高能球磨FeCo+MnO的结构与磁性研究

用高能球磨采用两种方案制备了FeCo MnO体系,并用X射线衍射和振动样品磁强计对其结构和磁性质做了分析.发现采用直接氧化Mn而得到MnO的方法,所得体系的MnO较纯;而通过分解MnCO3得到MnO的体系,MnO纯度较低,有较多Mn3O4杂质,两种方法制备的FeCo MnO体系的矫顽力和剩磁比都比单纯FeCo体系的增加很多,且前一种方法比后一种方法制备的FeCo MnO体系的矫顽力和剩磁比较大.然后研究了球磨时间及退火处理对FeCo MnO体系矫顽力及剩磁比的影响,发现球磨时间为120h体系的矫顽力和剩磁比最大;经过退火处理后,体系的矫顽力和剩磁比都有较大幅度的增加.     

低温固相反应法在纳米电极材料合成中的应用

介绍了低温固相合成技术的特点和优势，以及该技术在制备二次碱锰电池正极材料及其改性添加剂中的应用，纳米级MnO2正极材料以及由纳米改性添加剂修饰的MnO2正极材料在深度放电时具有更优越的性能。     

MnO超微粒子的制备及其对PEMFC电催化性能的研究

用微乳液法合成了 Mn O超微粒子 ,探讨了影响萃取率及粒度的因素 ,得到了最佳反应条件 ,并用透射电子显微镜 (TEM)、X射线衍射仪 (XRD)及红外光谱 (FTIR)进行了表征。得到了粒径为 5 nm左右的 Mn O超微粒子 ,并在质子交换膜燃料电池 (PEMFC)的铂电极中加入 5 nm的Mn O超微粒子作为催化剂 ,改变了电池的放电机理 ,提高了输出电压。为 PEMFC的商品化进行了有价值的探索。     

La0.7Ca0.3MnO3多晶材料制备及其电磁特性

以化学溶液分解法制备La0.7Ca0.3MnO3粉体,常压烧结制备多晶块体样品。对La0.7Ca0.3MnO3样品的磁矩、磁致电阻效应（CMR）和电脉冲诱导电阻转变效应（EPIR）进行了研究。磁矩零场冷和场冷试验结果发现,居里温度以下,零场冷和场冷条件下磁矩具有较大差别。这说明材料中缺少真正的长程磁有序。La0.7Ca0.3MnO3多晶具有磁致电阻效应,在9 T磁场作用下,磁致电阻变化大约为70%。在80 V,20 ns电脉冲作用下,材料具有电脉冲诱导电阻转变效应。从理论上对磁致电阻效应与电脉冲诱导电阻转变效应的机理进行了分析。     

蜂窝陶瓷型La0．8Sr0.2MnO3催化剂VOCs催化燃烧反应活性

以堇青石(CH)为第一载体,六铝酸盐(HA)为第二载体(washcoat),La0.8Sr0.2MnO3(LSM)为活性物种,制备了LSM/HA/CH催化剂.XRD表征发现,LSM具有完善的钙钛矿晶型.SEM观察表明,活性物种在涂层表面分散均匀.通过对苯、甲苯、二甲苯、乙酸乙酯、丙酮和乙醇六种有机物的性能测试,发现LSM/HA/CH对上述六种有机物均具有很好的催化活性,特别是对乙酸乙酯等含氧有机物表现出更好的燃烧性能,在10000 h-1空速下,反应温度为240℃时即可将含氧有机物完全燃烧.     

Spinel-layered integrate structured nanorods with both high capacity and superior high-rate capability as cathode material for lithium-ion batteries

Spinel phase LiMn2O4 was successfully embedded into monoclinic phase layeredstructured Li2MrnO3 nanorods,and these spinel-layered integrate structured nanorods showed both high capacities and superior high-rate capabilities as cathode material for lithium-ion batteries (LIBs).Pristine Li2MnO3 nanorods were synthesized by a simple rheological phase method using α-MnO2 nanowires as precursors.The spinel-layered integrate structured nanorods were fabricated by a facile partial reduction reaction using stearic acid as the reductant.Both structural characterizations and electrochemical properties of the integrate structured nanorods verified that LiMn2O4 nanodomains were embedded inside the pristine Li2MnO3 nanorods.When used as cathode materials for LIBs,the spinel-layered integrate structured Li2MnO3 nanorods (SL-Li2MnO3) showed much better performances than the pristine layered-structured Li2MnO3 nanorods (L-Li2MnO3).When charge-discharged at 20 mA·g-1 in a voltage window of 2.0-4.8 V,the SL-Li2MnO3 showed discharge capadties of 272.3 and 228.4 mAh.g-1 in the first and the 60th cycles,respectively,with capacity retention of 83.8％.The SL-Li2MnO3 also showed superior high-rate performances.When cycled at rates of 1 C,2 C,5 C,and 10 C (1 C =200 mA·g-1) for hundreds of cycles,the discharge capacities of the SL-Li2MnO3 reached 218.9,200.5,147.1,and 123.9 mAh·g-1,respectively.The superior performances of the SL-Li2MnO3 are ascribed to the spineMayered integrated structures.With large capacities and superior high-rate performances,these spinel-layered integrate structured materials are good candidates for cathodes of next-generation high-power LIBs.     

基于低温炼铁技术酸性高炉渣流动性的实验研究

用分析纯化学试剂配制高炉炉渣,研究基于低温炼铁技术MnO和Na2CO3含量对高炉渣熔化温度及黏度的影响,并用XRD分析缓冷后熔渣的矿相。结果表明:MnO能促进高炉渣形成大量的钙镁、钙铝黄长石,同时形成含锰的复杂化合物,这些物质能有效降低高熔渣的熔化性温度及黏度;当MnO质量分数在2.0%左右、1 400℃时,高炉渣黏度能达到0.564 Pa.s;Na2CO3能扩大炉渣的软熔区间,但对高炉渣的黏度影响不大。     

Evaluation of Al and Some of Its Alloys as Anode Materials vs γ-MnO2 as Cathode Material and Ore Produced γ-MnO2 vs Zn Anode in KOH Solution

In this study electrochemical performance of Al and some of its alloys (Al-Zn, Al-Mg and Al-Mn) anodes vs MnO2 cathode were carried out in alkaline solution. The results show that the Al-Zn alloy anode has the best cell capacity among the other alloys. Cell capacity values go in the order Al-Zn＞Al-Mg＞Al＞Al-Mn. This result is probably related to the nature of passive films formed on the surface of the alloys which examined by scanning electron microscopy (SEM). SEM morphologies of Al and its alloys showed coarse grains of passive films formed on the surface of these anode materials while Al-Mn morphology shows a needle-like structure.Electrolytic manganese dioxide (EMD) produced by electrodepositing on platinum anode from liquor resulting from reduction of low grade pyrolusite ore (β-MnO2) by sulfur slag was characterized as cathode in alkaline Zn-MnO2 batteries. Ore produced sample (EMD1) was performed well in comparison with EMD standard (EMD2) (commercial battery grade electrolytic manganese dioxide, TOSOH-Hellas GH-S). SEM morphology of Zn anode after cell reaction was carried out and showed that Zn anode has fine grains of passive film on its surface.     

钴锰矿矿浆电解试验研究

采用矿浆电解工艺处理高锰含钴物料,具有试剂消耗少,钴、锰浸出率高的优点,在阳极可以直接得到高品位的MnO2产品,在阴极得到高钴锰比的阴极液,大大降低后续钴溶液的除锰负荷。