The case-dependent lignin role in lignocellulose nanofibers preparation and functional application-A review

Lignocellulose nanofibers(LCNFs) as a new material is attracting extensive attention. The pretreatment and mechanical fibrillation are the two main stages involved in the preparation of LCNFs, and lignin plays the important role of these two stages. This review discussed the interaction between lignin and chemicals in the pretreatment stage, and discovered the general law of the effect of lignin in the mechanical fibrillation stage.Lignin exhibits both promotion and inhibition effects on mechanical fibrillation, and the mutual competition between the two effects ultimately affects the energy consumption, morphology and yield of LCNFs. Furthermore, the recent research progress related to the contributions of lignin on the functional application of LCNFs was summarized, aiming to provide profound guidance for the preparation and application of LCNFs.

The Microparticles SiOx Loaded on PAN-C Nanofiber as Three-Dimensional Anode Material for High-Performance Lithium-Ion Batteries

Three-dimensional C/SiOx nanofiber anode was prepared by polydimethylsiloxane(PDMS)and polyacrylonitrile(PAN)as precursors via electrospinning and freeze-drying successfully.In contrast to conventional carbon cover-ing Si-based anode materials,the C/SiOx structure is made up of PAN-C,a 3D carbon substance,and SiOx load-ing steadily on PAN-C.The PAN carbon nanofibers and loaded SiOx from pyrolyzed PDMS give increased conductivity and a stable complex structure.When employed as lithium-ion batteries(LIBs)anode materials,C/SiOx-1%composites were discovered to have an extremely high lithium storage capacity and good cycle per-formance.At a current density of 100 mA/g,its reversible capacity remained at 761 mA/h after 50 charge-dis-charge cycles and at 670 mA/h after 200 cycles.The C/SiOx-1%composite aerogel is a particularly intriguing anode candidate for high-performance LIBs due to these appealing qualities.

甲基丙烯酸锌/丁腈橡胶纳米-微米混杂复合材料 Ⅱ.微观结构与宏观性能

研究了甲基丙烯酸锌/丁腈橡胶纳米-微米复合材料的应力-应变特性,物理机械性能与温度间的依赖关系及动态压缩疲劳性能。推测了复合材料内部可能存在的多种物理和化学结构,并提出了一些模型。认为离子键及其所形成的离子簇易于在外力和热的作用下松弛,使材料的伸长率和永久变形增大,高温性能下降,同时也对材料的常温强度产生贡献。聚甲基丙烯酸锌纳米粒子强的内聚能及其与橡胶间的化学接枝是材料高温性能优异和常温高强度的主要原因。

PVDF/石墨烯复合纳米纤维的制备及防水透湿性能

为深入了解聚偏氟乙烯(PVDF)/石墨烯纳米纤维复合膜的微观结构和防水透湿性能,通过静电纺丝技术制备PVDF/石墨烯纳米纤维复合膜。采用电镜扫描、水蒸气透湿仪、静态接触角测试仪和渗水性测试仪对纳米纤维复合膜的微观结构和防水透湿性能进行了表征及测试。结果表明,当石墨烯浓度较低时通过超声波振荡以后能和PVDF纺丝液均匀混合,且石墨烯的添加会使得复合膜的纳米纤维平均直径增大;同时复合膜的孔隙率和透湿性得到提高,其透湿量由纯PVDF膜的2915.92 g/(m^2 24 h)提高到4415.37 g/(m^2 24 h),其静态接触角和静水压出现下降,接触角由纯PVDF膜的143.5°下降到125.3°,耐水压由纯PVDF膜的23.4 MPa下降到13.7 MPa。

纳米硫化汞/偕胺肟复合纤维的制备及抑菌性能研究

以聚丙烯腈纤维(PAN)为原料,改性制得含有偕胺肟基团的螯合纤维(AOCF),使其与纳米硫化汞反应,制得纳米硫化汞/偕胺肟复合纤维(nano-HgS/AOCF)。运用扫描电镜(SEM)及X-衍射能谱仪(EDX)对样品进行了表征,并研究了纤维对大肠杆菌和枯草芽孢杆菌的抑菌性能。结果表明,偕胺肟纤维表面生成了分散均匀的纳米硫化汞,0.15 g的nano-HgS/AOCF对大肠杆菌的抑菌能力与5.0万单位的青霉素相当,而对枯草芽孢杆菌的抑菌能力与2.0万单位的青霉素相当。

静电纺PMIA纳米纤维的制备工艺优化及性能

以氯化锂/N,N–二甲基乙酰胺为溶剂,通过静电纺丝和正交试验优化制备了间位芳纶(PMIA)纳米纤维。采用扫描电子显微镜、傅立叶变换红外光谱和热失重分析表征了PMIA纳米纤维的外貌形态和性能。在正交试验优化结果的基础上,将PMIA纳米纤维复合到PMIA针刺非织造布上得到PMIA复合过滤非织造布,并对其力学性能、透气性能和过滤性能进行了测试。结果表明,LiCl浓度对PMIA纳米纤维直径影响最显著。在LiCl浓度为2%,PMIA浓度为12%及接收距离为20cm和静电电压为20kV时,制得的PMIA纳米纤维平均直径最小,为74.84nm。PMIA纤维的分解温度约为415℃。红外光谱显示,PMIA纳米纤维的微结构没有变化,在3450cm^-1处存在羟基特征峰。PMIA复合过滤非织造布的透气性能下降16.4%,过滤阻力增加27.5%,过滤效率提高46.2%。

白炭黑/纳米甲壳素/多层石墨烯对溶聚丁苯橡胶/顺丁橡胶并用胶性能的影响

将白炭黑、纳米甲壳素与多层石墨烯三者并用填充溶聚丁苯橡胶(SSBR)/顺丁橡胶(BR)并用胶,考察了多层石墨烯用量对并用胶硫化特性、物理机械性能、耐老化性能及Payne效应的影响。结果表明,加入多层石墨烯后,SSBR/BR混炼胶的焦烧时间及正硫化时间明显缩短,硫化速率加快,加工性能得到改善;随着多层石墨烯用量的增加,SSBR/BR硫化胶的拉伸强度略提高后降低,100%定伸应力及300%定伸应力逐渐降低,扯断伸长率增大,撕裂强度及邵尔A硬度变化不大;经热空气老化后,SSBR/BR硫化胶的拉伸强度变化率明显降低,综合考虑,多层石墨烯最佳用量为1.0份;随着多层石墨烯用量的增加,SSBR/BR混炼胶的Payne效应逐渐下降,而硫化胶的Payne效应变化不大。

钛中空纤维膜改性及应用研究

采用相转化法制备高致密的钛中空纤维膜后,使用电化学阳极沉积法在其表面负载二氧化钛TiO_(2)纳米结构进行改性,并以罗丹明B(RhB)为模拟有机废水评价其催化降解性能。结果表明,以钛粉(Ti)、N-甲基吡咯烷酮(NMP)、钯(Pd)、聚砜(PS)为铸膜液原料,且NMP:PS=6:1,烧结温度为1000℃制得的高致密钛中空纤维膜,将其浸泡于TiCl_(3)溶液中,在恒电流10mA/cm^(2)、沉积时间10min条件下,可在钛中空纤维膜载体表面负载平整光滑的线状纳米TiO_(2)。与纯钛板和纯钛中空纤维膜相比,负载纳米TiO_(2)的钛中空纤维膜,对浓度为8mg/L的RhB溶液的电化学降解速率最快,其降解效率在40min内可达95%。