采用静电纺丝/非溶剂致相分离制备聚丙烯腈多孔超细纤维的研究

以聚丙烯腈/二甲基亚砜/N,N'-二甲基甲酰胺三元体系为纺丝液、3℃水浴为接收介质,通过静电纺丝制备了具有纳米孔结构的静电纺聚丙烯腈多孔超细纤维.探讨了溶剂比例、接收介质、聚丙烯腈浓度、纺丝电压及接收距离等因素对纤维直径和表面孔隙率的影响.结果表明最佳制备条件为混合溶剂质量比1∶1、纺丝电压16 kV、聚丙烯腈浓度15 wt%、接收距离5 cm、纺丝速率0.7 mL/h、环境温度25℃、相对湿度40%～70%.在此条件下得到的聚丙烯腈多孔超细纤维直径在420～490 nm,平均直径468 nm,表面孔隙率3.4%,纤维内部形成大量孔径为8～30 nm的孔结构,且孔径分布均匀,孔形状相对一致.N2吸附脱附测试表明,聚丙烯腈多孔纤维的BET比表面积达43.86 m2/g,是相同直径无孔聚丙烯腈纤维比表面积理论值的6倍.通过研究聚丙烯腈/(二甲基亚砜+N,N'-二甲基甲酰胺)/水的三元相图,提出非溶剂致相分离是主要成孔机理.     

静电纺丝法制备PLLA/g-HNTs复合纳米纤维膜及其性能研究

以辛酸亚锡为催化剂,利用HNTs表面的羟基引发L-LA开环聚合,合成了表面接枝聚(L-乳酸)(PLLA)链段的埃洛石纳米管(g-HNTs),通过红外、热失重和透射电镜对改性前后HNTs的组成与形貌进行了观察;然后采用静电纺丝技术制备了PLLA纳米纤维膜以及不同组成的PLLA/HNTs和PLLA/g-HNTs复合纳米纤维膜,探讨了纺丝条件对纳米纤维膜形貌的影响,并对复合膜的组成、形貌、力学性能和细胞相容性进行了研究.结果表明,当HNTs与L-LA的摩尔投料比为1∶10时,g-HNTs表面PLLA链段的接枝率为14.22％,HNTs纳米管的形态在接枝后变化不大,易于在无水乙醇中分散.电压强度和进样速率对纤维膜的形貌有一定影响,当电压强度为15 kV、进样速率为1 mL/h时,电纺纤维的直径较为均匀.复合纤维膜中g-HNTs在基体PLLA中的分散性以及与基体的界面相容性要优于相应的HNTs,当g-HNTs含量高达40％时,复合纳米纤维膜中的纤维形态仍然保持较好,可以得到连续、粗细较均匀的纤维;随着HNTs和g-HNTs含量增加,复合纳米纤维膜的拉伸强度和模量先增大后下降,当HNTs和g-HNTs的含量为5％时,两种复合纳米纤维膜的拉伸强度和模量均达到最大值,但PLLA/g-HNTs组复合纳米纤维膜的拉伸强度始终大于相应的PLLA/HNTs组.体外3T3细胞培养结果显示,PLLA/g-HNTs复合纳米纤维膜具有良好的细胞相容性,且优于相应的PLLA和PLLA/HNTs纳米纤维膜.     

γ-Al2O3柔性纳米纤维膜的制备及机械性能

以氯化铝和异丙醇铝为原料, 水和乙醇为溶剂, 通过溶胶凝胶结合静电纺丝法制备了柔性γ-Al₂O₃纳米纤维膜. 表征了纤维膜的形貌和机械性质, 并研究了纤维膜的形成过程. 组成纤维膜的纤维直径均匀, 平均直径188 nm, 纤维由粒径在15~30 nm的纳米颗粒组成且表面光滑. 制备的纤维膜具有较好的柔性及抗拉强度(1.01 MPa).     

γ-Al2O3柔性纳米纤维膜的制备及机械性能

以氯化铝和异丙醇铝为原料, 水和乙醇为溶剂, 通过溶胶凝胶结合静电纺丝法制备了柔性γ-Al2O3纳米纤维膜.表征了纤维膜的形貌和机械性质, 并研究了纤维膜的形成过程.组成纤维膜的纤维直径均匀, 平均直径188 nm, 纤维由粒径在15~30 nm的纳米颗粒组成且表面光滑.制备的纤维膜具有较好的柔性及抗拉强度(1.01 MPa).     

β-环糊精功能化聚丙烯腈纳米纤维的制备及对亚甲基蓝的吸附性能

以N,N-二甲基甲酰胺(DMF)为溶剂,利用静电纺丝法制备了聚丙烯腈(PAN)/β-环糊精(β-CD)纳米纤维.通过场发射扫描电镜、红外光谱和粉末XRD对纳米纤维进行了表征,并检测了纺丝溶液的电导率和黏度.结果表明,β-CD的添加量可以改善纳米纤维的形貌,固定在纤维上的β-CD保留了空腔结构,为其在纳米纤维中发挥超分子...     

PLLA/β-TCP杂化微纳米纤维的制备及其性能

将湿法工艺合成的β-磷酸钙纳米粒子与左旋聚乳酸(PLLA)的混合溶液通过电纺丝法制成杂化纳米纤维膜,以期制备一种新型纳米纤维骨组织修复材料。采用FT-IR,XRD,TEM,DSC等手段研究了β-磷酸钙(β-TCP)的结构和形态,采用SEM和直径分布探讨了优化PLLA/β-TCP纤维的电纺丝工艺。结果表明:采用湿法合成β-TCP的纳米粒子具有良好的晶型结构,直径在219~328 nm之间;采用双溶剂体系在优化条件下制备的PLLA/β-TCP杂化纳米纤维直径在500~700 nm之间,PLLA/β-TCP界面结合良好,β-TCP起到了增强作用。在湿态条件下,PLLA纤维膜的力学性能有所提高,而PLLA/β-TCP纤维膜的力学性能则呈现下降趋势。     

γ-Al_2O_3柔性纳米纤维膜的制备及机械性能（英文）

以氯化铝和异丙醇铝为原料,水和乙醇为溶剂,通过溶胶凝胶结合静电纺丝法制备了柔性γ-Al_2O_3纳米纤维膜.表征了纤维膜的形貌和机械性质,并研究了纤维膜的形成过程.组成纤维膜的纤维直径均匀,平均直径188 nm,纤维由粒径在15~30 nm的纳米颗粒组成且表面光滑.制备的纤维膜具有较好的柔性及抗拉强度(1.01 MPa).     

静电纺丝法制备相变调温纤维及其性能

以丙酮和N,N-二甲基甲酰胺（DMF）为混合溶剂,实验室自制固-固相变材料为相变工作物质,醋酸纤维素（CDA）为高分子载体,利用静电纺丝技术制备了相变调温纤维,研究了溶剂配比、纺丝液浓度、纺丝电压等对纤维形貌的影响。结果表明：以N,N-二甲基甲酰胺（DMF）和丙酮为溶剂（体积比为1/4）,在纺丝液质量分数为22%、纺丝...     

温敏性丙烯腈共聚物纳米纤维膜的制备与性能

采用可逆加成断裂链转移可控/活性聚合方法合成了丙烯腈与N-异丙基丙烯酰胺(NIPAM)的嵌段共聚物,通过调控嵌段聚合反应时间可以获得一系列不同嵌段链长的共聚物,分子量分布在1.3左右.运用静电纺丝技术制备了所合成嵌段共聚物的纳米纤维膜,扫描电镜照片表明纳米纤维膜较为均匀且直径可调.研究了纳米纤维膜表面水接触角与荧光标记牛血清清蛋白的吸附现象,接触角结果证实共聚物纳米纤维膜具有一定的温度响应性,且疏水性嵌段的引入导致响应温度较PNIPAM有所降低;蛋白质吸附结果则表明温度较低时纳米纤维膜表面更亲水,蛋白质吸附较少.所制备的温敏性纳米纤维膜可望用作智能分离与吸附材料.     

聚乙烯醇明胶混合水溶液的静电纺丝

将聚乙烯醇与明胶混合水溶液进行静电纺丝,制备了聚乙烯醇与明胶混合超细纤维及其电纺膜,研究了混合纺丝液的组成对纺丝液的粘度、表面张力和电导率的影响,观察了纤维的微观形貌,并对电纺膜进行了差示扫描量热测定.结果表明:当混合液中明胶含量小于20 9/6时,静电纺丝可以稳定进行.随着明胶含量由5%逐渐增加至25%,混合超细纤维的平均直径先是由260nm逐渐下降至207 nm而后又逐渐增加至320 nm.明胶的含量低于15%时,不影响其混合电纺膜中PVA的结晶.     

Controlling electrospun nanofiber morphology and mechanical properties using humidity

Electrospinning is a fiber spinning technique used to produce nanoscale polymeric fibers with superior interconnectivity and specific surface area. The fiber diameter, surface morphology, and mechanical strength are important properties of electrospun fibers that can be tuned for diverse applications. In this study, the authors investigate how the humidity during electrospinning influences these specific properties of the fiber mat. Using two previously uninvestigated polymers, poly(acrylonitrile) (PAN) and polysulfone (PSU) dissolved in N,N‐Dimethylformamide (DMF), experimental results show that increasing humidity during spinning causes an increase in fiber diameter and a decrease in mechanical strength. Moreover, surface features such as roughness or pores become evident when electrospinning in an atmosphere with high relative humidity (RH). However, PAN and PSU fibers are affected differently. PAN has a narrower distribution of fiber diameter regardless of the RH, whereas PSU has a wider and more bimodal distribution under high RH. In addition, PSU fibers spun at high humidity exhibit surface pores and higher specific surface area whereas PAN fibers exhibit an increased surface roughness but no visible pores. These fiber morphologies are caused by a complex interaction between the nonsolvent (water), the hygroscopic solvent (DMF), and the polymer. © 2011 Wiley Periodicals, Inc. J Polym Sci Part B: Polym Phys, 2011     

Aligned and molecularly oriented semihollow ultrafine polymer fiber yarns by a facile method

In this work, aligned and molecularly oriented bone‐like PLLA semihollow fiber yarns were manufactured continuously from an optimized homogeneous polymer‐solvent‐nonsolvent system [PLLA, CH₂Cl₂, and dimethyl formamide (DMF)] by a single capillary electrospinning via self‐bundling technique. Here, it should be emphasized that the self‐bundling electrospinning technique, a very facile electrospinning technique with a grounded needle (which is to induce the self‐bundling of polymer nanofibers at the beginning of electrospinning process), is used for the alignment and molecular orientation of the polymer fiber, and the take‐up speed of the rotating drum for the electrospun fiber yarn collection is very low (0.5 m/s). PLLA can be dissolved in DMF and CH₂Cl₂ mixed solvent with different ratios. By varying the ratios of mixed solvent system, PLLA electrospun semihollow fiber with the porous inner structure and compact shell wall could be formed, the thickness of the shell and the size of inner pores could be adjusted. The results of polarized FTIR and wide angle X‐ray diffraction investigations verified that as‐prepared PLLA semihollow fiber yarns were well‐aligned and molecularly oriented. Both the formation mechanism of semihollow fibers with core‐shell structure and the orientation mechanism of polymer chains within the polymer fibers were all discussed. The as‐prepared self‐bundling electrospun PLLA fiber yarns possessed enhanced mechanical performance compared with the corresponding conventional electrospun PLLA fibrous nonwoven membranes. © 2010 Wiley Periodicals, Inc. J Polym Sci Part B: Polym Phys 48: 1118–1125, 2010     

Membranes of epitaxial-like packed, super aligned electrospun micron hollow poly(l-lactic acid) (PLLA) fibers

Novel epitaxial-like packed, super aligned, mono-layered hollow fibrous membranes were prepared by co-axial electrospinning technology. PLLA pellets were dissolved in solvent mixture of dichloromethane and dimethyl formamide (DCM/DMF = 9:1) to prepare sheath solution dope with various concentrations (from 8 to 19 wt.%). Aqueous solution of poly-ethylene glycol (PEG) was used as core solution dope. During the electrospinning process, dope concentrations and feed rate ratios were adjusted, separately, to evaluate the formation of resulting membranes. With lower shell solution concentration (from 8 to 15 wt.%), the collected, flattened film showed arrangement of lower order. A stood-up film was clearly seen when concentration increased to 17 wt.% and higher. As the collecting time went longer, these fibers piled up and eventually, stood up as a thin film from the surface of collector. Increasing flow rate ratio (FRR) also resulted similar outcomes and verify the cause of this phenomenon. After washing with water, scanning electron microscopy (SEM) revealed sheets of mono-layered, micron-sized hollow fiber arrays which were well aligned and tightly packed, just like the epitaxial growth of some semiconducting materials. These perfectly aligned and tightly packed hollow fiber arrays can be considered as highly anisotropic scaffolds that mimic tissue structures, such as nerve tissue, vascular structure as well as other application.     

Process optimization and empirical modeling for electrospun polyacrylonitrile (PAN) nanofiber precursor of carbon nanofibers

Ultrafine fibers were spun from polyacrylonitrile (PAN)/N,N-dimethyl formamide (DMF) solution as a precursor of carbon nanofibers using a homemade electrospinning set-up. Fibers with diameter ranging from 200 nm to 1200 nm were obtained. Morphology of fibers and distribution of fiber diameter were investigated varying concentration and applied voltage by scanning electric microscopy (SEM). Average fiber diameter and distribution were determined from 100 measurements of the random fibers with an image analyzer (SemAfore 5.0, JEOL). A more systematic understanding of process parameters was obtained and a quantitative relationship between electrospinning parameters and average fiber diameter was established by response surface methodology (RSM). It was concluded that concentration of solution played an important role to the diameter of fibers and standard deviation of fiber diameter. Applied voltage had no significant impact on fiber diameter and standard deviation of fiber diameter.     

Electrospinning of Hyaluronic Acid (HA) and HA/Gelatin Blends

Summary: In the present study, electrospinning of hyaluronic acid (HA) and hyaluronic acid/gelatin (HA‐GE) blends in N,N‐dimethylformamide (DMF)/water‐mixed solvents have been investigated. When the volume ratio of DMF to water was in the range of 1.5–0.5, HA solutions could be electrospun into fibrous membranes successfully. The average diameter of HA fibers was about 200 nm. The HA‐GE composite nanofibrous membranes with varied HA/GE weight ratio in the range of 100/20–100/100 have also been successfully fabricated. The average diameter of HA‐GE fibers was in the range of 190–500 nm. The decrease in surface tension could promote fiber formation. Thus, an introduction of DMF that could decrease the surface tension distinctively, without significant change or increase in viscosity of the solution, could bypass the use of blowing‐assisted electrospinning. Our postulated picture is that the lower surface tension could help the ejection of stream with relatively high viscosity and reduce or prevent the droplet formation during the spinning process.

HA/GE (100/80) nanofibrous membrane produced by electrospinning.     

Solvent and concentration effects on the properties of electrospun poly(ethylene terephthalate) nanofiber mats

This study describes the preparation and characterization of nanofibrous mats obtained by electrospinning poly(ethylene terephthalate) (PET) solutions in trifluoroacetic acid/dichloromethane (TFA/DCM). Special attention was paid to the effect of polymer concentration and solvent properties on the morphology, structure, and mechanical and thermal properties of the electrospun nonwovens. The results show that the spinnable concentration of PET solution in TFA/DCM solvents is above 10 wt %. Mats have nanofibrous morphology with fibers having an average diameter in the range of 200–700 nm (depending on polymer concentration and solvent composition) and an interconnected pore structure. Higher solution concentration favors the formation of uniform fibers without beads and with higher diameter. Morphology and fiber assembly changed with the solvent properties. Solvent mixtures rich in TFA, i.e., those with higher dielectric constant and lower surface tension, originated fibers with small diameter. However, due to the lower volatility, those solvent mixtures also produced more branched and crosslinking fibers, with less morphologic uniformity. Mechanical properties (Young's modulus, ultimate strength, and elongation at break) and thermal properties (glass transition, crystallization, and melting) have been studied for the PET electrospun nanomats and compared with those of the original polymer. Solvent effect on fiber crystallinity was not significant, but a complex effect was observed on the mechanical properties of the electrospun mats, as a consequence of the different structural organization of the fibers within the mat network. © 2008 Wiley Periodicals, Inc. J Polym Sci Part B: Polym Phys 46: 460–471, 2008     

Bio-based and Biodegradable Electrospun Fibers Composed of Poly(L-lactide) and Polyamide 4

Novel bio-based and biodegradable block copolymers were synthesized by "click" reaction between poly(L-lactide)(PLLA) and polyamide 4(PA4). Upon tuning the molar mass of PLLA block, the properties of copolymers and electrospun ultrafine fibers were investigated and compared with those of PLLA and PA4 blends. PLLA and PA4 were found incompatible and formed individual crystalline regions, along with reciprocal inhibition in crystallization. Electrospun fibers were highly hydrophobic, even if hydrophilic PA4 was the rich component. The crystallinity of either PLLA or PA4 decreased after electrospinning and PLLA-rich as-spun fibers were almost amorphous. Immersion tests proved that fibers of block copolymers were relatively homogeneous with micro-phase separation between PLLA and PA4. The fibrous structures of copolymers were different from those of the fibers electrospun from blends, for which sheath-core structure induced by macro-phase separation between homopolymers of PLLA and PA4 was confirmed by TEM, EDS, and XPS.     

同轴静电纺丝法在纳米中空TiO2纤维中填充Ag的应用

以聚乙烯吡咯烷酮(PVP)溶胶/钛酸四正丁酯和PVP溶胶/银颗粒为前驱体, 以共轴静电纺丝法制备了银填充的TiO2中空纳米纤维. 将双组分纤维在200 ℃下热处理去除乙醇与表面吸附水后, 继而在空气气氛中焙烧至600 ℃, 可以得到在内表面上沉积银颗粒的TiO2纳米管, 银颗粒的直径为5-40 nm, TiO2纳米管的外径150-300 nm, 管臂厚10-20 nm. 用红外吸收光谱(IR)、X射线衍射(XRD)、扫描电子显微镜(SEM)、透射电子显微镜(TEM)等测试手段对超细纤维进行了表征. 中空纤维的直径和管壁可以通过改变电纺参数来调节. 与Ag-TiO2纳米纤维、TiO2纳米中空纤维、TiO2纳米纤维及TiO2纳米粉体相比较, Ag颗粒填充的TiO2纳米中空纤维在光分解亚甲基蓝上表现出了更好的光催化性能.     

同轴静电纺丝法在纳米中空Ti02纤维中填充Ag的应用

以聚乙烯吡咯烷酮(PVP)溶胶,钛酸四正丁酯和PVP溶胶,银颗粒为前驱体,以共轴静电纺丝法制备了银填充的TiO2中空纳米纤维.将双组分纤维在200℃下热处理去除乙醇与表面吸附水后,继而在空气气氛中焙烧至600℃.可以得到在内表面上沉积银颗粒的TiO2纳米管,银颗粒的直径为5-40 nm,TiO2纳米管的外径150-300 nm.管臂厚10-20 nm.用红外吸收光谱(IR)、X射线衍射(XRD)、扫描电子显微镜(SEM)、透射电子显微镜(TEM)等测试手段对超细纤维进行了表征.中空纤维的直径和管壁可以通过改变电纺参数来调节.与Ag-TiO2纳米纤维、TiO2纳米中空纤维、TiO2纳米纤维及TiO2纳米粉体相比较,Ag颗粒填充的TiO2纳米中空纤维在光分解亚甲基蓝上表现出了更好的光催化性能.