一种压电陶瓷水听器极性专用检测设备的设计

作为水声检测领域的关键传感器,水听器有着广泛的应用。在生产过程中,水听器容易出现极性不易辨别的情况。极性反接将影响后续波束形成、时频分析等一系列算法,导致直接的运算结果偏离甚至错误。对此,提出一种简单易用的水听器极性检测方法。基于此方法,设计一款水听器极性专用检测设备。经测试,该设备使用便捷、快速,结果简单、可靠,能够较大地提高生产便利性。     

一种温差发电式激光指示器设计

激光指示器是一种使用广泛的激光手握笔型发射器,针对目前激光指示器供电电源容量有限、耐用度低等问题,设计了一种温差发电式激光指示器,利用热电材料的赛贝克效应和碳纳米管薄膜热电发电结构产生电流用于激光二极管的供电,设计散热结构以维持发电结构两端的温差,通过升压稳压电路产生稳定的电动势,从而提高装置工作的可靠性。     

谐振调幅压电石英晶体分子键裂型传感仪的研制北大核心CSCD

基于谐振调幅激励压电石英晶体开发了一种分子键裂型传感仪。该传感系统通过数字信号发生器DDS 9854产生频率可调的正弦波,激励9.98 MHz的压电石英晶体,经信号放大滤波后得到谐振频率。通过数控技术调节激励电压实现谐振调幅,以增大石英晶振表面的剪切动量。当调幅到一定程度会导致分子间键断裂,通过调幅电压值测定分子键的强度,可在数分钟内得到晶体表面的结合质量和结合强度的信息。使用了谐振调幅压电石英晶体分子键裂型传感仪检测了不同粒径的氨基纳米磁珠与金电极之间的相互作用,由频率信号得到磁珠在金电极上的结合量。通过不同谐振调幅电压激励石英晶体以甩脱电极表面的磁珠,由激励电压得到不同粒径的氨基纳米磁珠与金电极间的键裂力为2±0.5 nN。本仪器的研制为传感分子间的相互作用提供了一种新技术,可快速检测鉴别键的强度。     

动力学—压电石英晶体传感器测定水中微量汞的研究

基于涂银压电石英晶体对ＣＮ＾－离子的灵敏响应，应用汞对六氰合铁酸钾与邻二氮杂菲反应的动力学催化作用，建立了动力学－ＰＱＣ传感器单面触液测定微量汞的新方法。研究了ＰＱＣ传感器对汞的响应机理，响应曲线，实验条件及共存离子干扰情况。     

二维铁电材料ABP2X6内在极高的负泊松比

Recently, ferroelectric materials have attracted considerable research attention. In particular, two dimensional (2D) ferroelectric materials have been considered as most crucial for next-generation circuit designs because of their application as novel electric memory devices. However, a 2D ferroelectric material is very rare. The ferroelectric materials with the form ABP₂X₆ (A = Ag, Cu; B = Bi, In; X = S, Se) are of interest because of their ferroelectric property maintained in their ultrathin structures. Within the ABP₂X₆ monolayer, the P―P bonds form the pillars that hold the top and bottom X planes, while the off-center A―B atoms between the X layers induce a spontaneous ferroelectric polarization. If the two off-center A―B sites are equally aligned, this would lead to the appearance of the paraelectric state. Such intriguing structures must impart novel mechanical properties to the materials. Until now, there has been no report on the mechanical properties of monolayer ABP₂X₆. Based on first-principles calculations, we studied the structural, electronic, mechanical as well as the electromechanical coupling properties of monolayer ABP₂X₆ (A = Ag, Cu; B = Bi, In; X = S, Se). We found that they are all semiconductors with wide bandgaps of 2.73, 2.17, 3.00, and 2.31 eV for CuInP₂Se₆, CuBiP₂Se₆, AgBiP₂S₆, and AgBiP₂Se₆, respectively, which are calculated based on the Heyd-Scuseria-Ernzerhof (HSE) exchange correlation functional model. The conduction band minimum is mainly from p orbitals of X and B atoms, whereas the valence band maximum is due to the hybridization of the p orbital of X atoms and the d orbital of A atoms. Moreover, there are three short and three long A/B―X bonds due to the A―B off-center displacement. Together with the d-p orbital hybridization, the main reason for the distorted ferroelectric structure in ABP₂X₆ monolayers is the Jahn-Teller effect. ABP₂X₆ monolayers are predicted to be a new class of auxetic materials with an out-of-plane negative Poisson's ratio, i.e., the values of the negative Poisson's ratio are in the order AgBiP₂S₆ (−0.805) < AgBiP₂Se₆ (−0.778) < CuBiP₂Se₆ (−0.670) < CuInP₂S₆ (−0.060). This is mainly due to the tensile strain applied in the x/y direction enlarging the angle between P―P bonds and top layer X atoms, thereby enhancing the bucking height of monolayer ABP₂X₆. Moreover, external strain has a significant impact on the A―B off-center displacement, rendering an out-of-plane piezoelectric polarization. The values of e₁₃ for CuInP₂S₆, CuBiP₂Se₆, AgBiP₂S₆, AgBiP₂Se₆ monolayers are calculated to be −3.95 × 10⁻¹², −5.68 × 10⁻¹², −3.94 × 10⁻¹², −2.71 × 10⁻¹² C∙m⁻¹, respectively, which are comparable to the only experimentally confirmed 2D out-of-plane piezoelectric Janus system (piezoelectric coefficient = −3.8 × 10⁻¹² C∙m⁻¹). This unusual auxetic behavior, ferroelectric polarization, and the electromechanical coupling in monolayer ABP₂X₆ could potentially lead to enormous technologically important applications in nanoelectronics, nanomechanics, and piezoelectrics.     

增塑的PVC涂膜压电晶体传感器阵列用作香味传感系统

增塑的ＰＶＣ涂膜压电晶体传感器阵列用作香味传感系统曹忠，林辉概，王彬锋，王柯敏，陈泽忠，俞汝勤（湖南大学化学化工系，长沙，４１００８２）关键词阵列，压电晶体传感器，增塑的ＰＶＣ涂膜，香味传感系统吸附活性物质如类脂化合物等涂膜的压电晶体传感器（ＰＣＳ）...     

基于压电振荡原理的微阵列点样系统的研制

针对基于电磁微阀原理的非接触点样方式存在操作过程复杂、点样量偏大,以及压电喷墨原理的非接触点样方式存在点样针不易清洗、造价昂贵等不足,研制了一种基于压电振荡原理的新型非接触点样装置,实现了微量液体点样.在本装置中,毛细管点样针与压电驱动装置为两个独立单元,可以单独对毛细管点样针进行更换和清洗.采用激光拉制法制备的玻璃毛细管点样针具有内径可调、成本低等优点.此点样方式通过改变压电陶瓷的振幅和频率,可在10Symbolm@@_10～10Symbolm@@_9 L之间调控点样体积.以此为基础,结合三维精密位移控制技术,研制了一种基于压电振荡原理的微阵列生物芯片点样系统.对点样系统的点样体积、点样密度、点样精度等参数进行了测试,结果表明,此点样系统的最小点样体积可达320 pL,点样密度可达4000 点/cm2,并能够实现界面图案化制备.     

压电增强的等离激元光催化材料Ag/BaTiO3的制备及性能研究

针对光催化过程中的低光利用率和低催化效率，采用光化学还原法将Ag纳米颗粒均匀修饰在BaTiO₃纳米压电材料表面，制备了x mol/L-Ag/BaTiO₃（x=0.01、0.02、0.04，x为Ag的浓度）等离激元压电光催化剂.研究了压电光催化过程中的反应机理及等离激元颗粒负载的浓度对光催化剂性能的影响.研究结果显示，0.02 mol/L-Ag/BaTiO₃在全光谱光辐照和超声激发的压电场的辅助下，在75 min内可降解91%的罗丹明B，将降解效率提升了21%，证实了纳米复合结构中压电势对表面等离激元光催化活性的重要影响.催化性能的提升源于压电效应和表面等离子体共振效应的协同作用.Ag纳米颗粒的等离子体共振效应（LSPR），使光吸收范围从紫外光区扩大至可见光波段.超声驱动可使BaTiO₃纳米压电体发生形变而于表面产生压电电荷，压电势的存在进一步增强了LSPR诱导的光生载流子分离，促进羟基自由基的生成，加速有机染料的降解.本工作将BaTiO₃的压电效应引入等离子体光催化中，可推广到其他材料和催化系统中，为环境净化提供一种有效的技术.     

基于巯基和聚电解质双层自组装膜的压电免疫传感器检测小鼠IgG气溶胶

本文结合自组装单分子层膜(SAMs)和聚电解质静电吸附组装技术,提出了一种新的用于气相压电免疫检测的生物分子固定化方法,研制了一种用于检测小鼠IgG抗体的压电免疫传感器。首先在石英晶片的金电极表面自组装了一层L-胱氨酸SAMs,再在膜上组装带相反电荷的海藻酸钠,最后通过调节pH值定向固定羊抗鼠纯化抗体,优化了固定条件。通过超声雾化法产生的小鼠IgG气溶胶,研制成了直接气相检测小鼠IgG的压电免疫系统。结果表明,该方法对所固定的生物分子活性影响较小,传感器对小鼠IgG的响应快,灵敏度高,在0.14~6μg.μL-1范围内具有良好的线性关系,精密度好,再生方便。     

压电免疫质量传感器中生物大分子的固定化方法

评述了近十几年来压电免疫质量传感器研究中的关键技术－生物分子固定化方法的研究应用,并对固定化方法的发展予以展望。