Application of different fiber structures and arrangements by electrospinning in triboelectric nanogenerators

In recent years,nanogenerators(NGs)have attracted wide attention in the energy field,among which triboelectric nanogenerators(TENGs)have shown superior performance.Multiple reports of electrospinning(ES)-based TENGs have been reported,but there is a lack of deep analysis of the designing method from microstructure,limiting the creative of new ES-based TENGs.Most TENGs use polymer materials to achieve corresponding design,which requires structural design of polymer materials.The existing polymer molding design methods include macroscopic molding methods,such as injection,compression,extrusion,calendering,etc.,combined with liquid-solid changes such as soluting and melting;it also includes micro-nano molding technology,such as melt-blown method,coagulation bath method,ES method,and nanoimprint method.In fact,ES technology has good controllability of thickness dimension and rich means of nanoscale structure regulation.At present,these characteristics have not been reviewed.Therefore,in this paper,we combine recent reports with some microstructure regulation functions of ES to establish a more general TENGs design method.Based on the rich microstructure research results in the field of ES,much more new types of TENGs can be designed in the future.

Comparative structural and electrochemical properties of mixed P2/O′3-layered sodium nickel manganese oxide prepared by sol-gel and electrospinning methods:Effect of Na-excess content

The effect of Na-excess content in the precursor on the structural and electrochemical performances of sodium nickel manganese oxide(NNMO)prepared by sol-gel and electrospinning methods is investigated in this paper.X-ray diffraction results of the prepared NNMO without adding Na-excess content indicate sodium loss,while the mixed phase of P2/O′3-type layered NNMO presented after adding Na-excess content.Compared with the sol-gel method,the secondary phase of NiO is more suppressed by using the electrospinning method,which is further confirmed by field emission scanning electron microscope images.N_(2) adsorption-desorption isotherms show no remarkably difference in specific surface areas between different preparation methods and Na-excess contents.The analysis of X-ray absorption near edge structure indicates that the oxidation states of Ni and Mn are+2 and+4,respectively.For the electrochemical properties,superior electrochemical performance is observed in the NNMO electrode with a low Na-excess content of 5wt%.The highest specific capacitance is 36.07 F·g^(-1)at0.1 A·g^(-1)in the NNMO electrode prepared by using the sol-gel method.By contrast,the NNMO electrode prepared using the electrospinning method with decreased Na-excess content shows excellent cycling stability of 100%after charge-discharge measurements for 300 cycles.Therefore,controlling the Na excess in the precursor together with the preparation method is important for improving the electrochemical performance of Na-based electrode materials in supercapacitors.

A Rapid-Ab/Desorption and Portable Photothermal MIL- 101(Cr) Nanofibrous Composite Membrane Fabricated by Spray-Electrospinning for Atmosphere Water Harvesting

MIL-101(Cr)is a promising moisture absorbent for solar-driven water harvesting from moisture to tackle the worldwide water shortage issue.However,the MIL-101(Cr)powder suffers from a long ab/desorption cycle due to the crystal aggregation caused by its inherent powder properties.Here,we demonstrate a MIL-101(Cr)nanofibrous composite membrane with a nanofibrous matrix where MIL-101(Cr)is monodisperse in the 3D porous nanofibrous matrix through a simple spray-electrospinning strategy.The continuous porous nanofibrous matrix not only offers sufficient sites for MIL-101(Cr)loading but also provides rapid moisture transport channels,resulting in a super-rapid ab/desorption duration of 50 min(including an absorption process for 40 min and a desorption process for 10 min)and multicycle daily water production of 15.9 L kg^(−1) d^(−1).Besides,the MIL-101(Cr)nanofibrous composite membrane establishes a high solar absorption of 92.8%,and excellent photothermal conversion with the surface temperature of 70.7°C under one-sun irradiation.In addition,the MIL-101(Cr)nanofibrous composite membrane shows excellent potential for practical application due to its flexibility,portability,and use stability.This work provides a new perspective of shortening MOF ab/desorption duration by introducing a porous nanofibrous matrix to improve the specific water production for the solar-driven ab/desorption water harvesting technique.

Fabrication of High-Efficiency Polyvinyl Alcohol Nanofiber Membranes for Air Filtration Based on Principle of Stable Electrospinning

A mass flow matching model(MFMM)was established for studying the stable status of solution electrospinning.The study of the solution droplet status at the needle tip focused on various combinations of applied voltages and injection rates to figure out their influence on steadily fabricating polyvinyl alcohol(PVA)nanofibers prepared from PVA spinning solutions with two different mass fractions(10%and 16%).The results revealed that during the stable electrospinning,the influence resulted from the change of the injection rate approximately canceled out the impact brought by adjusting the applied voltage,leading to almost the same morphology as that of the PVA nanofibers.And the mass fraction of PVA in the spinning solution dominated the structure and the diameter distribution of the electrospun nanofibers.Under stable electrospinning conditions,the composite membrane was produced by depositing PVA nanofibers on the polyethylene terephthalate(PET)nonwoven substrate for an air filtration test.Furthermore,the prepared composite membrane exhibited a high air filtration efficiency(99.97%)and a low pressure drop(120 Pa)for 300-500 nm neutralized polystyrene latex(PSL)aerosol particles,demonstrating its potential as an alternative for a variety of commercial applications in air filtration.

An energetic nano-fiber composite based on polystyrene and 1,3,5-trinitro-1,3,5-triazinane fabricated via electrospinning technique

Electrospinning is a simple technique used to fabricate polymeric nano-fibrous membranes.These nano-fibers have found a wide range of valuable applications in the biomedical field.However,it has not been utilized with solid high explosives yet.Herein,the electrospinning technique has been used to fabricate polystyrene(PS)/1,3,5-trinitro-1,3,5-triazinane(RDX)composite nanofibers.The governed electrospinning parameters,voltage,distance from the collector,flow rate,mandrel rotating speed,time,and solution concentration,that greatly affect the morphology of the obtained nanofibers were optimized.The fabricated PS/RDX nano-fibers were characterized using scanning electron microscopy(SEM),X-ray diffractometer(XRD),and Fourier Transform Infrared(FTIR)spectroscopy.The impact and friction sensitivities of PS/RDX were also measured.The thermal behavior of the prepared composite and the pure materials were studied by the thermal gravimetric analysis technique(TGA).SEM results proved the fabrication of PS/RDX fibers in the nano-size via electrospinning.FTIR spectroscopy confirmed the existence of the characteristic functional groups of both PS and RDX in the composite nano-fibers.XRD sharp peaks showed the conversion of amorphous PS into crystalline shape via electrospinning and also confirmed the formation of PS/RDX composite.The PS fibers absorbed the heat and increased the onset decomposition of the pure RDX from 181.5 to 200.7℃in the case of PS/RDX fibers.Interestingly,PS/RDX nano-fibers showed the relatively low impact and friction sensitivities of 100 J and 360 N respectively.These results could introduce PS/RDX nanofibrous composite in the field of explosives detection with high levels of safety.

空气过滤用聚氨酯纳米纤维膜的制备及其性能

为拓展静电纺纳米纤维在空气过滤领域中的应用,以聚氨酯(PU)为原料,加入不同种类的盐,采用静电纺丝法制备树枝状PU纳米纤维膜。利用扫描电镜(SEM)、接触角测试仪、红外光谱仪、自动滤料测试仪测试纳米纤维膜的微观结构、亲疏水性、化学结构和过滤性能。结果表明:在PU质量分数14%条件下,添加有机盐TBAC,纺丝电压35 kV时,制备的纳米纤维膜的树枝状分叉结构明显;TBAC的加入使纤维膜的接触角由99.1°减小到82.8°;分叉结构使纳米纤维膜的过滤性能显著提高,与纯PU纳米纤维膜相比,过滤效率从50.8%提高到93.6%,品质因子从0.009提高到0.073,可满足高效低阻空气过滤材料的需求。

聚己内酯/MgO复合纳米纤维膜的制备及其性能

为制备集多种功能于一体的纳米纤维膜,将MgO纳米颗粒加入至可降解聚己内酯(PCL)溶液中,通过静电纺丝技术制备PCL/MgO复合纳米纤维膜,研究了其微观形态、结晶结构、过滤性能和抗菌性能等。结果表明:PCL/MgO复合纳米纤维的直径比纯PCL略有增加,且纤维膜中MgO依然保持着结晶状态;与纯PCL纤维膜相比,PCL/MgO复合纳米纤维膜的透气率增加,水接触角增大,透湿率减小;PCL/MgO复合纳米纤维膜的过滤效率为97.57%~98.87%,紫外线防护系数均大于50,具有良好的过滤性能和优异的紫外线防护性能,其对大肠杆菌的抑菌率为73.78%~98.55%,对金黄色葡萄球菌的抑菌率为53.61%~97.56%;对大肠杆菌的抑菌率优于金黄色葡萄球菌是因为MgO纳米颗粒具有晶格缺陷,更易与带有负电荷的大肠杆菌形成较强的相互作用。

一维多孔二氧化钛@碳纳米纤维复合材料的制备及储钠应用

通过静电纺丝法和浓碱水热刻蚀法原位制备出具有片状分枝结构的一维多孔二氧化钛@碳纳米纤维(P-TiO_(2)@CNFs)复合材料,并将其作为钠离子电池的负极材料。P-TiO_(2)@CNFs的片状分枝结构能够有效缩短离子扩散路径并增加电解液与活性物质的接触面积;多孔结构提供了更多的反应活性位点,从而加快了电荷转移动力学;二氧化钛与碳纳米纤维之间的化学键能够增加复合材料的结构稳定性。实验对P-TiO_(2)@CNFs的表面形貌、微观结构、晶体结构、比表面积、孔径、元素价态等进行了分析,并在新威尔电池测试系统上进行恒电流充放电测量和倍率性能测试,实验结果表明P-TiO_(2)@CNFs表现出优异的循环性能和倍率性能,在2.0A/g的电流密度下循环2000次仍能保持197mAh/g的比容量,在超大电流密度30.0A/g下电极仍然能够保持61.7mAh/g的比容量。

PDMS/PVDF静电纺丝膜的制备及油水分离性能研究

利用静电纺丝技术制备具有特殊浸润性表面用于油水分离研究。对比聚偏氟乙烯(PVDF)与聚二甲基硅氧烷(PDMS)不同配比下静电纺丝的成膜效果,并进行性能表征。研究表明,适量的PVDF可以对PDMS起到助纺与增塑的效果,且微球的存在使膜层表现出更好的疏水性。此外,膜层具有的对水高黏附性是受到毛细吸附与静电作用双重影响。当PVDF与PDMS的配比为2∶1时,膜层显示出对油包水乳液良好的选择透过性,水接触角可达150°,油接触角几乎为0°,油水分离率在98%以上,是油水分离材料良好的候选物。

聚乳酸-酪蛋白基复合膜性质及其在草莓保鲜中的应用

以聚乳酸(poly lactic acid,PLA)、酪蛋白(casein,CN)为基质,利用静电纺丝技术制备了负载黄芩苷的复合膜,研究了CN和PLA不同配比下复合膜的微观结构、亲水性、降解性、溶胀性等,评价了复合膜包装对草莓果实硬度、可溶性固形物含量、失水率等指标的影响。结果显示,在PLA中添加CN后,复合膜纤维直径减小,成纤性能下降;当CN与PLA质量比为1∶1时,纤维直径均匀,成纤能力较好,为最佳配比。最佳条件下,复合膜的水接触角为(122.90±4.08)°,显著低于PLA膜;降解率为(45.31±3.35)%,显著高于PLA膜;吸水溶胀率约为150%,而PLA膜仅为(8.82±0.62)%。草莓保鲜试验表明,经复合膜包装后,草莓果实的硬度、可溶性固形物含量显著高于对照组。研究结果可为PLA、CN在果蔬保鲜材料制备中的应用提供参考依据。

一种基于高压静电纺丝工艺制备的P(VDF-TrFE)/PZT压电传感器及其在睡眠监测中的应用

针对日常睡眠监测的需求,提出一种基于高压静电纺丝工艺制备的P(VDF-TrFE)/锆钛酸铅(PZT)压电传感器并对其性能进行了研究。首先,介绍了P(VDF-TrFE)/PZT压电传感器的制作及封装流程。其次对其灵敏度,频率响应特性,瞬时响应和稳定性等进行了测试。结果表明,该传感器不仅具有良好的微观外貌形态,且相比于纯P(VDF-TrFE)压电传感器0.73 V/N的灵敏度,制备的含30%PZT的P(VDF-TrFE)/PZT压电传感器灵敏度是纯P(VDF-TrFE)压电传感器的2.5倍,达到了1.78 V/N。此外在低频下能够保持稳定压电输出且具备2 ms较快的响应时间。最后采用自制的P(VDF-TrFE)/PZT压电传感器测量人体心冲击信号,并通过支持向量机(SVM)训练睡眠分期模型实现了对睡眠质量的监测,四分类模型平均准确率达到72.5%,为可穿戴睡眠监测传感器的选择提供了参考。

羟基化氮化硼改性PLA纳米纤维膜的制备及性能研究

为拓展生物基可降解PLA纳米纤维膜在空气过滤等医疗卫生领域的应用范围,通过机械剥离与功能化改性方法制备羟基化氮化硼(BNO)二维纳米片,并采用静电纺丝工艺制备羟基化氮化硼纳米片改性聚乳酸(PLA/BNO)纳米纤维膜。探讨BNO纳米片的引入对PLA纳米纤维膜的微观结构与形貌、导热性能、力学性能以及空气过滤性能的影响。结果表明:与纯PLA纳米纤维膜相比,PLA/BNO纳米纤维膜的拉伸力学性能以及导热性能显著提高。当纺丝液中BNO纳米片质量分数为0.7%时,风速为0.01 m/s时,PLA/BNO纳米纤维膜的过滤效率为99.97%,品质因子达到最大值0.262 Pa^(-1),阻力压降最小为31 Pa,PLA/BNO纳米纤维膜的拉伸断裂强度以及导热系数较纯PLA纳米纤维膜分别提高27.39%和26.62%。

纺丝液配制对PI/TiO_(2)活性碳纳米纤维膜吸附性能的影响

以均苯四甲酸酐(PMDA)、4,4′-二氨基二苯醚(ODA)及纳米TiO_(2)为原料,采用静电纺丝及热酰亚胺化的方法制备聚酰亚胺/二氧化钛(PI/TiO_(2))复合纳米纤维膜,在高温下对PI/TiO_(2)复合纳米纤维膜进行活化处理,通过正交试验研究了PMDA与ODA摩尔比、纳米TiO_(2)含量及纺丝液含量对PI/TiO_(2)活性碳纳米纤维膜吸附性能的影响。结果表明:PMDA与ODA摩尔比为1.03∶1、TiO_(2)质量分数为3%、纺丝液质量分数为22%时,活性碳纳米纤维薄膜的吸附性能最佳。

用于压电传感器的层加层结构纳米纤维膜

通过聚丙烯腈(PAN)与改性木质素(CEHL-PTMG)接枝物进行共混,使用多层静电纺丝技术得到PAN|PAN/CEHL-PTMG|PAN层加层结构的纳米纤维膜,并制备一系列的薄膜。对制备的层加层结构纳米纤维膜进行表面形貌、构象、热性能、力学性能以及压电性能测试。实验结果表明:层加层结构使得薄膜的压电性能得到了大幅提高,PAN(11%,1 mL)|PAN/CEHL-PTMG(11%/2%,2 mL)|PAN(11%,1 mL)层加层结构纳米纤维膜的压电性能最为优异,输出电压和电流分别可达2.57 V、1468.0 nA;层加层结构薄膜的拉伸强度提高到了7.16 MPa,相较复合纳米纤维膜拉伸强度提高了7.51%,比纯PAN薄膜拉伸强度提高了52.67%;结构化后的薄膜的稳定性大幅提高,经过上千次的撞击仍能输出较好的电压;同时将其附于手指及手肘上,能更加明确地指示两者的运动,且在数值上出现较大的差距。

含铁纳米纤维电极去除水中孔雀石绿

作为一种典型的三苯甲烷类染料,孔雀石绿具有降解难度大、对生态环境和人类危害大等特点,因此水中孔雀石绿的治理问题不容忽视。本工作借助静电纺丝技术和液相还原法,将纳米铁颗粒物负载于高度蓬松的PVA纳米纤维,制备高性能的含铁纳米纤维,并利用其作为第三维电极构建三维电极反应体系,考察三维电极体系中孔雀石绿的去除行为。结果表明,未接通电源时含铁纳米纤维对水中孔雀石绿具有良好的吸附效果,吸附行为符合准二级动力学模型;在三维电极体系中,含铁纳米纤维先借助吸附作用对水中孔雀石绿进行富集浓缩,然后通过电解作用同时实现孔雀石绿的降解和含铁纳米纤维活性位点的再生。在预吸附-电解40 min后,水中孔雀石绿的去除率超过了95%,且反应体系呈现出较强的pH值耐受性。

树枝状聚合物对聚乳酸熔体微分电纺纤维膜的增韧改性研究

采用树枝状聚合物CYD-T151为增塑剂,通过熔融共混方式对聚乳酸(PLA)进行改性,探究了CYD-T151含量、纺丝温度和纺丝电压对熔体微分电纺PLA及PLA/CYD-T151纤维平均直径、直径分布和纤维膜拉伸力学性能的影响。结果表明,树枝状聚合物CYD-T151的加入可有效提高PLA的熔体流动性,降低纤维细度,当CYD-T151含量(质量分数,下同)为1.25%、纺丝温度为240℃、纺丝电压为55 kV时,熔体电纺纤维的纤维平均直径为1.360μm,较纯PLA减小了49.72%;树枝状聚合物CYD-T151作为增塑剂,可有效提高PLA熔体电纺纤维膜的韧性,当CYD-T151含量为1.25%,纺丝温度为240℃,纺丝电压为55 kV时,PLA/CYD-T151纤维膜的抗拉强度和断裂伸长率分别为11.50 MPa和92.33%,较纯PLA提高了4.07%和13.99%。

同轴激光辅助电纺射流检测

针对静电纺丝射流直径小、速度快,不易检测的难题,提出一种带同轴激光辅助的静电纺丝射流检测方法。基于光波导传输原理,激光经由光纤传导到同轴针内针出口处与纺丝射流耦合,有效增强了射流与背景的对比度。结合图像处理技术,对比分析有激光辅助和无激光辅助的静电纺丝射流图像的演变规律,并在此基础上探索辅助激光的最佳功率。实验结果表明,同轴激光辅助有助于增强射流的可检测性,最适于射流检测的激光功率为4 mW;在射流稳定阶段,有光辅助下射流平均可视化长度为10.79 mm,无光辅助射流平均可视化长度为5.68 mm,有光辅助下射流可视化长度平均提升了89.81%;对于细小射流,有光辅助下射流平均可视化长度为5.36 mm,无光辅助射流平均可视化长度为3.33 mm,有光辅助下射流可视化长度平均提升了60.74%。因此,引入同轴激光能有效提高静电纺丝射流的可检测性,为微纳喷印的实时检测提供了一种新思路。

具有光致变色功能的PA6纳微米纤维的制备与性能

为制备具有光致变色功能的纳微米纤维,以萘并吡喃(NA)为变色单元,以甲基丙烯酸甲酯(MMA)为聚合物基质单体,以二氧化硅(SiO_(2))为包覆层,制备了光致变色纳微米微球PMMA/NA@SiO_(2),然后将PMMA/NA@SiO_(2)纳微米微球引入到尼龙6的静电纺丝溶液中,通过对静电纺丝过程中的各工艺参数的优化,对PA6的基本形貌进行了在线调控,成功制备了直径分布较均匀的PA6纳微米变色纤维。场发射扫描电镜和紫外可见光分光光度计的测试结果表明:PMMA/NA@SiO_(2)的直径范围在100~210 nm之间;在PMMA/NA@SiO_(2)质量分数小于10%时,纤维样品的形貌无明显变化,变色性能随添加的变色材料的增加而增强,所制备的样品变色性能和纤维形貌最好,在紫外光照射后会呈现出较好的变色性能和耐疲劳性;通过紫外灯照射发现,相对于λ=365 nm的紫外光,λ=254 nm的紫外光对该光致变色纳微米纤维的变色性能影响较大。

花瓣状多尖端静电纺丝喷头的电场模拟及优化

针对目前多针头静电纺丝易堵塞、针头之间存在边缘效应和无针头静电纺丝供液易挥发、泰勒锥位置不可控等问题,提出一种花瓣状多尖端喷头静电纺丝方法。喷头为半封闭式结构,上半部分为圆柱直管多流道结构,下半部分为花瓣状流道扩张结构,每层的花瓣之间的间距为4 mm,能够在花瓣尖端高电场诱导作用下激发多股射流;利用COMSOL有限元分析软件对下半部分花瓣状流道扩张结构的各个参数电场强度进行模拟,研究喷头下端花瓣数量、花瓣长度和花瓣排布方式对电场均匀性的影响。结果表明:当静电纺丝喷头花瓣数量为4对(8个)、花瓣内层长度为21 mm、外层长度为20 mm、接收距离为200 mm、电压为30 kV时,电场强度平均值为5.441×10^(6) V/m,变异系数(CV)值为5.58%,表明该静电纺丝喷头可激发较高的电场强度且分布均匀;最后采用静电纺丝设备进行纺丝实验,验证了该新型花瓣状多尖端静电纺丝喷头在静电纺丝过程中能够降低边缘效应,减小能耗,射流多且稳定可控,可进行规模化静电纺丝。

石墨烯-PAN基复合纳米纤维的微观形貌及其抗菌性能

为了优化GO-PAN基复合纳米纤维的制备方法,探究石墨烯的质量分数对复合纳米纤维抗菌性能的影响效果,利用静电纺丝法制备了不同石墨烯质量分数的GO-PAN基复合纳米纤维,使用X射线衍射仪、扫描电子显微镜、傅里叶红外光谱、差示扫描量热仪、力学性能分析等对复合纳米纤维的宏观性能和微观结构进行表征。研究结果表明:石墨烯的添加降低了复合纳米纤维的结晶度,GO-PAN基复合纳米纤维微观上呈三维网状结构,纳米纤维无序交错排列,纤维直径为170~230 nm。随着石墨烯质量分数的增加,复合纳米纤维的拉伸强度先增大后降低,断裂延伸率持续降低,且当石墨烯质量分数增大至0.9%时,复合纤维的拉伸强度达到了最大值20.61 MPa;石墨烯的添加改善了复合纳米纤维热学性能,脱水温度提高。GO-PAN基复合纳米纤维对大肠杆菌和金黄色葡萄球菌的抑菌率均超过了95%,且石墨烯质量分数0.9%的复合纳米纤维膜对2种菌种的抑菌效率均达到最大值,抑菌率分别为97.32%、99.85%,其中复合纳米纤维膜对金黄色葡萄球菌的抑菌效率高于大肠杆菌。