中应用最为广泛的电极材料,它拥有极好的形变能力,但对于其自愈性能的深入研究较少且缺乏成熟的理论支撑,使得其在工业领域中难以应用和改善。最后总结对比了金属电极以及碳电极在自愈性能上的差异,并预测了可自愈柔性电极新的发展方向,进一步拓展自愈性的器件在工业领域中的应用。