PVA/明胶/Fe_3O_4磁敏感性水凝胶的制备及性能研究

采用物理交联的方法制备了聚乙烯醇（PVA）／明胶／Fe3O4磁敏感性水凝胶。对Fe3O4磁敏感性水凝胶在加入明胶前后的力学性能及溶胀性能进行了对比分析，利用SEM、IR等对水凝胶进行表征，采用振动样品磁强计测试了其磁敏感性。结果表明，PVA／Fe3O4磁敏感性水凝胶加入明胶后，其力学性能明显增强，提高了0．4～0．7MPa，当磁性粒子含量为1．5％时，力学性能较好；加入明胶后，水凝胶脱水率和溶胀度都随着磁性粒子增加而增大；从SEM照片及IR图上可知，加入明胶后，PVA、明胶和Fe3O4三者相容性较好；测得的水凝胶磁敏感性较好。

Fe_3O_4/MnO_2磁性复合颗粒的制备及表征

以纳米Fe3O4颗粒为核,分别采用液相沉积法和溶胶-凝胶法两种方法将MnO2包覆在其上制备了Fe3O4/MnO2磁性复合颗粒,并借助XRD、TEM、FTIR和VSM等手段分别对纳米Fe3O4颗粒和两种复合颗粒进行表征。结果表明:采用液相沉积法进行包覆可生成以多个纳米Fe3O4颗粒为核、粒径约为200 nm的近球形Fe3O4/MnO2磁性复合颗粒,其饱和磁化强度为24.4 kA.m-1;采用溶胶-凝胶法进行包覆则生成以单个纳米Fe3O4颗粒为核、粒径约为50 nm的磁性复合颗粒,包覆层为絮状MnO2,其饱和磁化强度为16.5 kA.m-1。

新型核壳结构Fe_3O_4/H_xMn_yO_4纳米粒子的制备

采用自制的多通道撞击流反应器合成以纳米Fe3O4为内核,表面均匀包覆碳酸锰的核壳结构载体.用沉淀法在载体上包覆碳酸锂,再浸渍上一定量硝酸锂,形成"三明治"结构的锂离子筛前躯体,焙烧、脱锂后得到新型核壳结构的锂离子筛Fe3O4/HxMnyO4.实验中制备四种锂离子筛前躯体:Fe3O4/MnCO3/Li2CO3,Fe3O4/MnCO3/LiOH,Fe3O4/MnCO3/LiNO3,Fe3O4/MnCO3/Li2CO3/LiNO3,以及Li2CO3与LiNO3不同比例的Fe3O4/MnCO3/Li2CO3/LiNO3,并对不同组合下得到的锂离子筛性能,包括Fe,Mn的溶损率和对Li脱附率进行表征、分析,得出包覆Li2CO3/0.65LiNO3制得的新型锂离子筛性能最好.

Deflecting Easy-axis of Fe_3O_4 Single Crystal Nanowires by Magnetic-field-induced Method

In order to control the orientation of easy-axis of magnetic nanowires, FesO4 single crystal nanowires with easy-axis perpendicular to wire-axis were prepared successfully by means of a magnetic-field-induced method. Analysis of X-ray diffraction and electron diffraction pattern showed that there was a wide-angle deflection of easy-axis in the prepared Fe304 nanowires. A high saturation magnetization （82 emu/g） of the FesO4 nanowires was achieved at room temperature. The benefits and mechanism of the deflection of easy-axis from its wire-axis in FesO4 single crystal nanowires were discussed. The results are expected to broaden the magnetic properties of traditional ferrite nanowires.