Highly Porous Fibers by Electrospinning into a Cryogenic Liquid

静电纺丝英文解释Electrospinning is a fascinating technique used to create ultra-thin fibers from various polymers. It involves the application of high voltage to a polymer solution, causing the formation of a tiny jet that stretches into a fiber as the solvent evaporates.This process is highly versatile, allowing for the production of fibers with diameters ranging from nanometers to micrometers. The resulting fibers are known for their high surface area to volume ratio, which makes them ideal for applications in filtration, tissue engineering, and drug delivery.The science behind electrospinning is rooted in the interaction of electric forces and surface tension. When the voltage is applied, the polymer solution forms a conical shape known as the Taylor cone. The electric field overcomes the surface tension, and the jet of polymer is ejected towards a grounded collector.The versatility of electrospinning is further enhanced by the wide range of materials that can be used, including synthetic polymers, natural proteins, and even inorganic materials. This opens up a plethora of possibilities for researchers and engineers to tailor-make fibers for specific applications.Moreover, the process is scalable and can be adapted for both laboratory research and industrial production. The control over fiber diameter, orientation, and composition makes electrospinning a powerful tool in the field of material science.In summary, electrospinning is a cutting-edge technology with a wide array of applications. Its ability to produce fibers with unique properties has made it an indispensable technique in modern material fabrication.。

本文的宗旨是为了说明在硅制成的平板热管中如何使用共聚焦显微镜研究半月板特征的情况。

毛细管结构是宽度从外围下降到系统中心的径向细纹组成，透明板用来关闭系统，并允许可视化效果。

共聚焦同时测量方法可以让里面的沟槽形状和液膜冷凝薄膜对鳍。

薄膜厚度小于10米,测量结果表明薄膜形式的冷凝水的凹槽连接到一个要求他们降低半月板曲率是颠倒的。

因此，一个非常薄的区域将存在其中的液体形成经缩合排入沟槽。

液滴的曲率半径从冷凝器到蒸发器逐渐下降如同半月板在沟槽中一样。

因此，一部分液体是通过从蒸发器到冷凝器的翅片排出的。

此外，凝膜覆盖了系统的很大一部分，也可以在高热流中接触。

分类号：10.1115/1.4000057 、关键词：蒸发，冷凝，热管平板，薄膜，毛细现象1简介平板式热管|是微流体装置。

通常设计用于电子元件的热管理1但可用于其它应用，如冷却质子交换膜燃料电池2。

他们是用他们的换热能力，以及他们的能力均质温度。

平板式热管是两相填充满工作液小厚度腔体。

热源和散热器固定在腔体的某些位置同时其他部分隔离。

热量是通过液体汽化和蒸汽冷凝从热源传到散热器的。

该系统的发生蒸发和冷凝的地方发装有蒸发器和冷凝器，分别地。

液体通过密纹或网状物制成毛细管结构从蒸发器回到冷凝器。

自20世纪90年代，热管响应电子冷设备却需求已经微型化，可以小到电子元件的那样。

平板式热管通常是由铜2-4制成用来增加其热转移的能力，但现在首选硅系统创建更小的设备5,6。

事实上，硅是微电子材料其蚀刻技术可以用来实现各种形状的小毛细结构。

此外，在硅材料平板式热管可以集成在电子元器件的核心，避免了冷却设备和电子元件热阻接触虽然在平板热管道有很多作品已发表，但有实验性的作品很少很少，尤其是对硅系统。

此外，所提供的测量不足以描述这些系统的行为，但只估计他们的整体散热性能。

只通过温度传感器驱动热管的物理现象是复杂的甚至是不能被理解的。

这些系统中的温度场主要归结于毛细管结构内的蒸发和冷凝现象。

基于无机钙钛矿(CsPbX3)量子点的发光二极管近年来，半导体量子点因其独特的光学性质，例如不同的发射波长，窄的发射光谱，以及高的发光效率等，近年来受到了广泛的关注。

所有这些极具吸引力的特性使得量子点成为下一代照明和显示器件以及光通信技术的优秀首选。

自从1994年，第一个CdSe量子点发光器件（QLEDs）被报道之后，包括硫化镉，碲化镉，铟@ ZnSeS，和Cu掺杂ZnInS在内的各种量子点相继被报道。

显然，过去20年研究QLEDs的主要材料都局限在纤锌矿和闪锌矿镉的量子点。

在过去的两年中，卤化物钙钛矿材料由于其出色的性能，被证明是令人惊叹的半导体材料，无论它是应用于太阳能电池，还是发光二极管亦或是激光器。

然而，有机–无机混合卤化物钙钛矿材料的稳定性是一个关键问题(CH3NH3PbX3, X = I, Br, Cl)。

与其相比较而言，所有无机钙钛矿材料具有较高的稳定性并且在各种光电器件中有着巨大潜能。

为了将高稳定性和量子限制效应整合在一起，科瓦连科和同事制作铯铅的卤化物（CsPbX3，X = Cl，Br，I）量子点，此卤化物具有出色的光学性能，尤其是可调谐、高量子产率的光致发光（PL）。

这个灵感来自近代激光和CH3NH3PbX3发光二极管，这些所有的无机钙钛矿型量子点所拥有的巨大潜能，会使它在QLED的应用中成为一种新型的发光材料。

到目前为止，所有的关于铅铯的无机钙钛矿纳米晶还未见报道。

这里，我们第一次制备出了这种铯铅无机钙钛矿纳米晶，其高质量的量子点通过将硬脂酸铯（CsSt）以热注入的方式滴入PbBr2溶液中合成。

发光波长可以通过量子点的大小和更换不同的卤族元素进行改变（Cl，Br，I）。

量子点能很容易地在各种非极性溶剂中扩散（比如：甲苯、辛烷、己烷），其中这里的非极性溶剂指基于用溶液法制备光电器件的旋涂液。

典型QLED装置由ITO / PEDOT:PSS/PVK/QDs/ TPBi /LiF/Al组成，电致发光呈现出蓝光，绿光，黄光，这表明所有的无机钙钛矿型量子点可能成为一种新的应用于低成本显示、照明和光通信技术的材料。

吸波材料英文Absorbing materials, also known as absorbers, are materials that can effectively absorb and attenuate electromagnetic waves, including microwave, radar, and radio waves. These materials are widely used in various fields such as telecommunications, electronics, aerospace, and defense. In this document, we will discuss the characteristics, types, and applications of absorbing materials in the English language.Firstly, absorbing materials possess the ability to absorb and convert electromagnetic energy into heat, thus reducing the reflection and transmission of electromagnetic waves. This unique property makes them essential in minimizing interference and improving the performance of electronic devices and systems. Additionally, absorbing materials can also be utilized for stealth technology, where they are employed to reduce the radar cross-section of aircraft and military equipment.There are several types of absorbing materials, each with its own specific composition and functionality. Ferrite-based absorbing materials, for example, are composed of magnetic materials such as iron, nickel, and cobalt, and are effective in absorbing high-frequency electromagnetic waves. On the other hand, carbon-based absorbing materials, which contain carbon particles or fibers, exhibit excellent absorption properties for microwave and radio waves. Furthermore, magnetic absorbing materials, dielectric absorbing materials, and hybrid absorbing materials are also commonly used in various applications.The applications of absorbing materials are diverse and extensive. In the field of telecommunications, absorbing materials are employed to reduce electromagnetic interference and improve signal quality in antennas, radomes, and communication equipment. In the electronics industry, they are utilized to suppress electromagnetic noise and enhance the performance of electronic devices. Moreover, in the aerospace and defense sectors, absorbing materials play a crucial role in stealth technology, electronic warfare, and radar-absorbing structures.In conclusion, absorbing materials are indispensable in the field of electromagnetic wave control and management. Their unique ability to absorb and attenuate electromagnetic energy makes them essential in various applications, ranging from telecommunications and electronics to aerospace and defense. With different types and compositions available, absorbing materials continue to play a significant role in advancing technology and improving the performance of electronic systems.。

物 理 化 学 学 报Acta Phys. -Chim. Sin. 2024, 40 (3), 2305007 (1 of 11)Received: May 8, 2023; Revised: June 5, 2023; Accepted: June 20, 2023; Published online: June 28, 2023. *Correspondingauthors.Emails:***************(T.Y.);***************.cn(L.-F.C.)The project was supported by the National Natural Science Foundation of China (52374301, U1960107, 22075269, U2230101, GG2090007003), the Anhui Provincial Major Science and Technology Project (202203a05020048), the Fundamental Research Funds for the Central Universities (N2123001, WK2480000007), the Anhui Provincial Hundred Talents Program, the Hefei Innovative Program for Overseas Excellent Scholar (BJ2090007002), USTC Startup Program (KY2090000062, KY2090000098, KY2090000099), the Performance Subsidy Fund for Key Laboratory of Dielectric and Electrolyte Functional Material Hebei Province (22567627H).国家自然科学基金(52374301, U1960107, 22075269, U2230101, GG2090007003), 安徽省科技重大专项(202203a05020048), 中央高校基本业务费(N2123001, WK2480000007), 安徽省百人计划(青年)项目, 合肥市留学人员创新项目(BJ2090007002), 中国科学技术大学启动基金(KY2090000062, KY2090000098, KY2090000099), 河北省电介质与电解质功能材料重点实验室绩效补助经费(22567627H)资助© Editorial office of Acta Physico-Chimica Sinica[Article] doi: 10.3866/PKU.WHXB202305007 Rational Design of Cross-Linked N-Doped C-Sn Nanofibers as Free-Standing Electrodes towards High-Performance Li-Ion Battery AnodesYing Li 1, Yushen Zhao 1,2, Kai Chen 3, Xu Liu 1,2, Tingfeng Yi 1,2,*, Li-Feng Chen 3,*1 School of Materials Science and Engineering, Northeastern University, Shenyang 110819, China.2 Key Laboratory of Dielectric and Electrolyte Functional Material Hebei Province, School of Resources and Materials, NortheasternUniversity at Qinhuangdao, Qinhuangdao 066004, Hebei Province, China.3 CAS Key Laboratory of Mechanical Behavior and Design of Materials (LMBD), Department of Thermal Science and EnergyEngineering, School of Engineering Science, University of Science and Technology of China, Hefei 230026, China.Abstract: Li-ion batteries (LIBs) have been considered as one of the most promising power sources for electric vehicles, portable electronics and electrical equipment because of their long cycle life and high energy density. The free-standing electrodes without binder, current collector and conductive agent can effectively obtain lager energy density as compared to the traditional electrodes where the addition of inactive components is required. In addition, the free-standing electrode plays an important role in developing flexible electronic devices. Currently, conventional graphite isstill the main commercial anode material, but its theoretical specific capacity is limited, and the rate performance is poor. In recent years, the high temperature pyrolytic hard carbon has attracted wide attention due to its higher theoretical specific capacity and more defects than graphite carbon. Moreover, polymer polyacrylonitrile (PAN) can be used as the raw material for preparation of free-standing anodes without any conductive additives or binders by electrospinning technique. Meanwhile, it is beneficial to reduce the production cost and simplify the manufacturing procedures of electrode. However, PAN-based hard carbon anode materials also have certain problems, such as low conductivity, poor rate performance, unsatisfactory cycling stability, and inferior initial Coulombic efficiency (CE). In addition, soft carbon has advantages of high carbon yield, good conductivity, superior cycling stability, high initial CE and relatively low price, but its specific capacity is generally lower than that of hard carbon materials. Based on above analysis, carbon anode materials with good electrochemical performance can be obtained by combining hard carbon and soft carbon, but the specific capacity of carbon materials is still low. Tin (Sn), as an anode material for LIBs, has a high theoretical specific capacity (994 mAh·g −1) and a low lithium alloying voltage. Nonetheless, the practical use of Sn anode has been limited by its huge volume change (theoretically ∼260%) during the repeated alloying-dealloying process, resulting in large pulverization and cracking, which triggers the rapid capacity fading. Hence, in order to increase the specific capacity of carbon anode materials of LIBs, the C-Sn composite film with uniform Sn nanoparticles embedded in N-doped carbon nanofibers was prepared byelectrospinning method following by a low-temperature carbonization process. The film was directly used as a free-standingelectrode for LIBs and exhibited good electrochemical performance, and the introduction of Sn significantly improved the electrochemical properties of the carbon nanofiber film. The formed fibrous structure after Sn was uniformly coated with carbon can promote the conduction of ions and electrons, and effectively buffers the volume change of Sn nanoparticles during cycling, thus effectively preventing pulverization and agglomeration. The C-Sn-2 electrode with a Sn content of about 25.6% has the highest specific capacity and best rate performance among all samples. The electrochemical test results show that, the charge (discharge) capacity reaches 412.7 (413.5) mAh·g−1 at a current density of 2 A·g−1 even after 1000 cycles. Density functional theory (DFT) calculations show that N-doped amorphous carbon has good affinity with lithium, which is conducive to anchoring the Sn x Li y alloy formed after alloying reaction on the carbon surface, thereby relieving the volume change of Sn during charge-discharge. This article provides a feasible strategy for the design of high-performance lithium storage materials.Key Words: Free-standing electrode; Carbon nanofiber; Metallic Sn; Li-ion battery; Cycling stability高性能锂离子电池用N掺杂C-Sn交联纳米纤维自支撑电极的理性设计李莹1，赵钰燊1,2，陈凯3，刘旭1,2，伊廷锋1,2,*，陈立锋3,*1东北大学材料科学与工程学院，沈阳 1108192东北大学秦皇岛分校资源与材料学院，河北省电介质与电解质功能材料重点实验室，河北秦皇岛 0660043中国科学院材料力学行为与设计重点实验室，中国科学技术大学工程科学学院热科学和能源工程系，合肥 230026摘要：为了提高碳材料作为锂离子电池负极材料的比容量，将氮掺杂的碳纤维与高容量的Sn进行复合。

高导热环氧复合材料干式电抗器热点温升的仿真研究曲展玉1，钟昱尧1，宋岩泽1，2，谢子豪1，孟雨琦1，谢庆1，2（1.华北电力大学电力工程系，河北保定071003；2.华北电力大学新能源电力系统国家重点实验室，北京102206）摘要：干式电抗器的稳定运行影响新型电力系统的输电可靠性。

干式空心电抗器包封材料整体由浸有环氧树脂的玻璃纤维丝经高温固化而成。

本文采用多物理场耦合有限元方法，考虑干式空心电抗器的包封材料热导率对其热点温升的影响，建立了环氧复合材料的COMSOL微观仿真模型和外电路约束下的干式空心电抗器电-磁、流-热耦合计算模型。

将电磁场下的损耗作为热源计算温度场与流场分布，研究在25℃环境温度下常规/高导热环氧复合材料对干式空心电抗器热点温升的影响规律。

结果表明：高导热环氧树脂对复合材料热导率的提升效果显著；包封材料本体及周围空气温度场区域中热点温升最大值为103.75℃，出现在内部第4层包封材料的上端处；不同热导率的复合材料对降低干式电抗器的热点温升有明显差异，其中干式电抗器在高导热环氧树脂复合材料下的热点温度降低了7.55℃。

关键词：干式空心电抗器；热导率；热点温升；多物理场耦合中图分类号：TM215；TM472 DOI:10.16790/ki.1009-9239.im.2024.04.015Simulation study on hot spot temperature rise of dry reactor with high thermal conductive epoxy composite as encapsulating materialQU Zhanyu1, ZHONG Yuyao1, SONG Yanze1,2, XIE Zihao1, MENG Yuqi1, XIE Qing1,2(1. Department of Electrical Engineering, North China Electric Power University, Baoding 071003, China;2. State Key Laboratory of Alternate Electrical Power System with Renewable Energy Sources,North China Electric Power University, Beijing 102206, China)Abstract: The stable operation of dry-type reactors affects the transmission reliability of new power system. The encapsulating material of dry-type reactor is made of glass fiber filament impregnated epoxy resin cured at high temperature. In this paper, a multiphysics coupled finite element method was used to consider the influence of thermal conductivity of the encapsulating material for dry-type reactor on its hot spot temperature rise, and a COMSOL microscopic simulation model of epoxy composites and an electro-magnetic and flow-thermal coupling calculation model of dry-type reactor under the constraints of external circuits were established. The temperature field and flow field distribution were calculated by using the loss under electromagnetic field as the heat source, and the influence of conventional/high thermal conductive epoxy composites on the hot spot temperature rise of the dry-type reactor at 25℃ of ambient temperature was studied. The results show that the high thermal conductive epoxy resin has a significant improving effect on the thermal conductivity of composites. The maximum hot spot temperature rise in the temperature field area of the encapsulating material body and the surrounding air is 103.75℃, which appears at the upper end of the fourth layer of encapsulating material. The epoxy resin composite with different thermal conductivity has obvious difference on decreasing the hot spot temperature of dry-type reactor, and the hot spot temperature of the dry-type reactor with high thermal conductive epoxy resin composite is reduced by 7.55℃.Key words: dry hollow reactor; thermal conductivity; hot spot temperature rise; multiphysical field coupling0　引言干式电抗器凭借线性度好、饱和性高、损耗小、运行维护方便等优点已成为在“双碳”战略下构建新型电力系统的重要发展方向[1]。

1.用英文作自我介绍回答问题：请简单说明什么事聚合物的粘弹性，并说明它与低分子液体流动的区别？朗读并翻译以下段落Larger diameter (50-10nm) vapor grown carbon nanofibers can be well dispersed in polypropylene melt, while singe wall carbon nanotubes(swnt) were not as well dispersed, techniques such as end-group functionalization, use of ionic surfactants, shear mixing and plasma coating have been used to improve dispersion and exfoliation of carbon nanotubes in polypropylene compatibility with fillers has been improved by matrix modification by grafting it with reactive moieties,such as acrylic acid,acrylic esters,and maleic anhydride.2.高聚物与高聚物之间相容性的好坏可以通过什么方法加以评价？A new copolyamide,nylon 6 11,was prepared by hydrolytic polymerization and melt polycondensation and characterized by means of intrinsic viscosity,fourier transform infraed(ftir) spectroscopy and differemtial scanning calorimetry(DSC)in this paper.it was found that the intrinsic viscosity of nylon 6 11 copolymerization time under vacuum. however,the incorporation of caprolactam into nylon 11 chains did not transform the crystal phase of nylon 11.3.请问聚合物分子量的测试方法有哪些？并描述其中两种测试方法的测试原理？Solutions of poly(ethylene-co-vinyl alcohol) or evoh,ranging in composition from 56 to71 wt% vinyl alcohol,can be readily electrospun at room temperature from solutions in 70% 2-propanol/water. The solutions are prepared at 80? And allowed to cool to room temperature. Interestingly, the solutions are not stable at room temperature and eventually the polymer precipitates after several hours. However,prior to precipitation,electrospinning is extensive and rapid,allowing coverage of fibers on various substrates. Fiber diameters of ca. 0.2-0.8um were obtained depending upon the solution concentration.4.用于生产合成纤维的高分子的分子量与橡胶、塑料相比有什么不同，结构有何差异？The use of macromonomers is a convenient method for preparing branched polymers. However,graft copolymers obtained by conventional radical copolymerization of macromonomers often exhibit poorly controlled molecular weights and high polydispersities as well as large compositional heterogeneities from chain-to-chain. In contrast,the development of “living”/contolled radical polymerization has facilitated the precise synthesis of well-defined polymers with low polydispersities in addition to enabling synthetic chemists to prepare polymers with novel and complex architectures.5.如何测定A Vrami指数？Avrami指数物理学上有什么意义？The thermal and electrical conductivities in nanocomposites of single walled carbon nanotubes(swnt) and polyethylene(pe)are investigated in terms of swnt loading, the degree of PEin thermal conductivity with increasing swnt loading,having 1.8 and 3.5 w/mk at a swnt volumefraction of ?~0.2 in low-density pe(ldpe)and high-density PE(hdpe),respectively.this increase suggests a reduction of the interfacial thermal resistance. Oriented swnt/hdpe nanocomposites exhibit higher thermal conductivities, which are attributed primarily to the aligned pe matrix. 6.请陈述你对“高分子”的理解？在你印象中，你知道哪些常用的聚合物品种？请列举其中两种聚合物品种的应用？We previously discovered that isotropic monomer solution shows birefringence due to its anisotropic structure after gelation in the presence of a small amount of rod-like polyelectrolyte. Here, we focus on what mechanism is responsible for the formation of anisotropic structure during gelation. Various optical measurements are performed to elucidate the structure change during gelation. It is found that the existence of a large-size structure in monomer solution with the rod-like polyelectrolyte is essentially important to induce birefringence during gelation.7.如何提高尼龙66的分子量？This work examines the pbt/pet sheath/core conjugated fiber, with reference to melt spinning,fiber properties and thermal bonding. Regarding the rheological behaviors in the conjugated spinning, pet and pbt show the smallest difference between their melt-viscosity at temperatures of 290 and 260 respectively,which has been thought to represent optimal spinning conditions. The effect of processing parameters on the crystallinity of core material-pet was observed and listed. In order of importance,these factors are the draw ratio,the heat-set temperature,and the drawing temperature.8.你对白色污染有何看法？你认为可以实现高分子得循环利用吗？Thermoresponsive shape memory fibers were prepared by melt spinning from a polyester polyol-based polyurethane shape memory polymer and were subjected to different postspinning operations to modify their structure. The effect of drawing and heatsetting operations on the shape memory behavior,mechanical properties,and structure of the fibers was studies. In contrast to the as-spun fibers, which were found to show low stress built up on straining to temporary shape and incomplete recovery to the permanent shape,the drawn and heat-set fibers showed signficantly higher stresses and complete recovery.9.在自由基聚合中存在反应的自加速现象，请简单说明产生的原理并说明如何采用措施来调整反应的速率？The dry-jet-wet spinning process was employed to spin poly(lactic acid)fiber by the phase inversion technique using chloroform and methanol as solvent and nonsolvent, respectively, for pla. The as-spun fiber was subjected to two-stage hot drawing to study the effect of various process paraments, such as take-up speed,drawing temperature, and heat-setting temperature on the fiber strucural properties. The take-up speed had a pronounced influence on the maximun draw ratio of the fiber. The optimum drawing temperature was observed to be 90 to get a fiber10.什么是晶体，如何测定晶胞参数，密勒指数，高分子材料的结晶行为与小分子材料比有什么区别？The electrostatic spinning technique was used to produce ultrafine polyamide-6 fibers. The effect of solution conditions on the morphological appearance and the average diameter of as-spun fibers were investigated by optical scanning and scanning electron microscopy techniques. It was shown that the solution properties(i.e.viscosity,surface tension and conductivity) were important factors characterizing the morphology of the fibers obtained. Among these three properties,solution viscosity was found to have the greatest effect. Solutions with high enough viscosities were necessary to produce fibers without beads.11.如何测定高分子的分子量，不同的方法得到的结果有什么差异？Ternary blend fibers(TBFs) , based on melt blend of poly(ethylene 2,6-naphthalate),poly(ethylene terephthalate), and a thermotropic liquid-crystal polymer(TLCP),were prepared by a process of melt blending and spinning to achieve high performance fibers. The reinforcement effect of the polymer matrix by the TLCP component,the fibrillar structure with TLCP fibrils of high aspect ratios,and the development of more ordered and perfect crystalline structures by an annealing process resulted in the improvement of tensile strength and modulus for the TBFs.12.高分子材料制成制品需要经过成型加工步骤。

The Principles and Applications ofElectrospinningElectrospinning是一种新兴的纳米纤维制备技术，已经被广泛应用于生物医学、材料科学、环境工程等领域。

本文将介绍电纺制备技术的原理、工艺条件、导电纤维、生物纤维以及电场稳定性等方面，以及该技术的未来发展方向。

一、电纺技术的原理电纺技术是指通过高压电场将高分子溶液或熔融体液喷出纳米尺寸的连续纤维。

实际上，通过正电荷的高分子溶液在电场中受到电荷作用，发生的伸长和碎裂的过程，在强的电场下，液滴被拉成了一个细长的柱状体，并通过溶液液滴表面的电荷释放高的表面电荷电流，在几个毫秒到微秒级别下，柱状体逐渐拉伸并在空气中形成了纳米纤维。

电纺纤维的直径取决于喷液压力、电场强度、高分子溶液的性质等因素。

二、电纺技术的工艺条件电纺技术的工艺条件包括高分子溶液性态、高压喷液设备、喷液距离、电场强度、湿度、温度等因素。

高分子材料的性质是影响电纺纤维直径和形态的最重要的因素。

高分子硬度越大，电纺纤维的直径越小。

在选择可溶性和可熔性的高分子溶液制备时，关键是确保高分子溶解度和收缩力的合理匹配。

在工艺操作中，喷液和收集器的距离应该适当，并正确设置喷液压力和电场强度，以控制电纺纤维的直径和分布均匀性。

此外，湿度和温度也会影响电纺纤维的形态与热稳定性。

三、导电纤维的制备与应用电纺技术中的导电纤维是指通过使用导电剂将高分子纤维导电化的过程，进而制备具有导电性的纳米纤维。

导电剂可以将高分子纤维导电化，并在通电过程中形成高度稳定的导电网络。

通过电纺产生的导电网络可以被制成热稳定的导电剂，并具有优异的导电性、耐热性和机械稳定性。

导电纤维在电子器件、光电器件、能量存储设备、生物传感器等方面具有广泛的应用前景。

四、生物纳米纤维的制备与应用生物纳米纤维是指以生物高分子为主要材料，通过电纺技术制备的纳米纤维。

生物高分子通常是一些天然物质，如含有丝素的蜘蛛网丝、含有胶原蛋白的动物皮肤和肌肉，以及含有淀粉的植物中的纤维素等。

大连理工大学硕士学位论文摘要活化的过硫酸盐氧化，作为一种新兴的高级氧化技术，是一种矿化难降解有毒污染物的有效方法。

在众多的活化方法中，过硫酸盐通过接受电子完成的电化学活化，具有容易操控和环境友好的特点，被认为是一种有前景的活化技术。

但在电化学活化的过程中，由于静电斥力阻碍了过硫酸盐阴离子和阴极之间的接触，导致过硫酸盐低的分解率和随后低的自由基的产生量，从而使污染物的降解效果变差。

针对此问题，本文使用天然木材衍生的碳化木（CW）制备了具有多通道的流通式阴极（FTC），通过将过一硫酸盐（PMS）阴离子限制在阴极的微通道中，能够显著地强化其与阴极的碰撞与接触，提高电化学活化的效率并增强对污染物的降解。

主要的研究成果如下：（1）通过天然松木的一步碳化制备并组装了具有丰富的介孔，良好的导电性，较高的机械强度，大量有序的微通道以及对PMS有良好的电催化活性的FTC。

以苯酚为目标污染物，探究了不同的反应条件（PMS浓度、电流密度和停留时间）对FTC电活化PMS降解苯酚性能的影响。

结果表明，在苯酚进水浓度为20 mg/L, 进水TOC=18 mg/L，进水PMS浓度为6.51 mM，背景Na2SO4为0.05 M，电流密度为2.75 mA/cm2，进水pH 2.87，停留时间10 min以及常温的条件下，通过FTC电活化PMS，PMS的分解率达到了71.9%。

苯酚和TOC的去除率分别达到了97.9%和39.6%。

EPR实验结果表明，在FTC电活化PMS的过程中，产生了大量的·OH和SO4•-。

同时，自由基淬灭实验也表明，·OH和SO4•-均参与了对苯酚的降解，且·OH对降解的贡献更大。

此外，五次循环实验的结果证明了本研究组装的FTC具有很好的稳定性。

（2）通过封闭CW的微通道，获得了流过式阴极（FBC）。

在相同的优化条件下，详细对比了在FTC中和FBC上的PMS的分解、自由基的产量以及电活化PMS降解三种酚类有机物（苯酚、双酚A和4-氯苯酚）的性能。

Electrospinning of Polymeric FibersElectrospinning is a process that enables the production of ultrafine fibers by manipulating the electrostatic forces between a charged polymer solution or melt and a grounded collector. This technique has been widely used in various applications, such as tissue engineering, drug delivery, filtration, and textiles.Polymeric fibers produced by electrospinning have unique physical, chemical, and mechanical properties, such as high surface area-to-volume ratio, large porosity, and high mechanical strength, which make them attractive in these applications. The electrospinning process is highly controllable and can produce fibers with diameters spanning from several nanometers to several micrometers.Polymeric materials used in electrospinning can be divided into two main types based on their physical state: solution and melt. Solution electrospinning involves dissolving a polymer in a solvent to form a homogeneous solution, which is then electrospun to produce fibers. Melt electrospinning, on the other hand, involves melting a polymer and electrospinning it directly into fibers.The selection of polymer and solvent/melt system is critical to successful electrospinning. Polymers with high molecular weight and low viscosity are desirable for high-quality fiber production. Solvents/melt system should be chosen based on the solubility or melting point of the polymer and its compatibility with the fabrication process. Common solvent systems include water, organic solvents, and ionic liquids. For melt electrospinning, an appropriate processing temperature and pressure are necessary to achieve proper fiber formation.Electrospinning can also be modified to produce more complex fiber structures, such as core-shell, multi-layered, and patterned fibers. Core-shell fibers consist of a core material surrounded by a shell material, which can provide enhanced functionality or compatibility with certain applications. Multi-layered fibers allow for the production of fibers with different properties in one single structure. Patterned fibers can be used to create intricate shapes, such as helical fibers or fibers with specific surface patterning.Despite its advantages, electrospinning also faces several challenges. The process is sensitive to environmental conditions, such as humidity, temperature, and air pressure, which can affect fiber morphology and quality. The production rate is also relatively low, and scalability is still a challenge. The electrospinning process also requires expensive equipment and a skilled operator.In conclusion, electrospinning is a promising technology for the fabrication of polymeric fibers in various applications. Its advantages in producing ultrafine fibers with unique properties make it an attractive option for researchers and manufacturers alike. With the continued development of this technology, electrospinning is expected to make significant contributions to the fields of materials science, nanotechnology, and biomedical engineering.。

低温等离子体磁控溅射英文When it comes to cutting-edge technologies, low-temperature plasma magnetron sputtering is truly remarkable. It's a process that utilizes the power of magnetic fieldsto precisely control the sputtering of materials in a low-temperature plasma environment. You know, this kind ofstuff is what dreams are made of for materials scientists!Imagine the precision and flexibility this technique offers. Not only does it allow for ultra-thin films to be deposited on surfaces, but it can also achieve high levelsof purity and uniformity. It's kind of like painting withthe finest brushstrokes, but at the atomic level!What really sets it apart is the low-temperature aspect. Unlike traditional sputtering methods, this one doesn't generate a lot of heat, which means it's gentle on the materials and can be used on a wider range of substrates.It's a real game-changer for applications where heat sensitivity is a concern.The magnetic fields involved are like the unseen hand that guides the process. They help concentrate the plasma and direct the sputtering particles where they need to go. It's a bit like magic, but with a solid foundation in physics!And talk about versatility! This technique can be used for everything from creating coatings for optical components to depositing thin films for electronic devices. It's truly a multipurpose tool in the toolbox of modern materials science.So there you have it – a snapshot of low-temperature plasma magnetron sputtering. It's cutting-edge, precise, gentle, magical, and versatile. What's not to love?。

·强激光物理与技术•研究快报·国产纺锤形增益光纤主振荡功率放大器实现5 kW 输出*奚小明， 杨　欢， 曾令筏， 黄良金， 叶　云， 张汉伟， 潘志勇，王小林， 王泽锋， 周　朴， 许晓军， 陈金宝（1. 国防科技大学 前沿交叉学科学院，长沙 410073； 2. 脉冲功率激光技术国家重点实验室，长沙 410073；3. 高能激光技术湖南省重点实验室，长沙 410073）摘 要： 设计了纤芯直径小—大—小变化的“纺锤形”增益光纤，利用该光纤可均衡模式不稳定和受激拉曼散射抑制的矛盾，提升光纤激光器的输出功率。

基于自研的纺锤形增益光纤搭建了主振荡功率放大器（MOPA ），实现了5 kW 的功率输出，放大器光光效率为66.6%，拉曼散射抑制比大于45 dB ，M 2因子约2.0。

通过优化光纤的设计，可以提升激光器的光束质量和效率。

关键词： 光纤激光器； 光纤放大器； 锥形光纤； 受激拉曼散射； 模式不稳定效应 中图分类号： TN242 文献标志码： A doi : 10.11884/HPLPB202133.2003095 kW all-fiber amplifier based on homemade spindle-shaped Yb-doped fiberXi Xiaoming ， Yang Huan ， Zeng Lingfa ， Huang Liangjin ， Ye Yun ， Zhang Hanwei ， Pan Zhiyong ，Wang Xiaolin ， Wang Zefeng ， Zhou Pu ， Xu Xiaojun ， Chen Jinbao（1. College of Advanced Interdisciplinary Studies , National University of Defense Technology , Changsha 410073, China ;2. State Key Laboratory of Pulsed Power Laser Technology , Changsha 410073, China ;3. Hunan Provincial Key Laboratory of High Energy Laser Technology , Changsha 410073, China ）Abstract ： To enhance the thresholds of both stimulated Raman scattering and transverse mode instability, we proposed a novel active Yb-doped fiber with a spindle-shaped core and inner-cladding. An all-fiber main oscillator power amplifier (MOPA) was experimentally established based on this homemade fiber. A maximum power of 5 kW was achieved with the optical-to-optical efficiency of 66.6%, Raman-suppression ratio of ＞45 dB and M 2 factor of about 2.0. We believe that the brightness and the efficiency of the laser can be improved by optimizing the structure of the Yb-doped fiber.Key words ： fiber laser ； fiber amplifier ； tapered fiber ； stimulated Raman effect ； transverse mode instability高功率光纤激光器具有转换效率高、散热性好、稳定性好等优点，在工业加工、材料处理和生物医疗等领域受到青睐[1-2]。

Electrospinning of Polymer Fibers andNanofibersElectrospinning is a technique used to manufacture polymer fibers and nanofibers. It is based on the use of an electric field to stretch and elongate a polymer solution or melt and then collect the obtained fibers on a substrate. This technique has been increasingly used in the past decades due to its versatility, simplicity, and cost-effectiveness in the production of fibers and nanofibers with unique properties and applications.Mechanism of ElectrospinningThe electrospinning process relies on the Coulomb forces that arise from the interaction between an electric field and a charged polymer solution or melt. When a high electric field is applied to a polymer solution or melt, the charged molecules and ions in the solution or melt generate an electrostatic force that overcomes the surface tension of the solution, promoting the formation of a charged Taylor cone at the tip of a spinneret. When the electrostatic force is greater than the surface tension, the solution or melt streams out from the cone, forming a thin jet that elongates and thins under the action of the electric field. The jet eventually solidifies into fibers or nanofibers upon reaching a grounded or electronegative collector.Features of Electrospun Fibers and NanofibersElectrospun fibers and nanofibers offer unique features that make them appealing for various applications. Some of these features include:1. High surface area-to-volume ratio: Electrospun fibers and nanofibers have a very high surface area-to-volume ratio due to their small diameter and large surface area, which provides better interactions between the fibers/nanofibers and their surroundings, such as cells, drugs, and catalysts.2. High porosity: Electrospun fibers and nanofibers possess a high porosity, which can be controlled by adjusting the parameters of the electrospinning process, such as theconcentration of the polymer solution, the electric field strength, and the collector distance. This porosity facilitates gas and fluid exchange, as well as cell adhesion and proliferation.3. Tunable mechanical properties: Electrospun fibers and nanofibers possess tunable mechanical properties, which depend on the type of polymer used, the concentration of the polymer solution, and the processing parameters. For example, some polymers can form stiff nanofibers, while others can form flexible fibers, or even hydrogels.Applications of Electrospun Fibers and NanofibersElectrospun fibers and nanofibers have been used in a wide range of applications, including:1. Tissue engineering: Electrospun fibers and nanofibers have been used as scaffolds for tissue engineering due to their high surface area-to-volume ratio, high porosity, and tunable mechanical properties. By mimicking the natural extracellular matrix, electrospun fibers and nanofibers can promote cell adhesion, proliferation, and differentiation in various tissues, such as bone, cartilage, skin, and nerve.2. Drug delivery: Electrospun fibers and nanofibers have been used as drug delivery vehicles due to their high surface area-to-volume ratio, high porosity, and tunable mechanical properties. By encapsulating drugs within the fibers/nanofibers, controlled and sustained drug release can be achieved, improving the efficacy and safety of drug delivery.3. Sensors and catalysts: Electrospun fibers and nanofibers have been used as sensors and catalysts due to their high surface area-to-volume ratio and tailored properties. By incorporating functional materials such as metals or enzymes into the fibers/nanofibers, they can act as efficient sensors or catalysts in various applications, such as environmental monitoring, energy harvesting, and biocatalysis.ConclusionElectrospinning is a promising technique for the manufacturing of polymer fibers and nanofibers with unique properties and applications. By adjusting the parameters of the process, such as the concentration of the polymer solution or melt, the electric field strength, and the collector distance, electrospun fibers and nanofibers can possess a wide range of features, such as high surface area-to-volume ratio, high porosity, and tunable mechanical properties. Their unique features make them appealing for various applications, such as tissue engineering, drug delivery, sensors, and catalysts. With the advancement in materials science and engineering, we can expect more applications of electrospun fibers and nanofibers in the future.。

Understanding the dynamics ofelectrospinningElectrospinning is a versatile technique for fabricating nanofibers from a wide range of materials, including polymers, ceramics, and metals. It involves applying a high voltage to a polymer solution to create an electrostatic force that draws the solution towards a grounded collector. The solution elongates and eventually solidifies into a fiber as it travels through the air. Electrospun nanofibers have a high surface area-to-volume ratio and can be used in a broad range of applications, including tissue engineering, drug delivery, and filtration.The electrospinning process depends on several factors, including the properties of the polymer solution, the electric field strength and geometry, and the ambient conditions. In this article, we will explore some of these factors in more detail.Polymer PropertiesThe properties of the polymer solution have a significant impact on the electrospinning process. Viscosity, surface tension, and conductivity all play essential roles in determining the final fiber morphology. High viscosity solutions result in thicker fibers, while low viscosity solutions produce finer fibers. Similarly, high surface tension solutions tend to produce more uniform fibers, while low surface tension solutions can lead to beading or droplet formation.Conductivity is another critical factor in the electrospinning process. The solution must be conductive enough to carry an electric charge but not so conductive that it becomes unstable during the process. Generally, a conductivity range between 10-8 and 10-4 S/cm is suitable for electrospinning.Electric Field Strength and GeometryThe electric field strength and geometry also have a significant impact on the electrospinning process. The electric field strength determines the intensity of theelectrostatic force, which influences the fiber diameter. A higher electric field strength leads to finer fibers, while lower electric field strengths result in thicker fibers.The electric field geometry can also affect the fiber morphology. A traditional electrospinning setup involves a needle as the source of the polymer solution and a grounded flat collector. However, other geometries, such as coaxial and parallel plate, can produce different fiber morphologies. Coaxial electrospinning involves two concentric needles; one for the polymer solution and one for the core material, while parallel plate electrospinning uses a flat emitting electrode and a parallel grounded electrode.Ambient ConditionsThe ambient conditions, such as humidity, temperature, and airflows, can also affect the electrospinning process. Humidity levels can impact the fiber morphology because they affect the evaporation rate of the solvent. Higher humidity levels lead to slower evaporation rates and thicker fibers.Temperature can also influence fiber diameter because it affects the viscosity of the solution. Higher temperatures result in lower viscosities and finer fibers, while cooler temperatures lead to thicker fibers.Airflows can also affect the stretching of the jet and the resulting fiber morphology. High airflow rates can lead to microdroplets or beading, while low airflow rates can lead to thicker fibers.ConclusionIn summary, electrospinning is a versatile technique for producing nanofibers with a broad range of applications. The process is influenced by several factors, including the properties of the polymer solution, the electric field strength and geometry, and the ambient conditions. Understanding the dynamics of electrospinning can help researchers optimize the process for specific applications and improve the quality of the resulting nanofibers.。

纳米陶瓷磁控溅射膜英文回答：Nanoceramic magnetron sputtering films have gained significant attention in recent years due to their unique properties and wide range of applications. As a researcher in this field, I have had the opportunity to explore the fascinating world of nanoceramic films and their potential in various industries.One of the key advantages of nanoceramic magnetron sputtering films is their exceptional hardness and wear resistance. These films are composed of nanoscale ceramic particles that are deposited onto a substrate using a magnetron sputtering technique. The resulting film exhibits superior mechanical properties, making it ideal for applications where durability is crucial. For example, in the automotive industry, these films can be used to enhance the hardness and scratch resistance of car body coatings, ensuring that the paint remains intact even under harshconditions. This not only improves the overall appearance of the vehicle but also extends its lifespan.Furthermore, nanoceramic magnetron sputtering films offer excellent corrosion resistance. The nanoscale ceramic particles form a dense and uniform film that acts as a barrier against corrosive agents. This makes these films highly suitable for applications in the aerospace industry, where components are exposed to extreme environments. For instance, these films can be applied to aircraft parts to protect them from corrosion caused by exposure to high altitude, humidity, and saltwater. This ensures the longevity and reliability of the aircraft, reducing maintenance costs and improving safety.Another remarkable characteristic of nanoceramic magnetron sputtering films is their exceptional optical properties. These films can be tailored to exhibit specific optical properties, such as high transparency or selective light absorption. This makes them valuable in various fields, including optics and electronics. For example, these films can be used as anti-reflective coatings oncamera lenses, allowing more light to pass through and improving image quality. They can also be used in solarcells to enhance light absorption, increasing theefficiency of energy conversion.中文回答：纳米陶瓷磁控溅射膜近年来因其独特的性能和广泛的应用而受到了广泛关注。

The Science of Electrospinning andNanofibers电纺和纳米纤维的科学纳米科技是21世纪最激动人心的领域之一，其涉及广泛的应用，从医学到能源，再到材料科学。

而在这一领域中，电纺和纳米纤维的发现和发展受到了很多人的关注。

这项技术可以制造出附有纳米级结构的纤维，这对于制备电子器件和生物组织相似的人工组织等多种应用具有重要意义。

本文将介绍电纺技术和纳米纤维的制备方法以及其在各个领域中的应用。

电纺技术是指将溶液通过高压电场引起分离，并沉积在基板上形成纳米级纤维结构的工艺过程。

这项技术首次被报道是在1934年，但是直到20世纪90年代，在纳米材料研究领域中，它才被广泛关注。

该技术不仅可以制备出具有纳米级尺寸的纤维，同时也可以制备出具有不同形状和结构的纤维，这使得电纺成为了研究和应用领域中备受欢迎的方法之一。

电纺技术不仅可以制备出具有结构化表面的材料，还可以制备出多种配方的聚合物或蛋白质纤维，这使得这项技术在医学和材料科学等领域中具有极大的潜力。

制备纳米纤维的方法通常包括两种：一种是半工业化方法，它是用塑料材料的高温熔体弄熔后冷却成纤维，这种方法需要采用高科技设备和高超技能的操作工人才能掌控纳米级的复杂制备过程。

而另一种则是基于电纺法的制备方法，它不需要用高温去熔纳米级别的物质，只需要将溶液经过电场引发静电力的效应，溶液因此产生了表面张力，将纤维液拉成细长的线，再通过旋转圆盘和一些其他参数，使纳米纤维沉积在基板上。

该方法成本低廉、简单易用，适用于大规模量产，其制备出来的纳米纤维具有高纯度和高细度的特点，在医学领域中特别受到欢迎。

对于电纺技术和纳米纤维的应用，参照文献表明其有很多的应用方向，比如用于生物医学和生命科学、体现出色的电气性能的电子器件、纳米电催化剂和材料科学等等。

例如，应用在生物医学领域上，制备纳米纤维结构可以为伤口提供医学用品，如高效的包扎纱布，这种纱布可以防止细菌感染，并为细胞提供适当的温度、湿度和营养。

用PFN/Al双分子阴极层很大的增加效率在低的能带隙Polycarbazole给体高效率体异质结太阳能电池聚合物太阳能电池(PVCs)已经吸引很大的关注在过去的几年内，由于它独特的优势：成本低，重量轻，和实现柔性和大面积器件。

典型的，体异质结(BHJ) PVCs,一种有希望高的能量转换效率的器件(PCE),包括使用相分离混合的电子给体共轭有机物和电子受体富勒烯衍生物作为活性层。

明智的设计聚合物给体和选择富勒烯受体已经实现有PCE高效率BHJ PVCs超过5%。

极大的效果已经使活性层的形成和器件的配置完善。

许多优选的方法，就像用不同的溶剂制造活性层，对活性层或器件退火，薄膜形成速度，在活性层增加附加剂，用光学的空间，级联结构，一个反转组态，阴极界面层，等，已经证明在BHJ PVCs的光电性能上有效的增加。

这有一些在BHJ PVCs阴极界面层的例子。

在聚合物(2-methoxy-5-(3’ ,7’-dimethyl-octyloxy))- p-phenylene vinylene:(6,6)-phenyl-C 61 -butric acid methyl ester (MDMO-PPV:PCBM)活性层和Al阴极之间插入绝缘的LiF作为早期测试，这使PCE得增加超过20%，归因于开路电压( V oc )和填充因子的增加。

carboxylic acids作为自组装的单层在ZnO的面上的应用能修饰ZnO/金属双分子阴极层界面的特性，在这里聚乙烯(3-hexylthiophene) (P3HT)基于PVCs的光电表现和金属接触有很大的不同。

一些报道同样描述用溶于乙醇或是水的聚合物作为阴极层。

是聚合物在乙醇或是水的溶解性避免活性层和随后放置层的混合，证实所有解决方案的器件。

用聚乙烯(ethylene oxide) (PEO)作为阴极界面层对于有polyfluorene聚合物作为给体的PVCs 提高PCE从1.2% 到1.8%,主要由于V oc的增大。

超高分子量聚乙烯（UHMWPE ）纤维与芳纶、碳纤维称为世界三大高科技纤维，其产品广泛应用于防弹、防刺等轻质高强类国防军需装备，以及航空航天、海洋产业、运动器材、建筑加固等领域。

1UHMWPE 纤维1．1性能概述UHMWPE 纤维质量轻，在几种高性能纤维中密度较小，是唯一能够漂浮在水面上的高科技纤维。

UHMWPE 纤维的优越性能是由于其具有亚甲基相连（—CH 2—CH 2—）的超分子链结构，没有侧基，结构对称、规整，单键内旋转位垒低，柔性好。

相关研究表明，在－150℃的环境，该纤维仍保持良好的耐挠曲性，无脆化点［1］。

由于UHMWPE 纤维规整的大分子链结构，使纤维沿轴向取向度高、结晶度高，因此具有优良的力学性能。

UHMWPE 纤维模量较高，具有突出的抗冲击性和抗切割性能，抗拉强度是相同线密度钢丝的15倍，比芳纶高40％，是普通纤维和优质钢纤维的10倍，仅次于特级碳纤维。

由于UHMWPE 纤维的分子结构—CH 2—CH 2—不含有易与接触物质发生反应的羟基、芳香环等基团，因此具有化学和光学惰性。

研究表明，强酸、强碱及有机溶剂均对UHMWPE 纤维强度没有影响，其化学稳定性较好；在经1500h 日晒后，纤维强度仍高达80％，耐候性、耐紫外性能均较优越［2－9］，该纤维还具有良好的耐磨性与生物共存性。

由于UHMWPE 纤超高分子量聚乙烯纤维性能及生产现状作者简介：李建利（1982—），女，工程师，硕士。

主要从事高性能纤维及产业用纺织品的开发。

李建利，张新元，贾哲昆，赵领航，王建新摘要：介绍超高分子量聚乙烯纤维的产品性能，并与芳纶、碳纤维进行性能对比。

结合国内外研究现状，详细阐述超高分子量聚乙烯纤维的生产工艺，主要包括熔融纺丝、干法凝胶纺丝和湿法凝胶纺丝工艺。

并分析国内外产能状况，包括荷兰帝斯曼、美国霍尼韦尔、日本东洋纺和国内部分公司，通过对比分析国内外企业特点，指出国内超高分子量聚乙烯纤维发展迅猛，但存在质量参差不齐、产能较低、应用开发水平低等问题，提出应加大工艺技术的开发与研究，并对市场前景进行展望。