毛刷状ZnO@PVDF复合纳米纤维柔性压电纳米发电机

采用静电纺丝技术并通过两步低温水热法制备了“毛刷”状的氧化锌(ZnO)@聚偏二氟乙烯(PVDF)复合纳米纤维膜。结果表明,氧化锌纳米棒(ZnO NRs)均匀地径向生长在PVDF纳米纤维的表面,FTIR分析发现ZnO@PVDF复合纳米纤维膜β相含量相比PVDF纳米纤维膜从72.3%提升到85.6%,增加了18.4%。ZnO@PVDF复合压电纳米发电机(PENG)输出电压可达4.9 V,短路电流为293 nA。在外部负载电阻达到13 MΩ时,ZnO@PVDF复合PENG达到最大输出功率0.93μW。ZnO@PVDF复合PENG可以为电容器充电,电容放电时成功点亮LED小灯泡。此外,在5000次的循环敲击测试中,ZnO@PVDF复合PENG具有稳定的输出电压,有望作为无源设备的自供电电源得到广泛应用。

Effect of Nanostructures Addition and Enhancement of Poly (Vinylidene Difluoride) (PVDF) Energy Harvesting

With concerns in energy crisis and global warming, researchers are actively investigating alternative energy renewable solutions. Among the various methods, piezoelectric transduction stands out due to its impressive electromechanical coupling factor and coefficient. As a result, piezoelectric energy harvesting has garnered significant attention from the scientific community. In this study, we explored methods to enhance the piezoelectric properties of polyvinylidene fluoride (PVDF) through two distinct approaches. The first approach involved applying external high voltages at various stages during the mixture reaction. The goal was to determine whether this voltage application could alter or enhance PVDF’s piezoelectric conformation by improving the alignment of polarized dipoles. In the second part of our study, we investigated the effects of incorporating various nanostructures (including Iron Oxide, Magnesium Oxide, and Zinc Oxide) into PVDF. To analyze changes in PVDF’s crystalline structure, we utilized Fourier Transform Infrared Spectroscopy (FTIR) and X-ray Diffraction (XRD) techniques. Additionally, we measured the electric polarization of samples using a Precision LC Meter and examined the morphology of nanofibers through Scanning Electron Microscopy (SEM).

纳米ZnO共混改性PVDF膜的制备及性能试验

聚偏氟乙烯(PVDF)膜由于机械强度高、分离通量大等优点被广泛应用于污水处理领域,但由于其强疏水性易产生膜污染。研究采用无机纳米ZnO与铸膜液共混的方法对PVDF滤膜进行基体改性,以提高膜的亲水性能与耐污染性能。研究结果表明,当铸膜液中ZnO添加量为0.50%时,改性膜的纯水通量最大可提高22%;相对于原始膜,无机纳米粒子的加入有效提高了膜的机械性能与亲水性,且当ZnO添加量为1.00%时,改性膜的抗污染性能最强;纳米粒子对膜性能的影响有一定的限度,当纳米粒子含量超过1.00%时,纳米粒子间的团聚现象、铸膜液稳定性改变等原因,使得改性膜的抗污染性能降低。文中提出的纳米ZnO共混改性PVDF膜方法,能够有效提高膜的亲水与抗污染性能,为膜在污水处理领域应用提供技术支持。

ZnO/PVDF压电复合材料的制备及性能

采用超声模板法制备了平行束状纳米ZnO晶须,将其与压电高聚物PVDF复合,用热压法制备六种含平行晶须状纳米ZnO不同质量分数与不同形态、尺寸的ZnO的ZnO/PVDF复合材料。经取向、极化后对其结构、形态及介电性和压电性能进行了系统测试。结果表明:尺寸与形态对压电复合材料的影响极大,球型、准球型、四针状纳米ZnO和非纳米ZnO与无定型PVDF复合,虽经同样条件极化处理,并无压电性能产生。与传统观念不同,即使主体为PVDF,但随着平行晶须状纳米ZnO含量的增加,电性能参数呈非线性增大,在ZnO含量仅为15%左右时就产生了复合材料介电常数ε和压电常数d33值的转折性突跃,与单一压电高聚物材料相比显著增加,且极化性能得到明显提高。

3种纳米材料改性PVDF膜的抗污染性能评价

采用模拟有机污染物(腐殖酸、海藻酸钠、牛血清白蛋白及其混合液),考察纳米(ZnO、Ag和TiO_2)改性聚偏氟乙烯(PVDF)膜对污染物的分离效能。结果表明,模拟污染物的膜污染机制与纳米改性无关联。PVDF/ZnO膜的水处理效能最佳,通量恢复率90%,可逆污染占总污染比例约90%。与PVDF膜相比,PVDF/ZnO膜在海藻酸钠条件下的污染指数降低了84.8%,对腐殖酸和混合液的浊度去除率分别达到98.9%和94.8%,且对浊度有更高的去除率。ZnO改性PVDF膜表现出良好的水分离性能和抗污染能力,可用于水处理过程。

界面缓冲层对全旋涂式PVDF–TrFE/ZnO量子点传感器压电性能的影响

首先制备了聚偏氟乙烯–三氟乙烯(PVDF-TrFE)/氧化锌(ZnO)量子点复合压电薄膜,采用广角X射线衍射仪、激光共聚焦显微镜及原子力显微镜等对其结构及形貌进行了表征。以其作为核心功能层,以聚乙烯吡咯烷酮(PVP)为界面缓冲层,采用全旋涂法成功制备了PVDF–TrFE/ZnO量子点压电传感器,分别利用落球试验及激振试验研究了PVP对传感器压电性能的影响。结果表明,添加PVP界面缓冲层的压电传感器输出电压为(1.84±0.06) V,误差棒较小,且在抗疲劳测试中经过3?500次机械循环后,输出电压仍保持在0.83 V。一方面,PVP缓冲层的亲水性使其分别与压电层中的ZnO量子点、聚(3,4-乙撑二氧噻吩):聚苯乙烯磺酸(PEDOT:PSS)电极层紧密结合,利于电荷在压电层与电极之间的传输;另一方面,PVP缓冲层良好的成膜性改善了压电层和PEDOT:PSS电极层的层间接触,利于收集更多的压电层电荷。制备的全旋涂式PVDF–TrFE/ZnO量子点压电传感器在柔性可穿戴领域具有广阔的应用前景。

低压近场静电纺丝ZnO/PVDF复合微米纤维阵列的制备及压力传感性（英文）

利用低压近场静电纺丝技术制备了ZnO/PVDF(聚二偏氟乙烯)微米纤维平行阵列,通过光学显微镜、扫描电子显微镜(SEM)和X射线能量色散光谱(EDS)对ZnO/PVDF微米纤维进行了表征.该复合纤维的平均直径约为40μm.EDS分析测试证明ZnO纳米颗粒已经掺杂进入了平行微米纤维中.压电性能和电学性能测试结果表明,ZnO/PVDF微米纤维阵列的压电性能增强.研究结果表明,近场电纺丝ZnO/PVDF复合微米纤维阵列在压电型压力传感器和纳米发电机领域具有潜在的应用价值.

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.

纳米氧化锌改性聚偏氟乙烯超滤膜的性能

采用共混法制备了纳米ZnO改性聚偏氟乙烯(PVDF)超滤膜,考察纳米ZnO添加量对聚偏氟乙烯膜性能的影响。膜性能测定数据表明,适量纳米ZnO(1.5%~2.0%)的添加使膜孔径增大了53.91%,膜纯水通量提高了77.01%。同时,膜接触角随着纳米ZnO添加而降低,从89.3°逐渐减小到77.9°;衰减系数减小了48.84%,膜阻降低了76.62%,PVDF-ZnO超滤膜对牛血清白蛋白(BSA)的截留率稳定在90%以上。以大肠杆菌为代表的PVDF-ZnO膜抑菌性能测试结果表明,随着纳米ZnO添加量的增加,PVDF-ZnO膜抑菌率相应增加,尤其在纳米ZnO质量分数为3.0%时抑菌率高达62.9%,显著提高PVDF膜的抗菌效果。

GO-ZnO共混改性PVDF膜的制备及抗污染性能

将不同量的GO-Zn O加入PVDF铸膜液中,通过浸没沉淀法制备PVDF复合超滤膜。利用FTIR、接触角、SEM对表面化学组成、亲水性和膜微观结构形貌进行了分析与表征,考察了GO-Zn O对膜性能的影响。同时以牛血清白蛋白和腐殖酸作为污染物进行过滤试验,分析了该复合膜的分离性能和抗污染性能,考察了污染膜清洗后的通量恢复效果。结果表明,添加GOZn O后的复合膜具有不同于基膜的渗透性能。随着添加量的增加,膜通量先增加后降低,并且在添加量为0.5%时,膜通量和膜通量恢复率均达到最大,即膜分离和抗污染性能最佳。