Fabrication and Properties of Graphene Oxide/Sulfonated Polyethersulfone Layer-by-layer Assembled Polyester Fiber Composite Proton Exchange Membranes

Using the hydrogen-bonding interaction between graphene oxide（GO） and sulfonated polyethersulfone （SPES）, we constructed the multilayer structure of GO and SPES on the polyester tiber mats via layer-by-layer self-assembly. In each self-assembled layer, sulfonic acid groups are arranged along the a^s of fiber, which provides the long-range proton transmission channels, promoting the rapidly proton conduction. The performances of the composite membranes based on SPES and multilayer assembled polyester fiber mats were studied. The results show that the proton conductivity of composite membranes increases with the increasing assembly layers. At the same time, the mechanical properties and methanol-resistance of the composite membranes were obviously improved.

A Novel Multiscale Reinforcement by In-Situ Growing Carbon Nanotubes on Graphene Oxide Grafted Carbon Fibers and Its Reinforced Carbon/Carbon Composites with Improved Tensile Properties

In-situ growing carbon nanotubes （CNTs） directly on carbon fibers （CFs） always lead to a degraded tensile strength of CFs and then a poor fiber-dominated mechanical property of carbon/carbon composites （C/ Cs）. To solve this issue, here, a novel carbon fiber-based multiscale reinforcement is reported. To synthesize it, carbon fibers （CFs） have been first grafted by graphene oxide （GO）, and then carbon nanotubes （CNTs） have been in-situ grown on GO-grafted CFs by catalytic chemical vapor deposition. Characterizations on this novel reinforcement show that GO grafting cannot only nondestructively improve the surface chemical activity of CFs but also protect CFs against the high-temperature corrosion of metal catalyst during CNT growth, which maintains their tensile properties. Tensile property tests for unidirectional C/Cs with different preforms show that this novel reinforcement can endow C/C with improved tensile properties, 32% and 87% higher than that of pure C/C and C/C only doped with in-situ grown CNTs. This work would open up a possibility to fabricate multiscale C/Cs with excellent global performance.

高介电常数低介电损耗PEG@graphene/PVDF复合材料的制备及性能研究

将单端氨基化聚乙二醇(PEG-NH2)接枝的石墨烯填充到聚偏氟乙烯(PVDF)基体中,通过溶液法制备了PEG@graphene/PVDF纳米复合材料,并借助扫描电子显微镜(SEM)、红外光谱(FTIR)、X射线衍射(XRD)、热重分析(TGA)以及阻抗分析仪等手段对复合材料的结构形貌及介电性能进行了分析表证。研究表明:改性的石墨烯具有较好的溶剂稳定性,能均匀分散在PVDF基体中,与基体界面结合良好;具有核壳结构的PEG@graphene有效提高了PVDF复合材料的介电常数,降低了介电损耗。PEG@graphene/PVDF质量分数3%复合材料的介电常数高达137,介电损耗为0.29(50 Hz)。

Reduced Graphene Oxide/Carbon Fiber Composite Membrane for Self-floating Solar-thermal Steam Production

Solar-thermal water evaporation has attracted increasing attention owing to the promising potential to solve the global clean water and energy crisis.But,the development of this strategy is limited by the lack of materials with high solar-thernal conversion efficiency,local heating of superficial water,easy preparation and low cost.Herein,we proposed a facile strategy to prepare a reduced graphene oxide/carbon fiber composite membrane,denoted as RGO/CF membrane.The surface of the RGO/CF membrane was highly hydrophobic,endowing the composite membrane with the self-floating ability on the water without any assistance.The light absorbance ability achieved as high as ca.98%in the wavelength range of 300-1200 nm.The steam evaporation efliciency under the illumination of3-sun was 97%,generating water steam at a rate of 4.54 kg·m^-2·h^-1.Moreover,the solar-thermal steam production rate showed high stability during successive 30 cvcle tests.

Synthesis, Characterization and Gas Sensing Properties of Graphene Oxide-Multiwalled Carbon Nanotube Composite

Graphene oxide （GO）-multiwalled carbon nanotube （MWCNT） composite was synthesized and characterized by X-ray diffraction, atomic force microscopy, scanning electron microscopy, micro Raman, Fourier transform infrared and ultraviolet-visible near infrared spectroscopy techniques. Spectral characteris- tics of cladding modified fiber optic gas sensors were studied for various concentrations of ammonia, ethanol and methanol at 27 ℃. Thickness of the gas sensing layer was controlled by varying the concentration of composite in ethanol medium （0.5 and 1 mg/mL） for three times dipping process. The O.S mg/ mL concentrated GO-MWCNT coated sensor showed 1.20, 1.40 and 1.15 times higher sensitivity than the GO coated sensor for ammonia, ethanol and methanol vapors, respectively. Furthermore, it exhibited 1.50, 1.80 and 1.80 times better sensitivity than 1 mg/mL concentrated GO-MWCNT coated sensor for ammonia, ethanol and methanol vapors, respectively. The presence of functional groups in GO increased the sen- sitivity. This is mainly attributed to the effective electron charge transfer between the composite materials and analytes.

Preparation and Characterization of Multi Shape ZnO/PVDF Composite Materials

Two different morphologies of ZnO（lotus-shaped, rod-shaped） and ZnO/PVDF composite materials were prepared. The morphologies of ZnO and composite materials were characterized by scanning electron microscopy（SEM） and transmission electron microscopy（TEM）. Fourier transform infrared spectroscopy（FT-IR）, thermal gravimetry（TG）, and X-ray diffraction（XRD） were also used to characterize the chemical structures and phase composites of ZnO and ZnO/PVDF composite materials. Breakdown voltage, dielectric constant and dielectric loss of ZnO/PVDF composite materials were also tested. Microstructure analysis showed that ZnO nanoparticles dispersed uniformly in the matrix. And the dielectric constant expresses a significantly improvement while the dielectric loss and breakdown voltage expresses no significant change. Moreover, dielectric constant keeps an improvement tendency with increasing content of ZnO.

A simple and controllable nanostructure comprising non-conductive poly（vinylidene fluoride） and graphene nanosheets for supercapacitor

An effective method was used to Ioidal suspensions of highly reduced graphene produce stable and homogeneous coloxide （RGO） in N,N-dimethylformamide （DMF） without the assistance of dispersing agents. According to the results of general characterization, relatively pure graphene sheets with the morphology of single layer or few-layer structure were obtained. Then nanocomposite powders of RGO and poly （vinylidene fluoride） （PVDF） were prepared by vacuum filtration of the mixed dispersions of both components. The nanocomposites exhibit a high-frequency capacitative response with small equivalent series resistance （ESR） at 0.4Q, a nearly rectangular cyclic voltammogram and possess a rapid current response as electrodes for supercapacitor in 5mol/L KOH electrolyte. Furthermore, after 600 galvanostatic charge/ discharge cycles, the supercapacitor still performs a very high stability and efficiency of capacitance.

石墨烯-碳纳米管复合纤维高灵敏度测温性能

以碳纳米管(CNT)为填料、氧化石墨烯(GO)溶液为主体,通过化学限域水热法制备了含有不同质量碳纳米管的石墨烯-碳纳米管复合纤维。发现石墨烯-碳纳米管复合纤维热电性能随着氧化石墨烯与碳纳米管质量比的增加有提升趋势。利用瞬态电热(TET)技术研究了石墨烯-碳纳米管复合纤维的测温性能,并分析了其导电机理。结果表明,石墨烯-碳纳米管复合纤维的测温性能表现良好,且随着温度的降低,测温性能进一步提升。在30 K时,电阻温度系数(TCR)为0.05 K^(-1),特征响应时间为0.56 s;电流热退火后结构尺寸增大了0.5倍。导电机理由热激活传导(150~292 K)转变为最近邻跳跃(NNH)传导(70~150 K)和可变范围跳跃(VRH)传导(30~70 K)。为石墨烯-碳纳米管复合纤维在高灵敏度温度传感器上的应用提供了理论支撑。

PVDF/GO-ZnO光催化复合平板膜的制备及其性能

为有效解决纳米催化剂光催化后的回收困难问题,本文以聚偏氟乙烯(PVDF)为基质膜,以亲水性的光催化剂氧化石墨烯(GO)/氧化锌(ZnO)为添加剂,通过相转化法(NIPS)制备出具有自清洁功能的PVDF/GO-ZnO光催化复合平板膜,并对其结构及光催化性能进行了系统研究。与纯PVDF膜相比,PVDF/GO-ZnO光催化平板膜的孔径增加,使其亲水性和水通量显著提高。其中,GO-ZnO掺杂量为1.26%的PVDF/GO-ZnO光催化复合平板膜M-4的纯水通量高达153.73 L/(m^(2)·h),纯水接触角最小为77°。在模拟太阳光照射80 min时,该光催化复合平板膜对甲基蓝(MB)的降解效率高达98.79%。此外,该光催化平板膜3次循环降解染料后的光催化降解效率仍高达93.60%,且在不同酸碱性的染料溶液中依旧保持良好的光催化降解效果,在工业处理印染废水中显示出很好的应用前景。

氧化石墨烯改性聚偏氟乙烯分离膜的制备、性能及应用

简述了聚偏氟乙烯(PVDF)膜与氧化石墨烯(GO)的结构特征,分析了有机-无机杂化膜的优势。详述目前GO/PVDF膜的几种主要制备方法,包括溶液浇铸法、静电纺丝法、化学接枝法、真空抽滤法等,分析了各制备方法的优劣。阐述了GO对PVDF复合膜孔径、亲疏水性能、膜通量、截留性能、力学性能等的影响,并对复合膜在水处理及其他潜在应用进行了综述。分析发现,溶液浇铸法工艺简单、制膜周期短,化学接枝法制得的膜各组分间结合稳固、服役时间长,而静电纺丝法制得的膜比表面积大、孔隙率高。在微观层面,GO片层发生毛细作用、低于片层直径的粒子能以更快的速度通过,宏观上表现为膜通量的提高,GO还能提高膜表面光洁度、减少杂质淤堵与污染,进而提高膜的使用寿命。对GO/PVDF复合膜的发展趋势进行了展望,以期为构建高效稳定的PVDF基分离膜提供理论依据与技术支持。

基于静电纺PVDF/GO复合纳米纤维的摩擦纳米发电机的制备和输出性能

为提高基于聚偏氟乙烯(PVDF)的摩擦纳米发电机(TENG)的输出性能,采用静电纺丝法制备PVDF/GO(氧化石墨烯)复合纳米纤维,并组装成垂直接触-分离式TENG,探究GO质量分数对由PVDF/GO复合纳米纤维组成的TENG的输出性能的影响。通过COMSOL软件对TENG的输出性能进行模拟仿真,分析TENG在不同极板距离下的电势和电能密度的变化规律,为TENG的工作原理提供理论支撑。通过扫描电子显微镜对PVDF/GO复合纳米纤维的形貌结构进行表征,并采用数字示波器对基于PVDF/GO复合纳米纤维的TENG的输出性能进行表征。结果表明:当GO质量分数为0.06%时,基于PVDF/GO复合纳米纤维的TENG具有良好的输出效率,其输出电压约为350 V,短路电流约为28μA,在阻抗匹配条件下,最大峰值功率约为9.66 mW,其功率密度约为3.86 W/m2。基于PVDF/GO复合纳米纤维制备的TENG具有良好的输出性能,能为120个发光二极管(LED)供电,因此在能量收集领域具有潜在的应用前景。

静电纺压电聚偏氟乙烯纳米纤维研究

因聚偏氟乙烯(PVDF)具有优异的压电性能、化学稳定性,在柔性传感器、钠离子电池隔膜和生物医学方面具有广泛应用。但纯PVDF的β相含量没有达到理想状态,而静电纺丝技术是一种简便有效制备纳米纤维的方法,可以有效控制纤维直径、提高PVDF的β压电相性能。文章对PVDF性能与静电纺丝技术分别进行介绍,对静电纺PVDF纳米纤维工艺及其影响因素进行分析,对静电纺施加电压、接收距离与β相含量关系进行对比,对静电纺PVDF的主要应用情况进行说明。

氧化石墨烯-壳聚糖-钛酸钡/聚偏氟乙烯-三氟乙烯压电复合涂层对人脐带间充质干细胞成骨分化的影响

目的:探讨氧化石墨烯-壳聚糖改性的钛酸钡纳米颗粒(BCG-NPs)与聚偏氟乙烯-三氟乙烯(P(VDF-TrFE))复合压电材料对人脐带间充质干细胞(hWJ-MSC)成骨分化的影响。方法:采用滴涂法在钛表面制备BCG-NPs/P(VDF-TrFE)涂层(BCGP-Ti),对其表面形貌、物相组成、亲水性和压电性能进行表征。通过模拟体液浸泡实验检测样本体外矿化的能力。将hWJ-MSC接种在样本表面,采用CCK-8检测细胞活力,细胞骨架染色观察hWJ-MSC铺展情况,碱性磷酸酶(ALP)和茜素红染色分别评估ALP活性和矿化水平,实时荧光定量PCR和免疫荧光染色检测成骨分化相关基因和蛋白表达。将Ti棒与BCGP-Ti棒分别植入SD大鼠股骨,Micro-CT和组织学染色观察骨整合效果。结果:扫描电镜和X射线衍射分析证实BCGP-Ti涂层成功构建。极化后BCGP-Ti具有良好的压电响应,其亲水性优于Ti和未极化的BCGP-Ti(P<0.01),体外矿化的能力高于Ti和未极化的BCGP-Ti(P<0.01)。hWJ-MSC在极化后BCGP-Ti表面铺展的面积较Ti组增加(P<0.05)。与Ti相比,极化后BCGP-Ti促进hWJ-MSC矿化水平、ALP以及Ⅰ型胶原蛋白(COL1)、Runt相关转录因子(RUNX2)、骨钙素(OCN)等成骨分化相关基因和蛋白的表达(P<0.05),在体内实现更好的骨整合。结论:在钛基表面构建BCG-NPs/P(VDF-TrFE)涂层可诱导hWJ-MSC成骨分化促进骨整合。

GO杂化PVDF纳米纤维复合压电器件制备及性能研究

为制备高性能小型压电发电机,用静电纺丝制备聚偏氟乙烯PVDF纳米纤维膜,其中掺杂0%、0.3%、0.4%、0.5%质量比氧化石墨烯GO,对其进行SEM、接触角测试仪、红外光谱仪、热失重仪等测试。研究表明,随着GO浓度的增大,纤维的串珠变少,均匀性变好;纤维膜的接触角变小,疏水性下降。添加GO能促进PVDF中的β晶型的形成,并抑制α晶型的形成,GO浓度为0.5%时效果最佳。随着GO浓度的增大,PVDF纤维膜质量损失变少,稳定性更好。通过电压测试可得,以针织导电布为基底添加0.5%GO的PVDF纤维膜模型在克重为0.15g时,运动所产生的电压值最大,最大的电压峰值可达到273.4mV。研究结果为制备简单高效的纳米发电器件提供一定的研究价值。

高通量rGO微球@PVDF纳米纤维复合膜的制备及其油水分离性能研究

采用静电纺丝法制备了聚偏氟乙烯(PVDF)纳米纤维膜,并采用共混纺丝法和真空抽滤两种方式将还原氧化石墨烯微球(rGO)负载于其上,获得高通量rGO微球@PVDF纳米纤维复合油水分离膜。通过调整静电纺丝过程参数(如推注速率和电场强度等)和纺丝液配方,对PVDF纳米纤维膜结构进行优化,并采用不同的rGO微球负载量、负载方式、黏结剂含量来提高纳米纤维膜的表面粗糙度和疏水性。利用扫描电子显微镜和接触角测试对纤维膜的表面形貌和亲疏水性进行表征,并通过二氯甲烷-水体系进行油水分离实验,测试了不同配方下杂化膜的重力驱动油水分离性能。结果表明,当静电纺丝溶液中PVDF含量为14%时,以1 mL·h^(-1)的推注速率,在15 kV下制得的PVDF纳米纤维膜,并将1%PVDF溶液、3 mg rGO微球(与黏结剂中有效成分PVDF质量比为3∶1)和溶剂组成的铸膜液抽滤在膜表面,复合膜表面水接触角为130.9°,其油水分离过程中的有机溶剂透过通量可达5641.3 L·h^(-1)·m^(-2),水相的截留率为99.28%。

CFGO@PVDF复合纳滤膜的结构调控及截留性能

以聚偏氟乙烯(PVDF)和羧基化氧化石墨烯(CFGO)为原料,制备了高亲水性和高脱盐效能的CFGO@PVDF复合纳滤膜(GONF膜),通过优化制备条件,结合微观结构及形貌表征,获得了GONF膜的最佳制备条件,实现了复合纳滤膜性能的显著提升。结果表明,与传统PVDF纳滤膜(CNF膜)相比,CFGO@PVDF复合纳滤膜展现了更深的孔通道和显著提高的亲水性,其纯水通量可达13.1 L/(m^(2)·h·bar)(1 bar=100 kPa),是CNF膜的2.5倍以上。此外,GONF膜的晶型实现了由α相向β相转化,膜表面的含氧官能团含量增加,大幅提升了对2 g/L不同盐溶液的截留率,其中对Na_(2)SO_(4)和MgSO_(4)的截留率分别高达96%和95%以上,且60 min内未发生明显衰减。研究成功研制了一种高水通量、高效稳定脱盐的CFGO@PVDF复合纳滤膜,为纳滤膜的设计与制备提供了新的思路,也为解决全球水处理问题提供了有效的技术思路。

纳米氧化物粒子对PVDF中空纤维膜结构与性能的影响

采用相转化法制备纳米氧化物/聚偏氟乙烯复合中空纤维膜,讨论了纳米氧化钛和氧化铝粒子对PVDF膜结构和性能的影响.应用牛血清白蛋白截留实验、扫描电子显微镜、傅立叶红外光谱分别对不同膜的分离性能、微观结构和晶相组成进行了分析.结果表明,复合膜的性能与纯PVDF膜相比有显著地改善,其中纯PVDF膜、Al2 O3 /PVDF和TiO2 /PVDF复合膜对牛血清白蛋白的截留率分别为3 . 2 7%、6 7 .2 0 %和86 . 6 7%,复合膜的水通量则较纯PVDF膜分别提高2 . 3倍和2 . 6倍.氮气吸附实验测定的孔径分布进一步表明复合膜的孔径分布变窄,孔径变小.

石墨烯/酚醛树脂/炭纤维层次复合材料的制备及其性能

分别以氧化石墨粉(GO)、还原氧化石墨烯乙醇悬浮液(RGO)和热法还原石墨烯粉(TRG)为填料,分散于酚醛树脂(PR)的乙醇溶液中,再将这些基体混合物涂覆于炭纤维(CF)布上,经热压成型工艺制备氧化石墨烯/酚醛树脂/炭纤维、还原氧化石墨烯乙醇悬浮液/酚醛树脂/炭纤维、热法还原氧化石墨烯/酚醛树脂/炭纤维层次复合材料。研究了GO、RGO和TRG对复合材料结构、压缩性能、弯曲性能及磨擦性能的影响。结果表明,与纯酚醛树脂/炭纤维复合材料相比,当纳米填料的质量分数仅为0.1%时,层次复合材料的压缩性能可显著提高,其中,热法还原氧化石墨烯/酚醛树脂/炭纤维的压缩强度和模量分别提高了178.9%,129.5%;弯曲性能也可得到一定的改善。还原氧化石墨烯乙醇悬浮液/酚醛树脂/炭纤维层次复合材料的最大储能模量可提高75.2%。所有改性石墨烯/酚醛树脂/炭纤维层次复合材料的Tg均有所降低。

碳纳米材料/聚偏氟乙烯杂化膜的制备及性能

为了改善膜的形貌,提高膜的分离性能和力学性能,以聚偏氟乙烯(PVDF)为聚合物,以多壁碳纳米管(MWCNT)为纳米填料,以氧化石墨烯(GO)溶液为凝固浴,通过基质混合和溶液凝固浴相结合的方式,成功制备了PVDF/MWCNT/GO杂化膜.通过TEM、SEM、FT-IR等手段对MWCNT和GO的形貌及结构进行了表征,同时研究了碳纳米材料的添加对膜的形貌、分离性能以及力学性能的影响.结果表明:MWCNT呈长管状网络结构,GO呈片层结构,二者的协同作用将有利于膜力学性能的改善;而GO表面丰富的含氧官能团,可以使其在水中有很好的分散稳定性,并且当MWCNT的质量分数为3%时,膜的综合性能达到最优,与纯膜相比,杂化膜的形貌和亲水性有了一定的改善,纯水通量、截留率和力学性能分别提高了约106%、58.7%和101%,这说明碳纳米材料可以有效提高膜的分离性能和力学性能.

氧化石墨烯/聚偏二氟乙烯复合纤维过滤膜的制备及其过滤性能

为得到高过滤效率、低过滤阻力的空气过滤材料,将氧化石墨烯掺入以聚偏二氟乙烯(PVDF)为基体,N,N-二甲基甲酰胺与丙酮为混合溶剂的纺丝液中,利用静电纺丝技术制备高性能氧化石墨烯/PVDF复合纤维过滤膜。研究不同聚偏二氟乙烯质量分数、氧化石墨烯质量分数、静电纺丝电压、接收距离等参数对复合纳米纤维过滤膜外观形态、过滤效率、过滤阻力的影响。结果表明:聚偏二氟乙烯质量分数为16%,氧化石墨烯质量分数为1. 0%,静电纺丝电压为29. 0 k V,接收距离为16 cm时,制备的复合纤维过滤膜形貌较好,纤维连续且均匀,过滤效率为99. 99%,过滤阻力为11. 53 Pa/μm,具有良好的过滤性能。