MnO_2掺杂对NiZn铁氧体磁性能的影响

采用传统陶瓷工艺制备了MnO2掺杂Ni0.88Zn0.12Fe1.98O4铁氧体材料。实验发现,较高的烧结温度有助于NiZn铁氧体磁导率的提高,但过高和过低烧结温度都不利于材料品质因数的提高,从降低损耗的角度考虑,最佳烧结温度为1220℃。当NiZn铁氧体中MnO2掺杂量为1.5%时,铁氧体晶粒生长均匀,平均晶粒尺寸适中,能获得最高的品质因数,过低或过高的掺杂量都不利于损耗的降低。铁氧体饱和磁感应强度随MnO2掺杂量的增多先上升,后下降,但总体的变化程度都不大。而矫顽力则随掺杂量的增多持续下降。相关的影响机制在文中作了详细的讨论。

MnO_2掺杂NiFe_2O_4的初期烧结动力学特征

借助热膨胀仪,采用恒升温速率法研究了升温速率和添加剂MnO_2对镍铁尖晶石的初期烧结行为影响。结果表明,较低的升温速率可以使样品获得较大的线收缩,添加MnO_2,可以降低样品的开始形成烧结颈温度,加快镍铁尖晶石的致密化过程。添加MnO_2后各体系的初期烧结均由晶界扩散机制转变成了体积扩散机制,烧结过程的表观活化能均大幅下降,其中添加1.0%(质量分数)MnO_2的体系下降最为明显,从未添加时的813.9kJ/mol降到了441.9kJ/mol。

MnO2掺杂的MmNi3.2Al0.2Mn0.6Co1.0对NaBH4氧化的电催化性能

通过测试线性扫描伏安曲线研究了MnNi3.2Al0.2Mn0.6Co1.0（Mm为混合稀土）经KOH处理和MnO2掺杂对催化NaBH4电氧化性能的影响．发现NaBH4在经KOH处理后的合金上峰电流达到50mA／cm^2．若再进行MnO2掺杂，其电催化活性会进一步提高，当掺杂MnO2的质量分数为10％时，MmNi3.2Al0.2Mn0.6Co1.0对NaBH4电氧化的峰电位和峰电流密度分别为-0．45V和126mA／cm2，峰电流密度为只经过KOH处理的合金的2．5倍，是未经过任何处理的合金的9倍．

MnO_2掺杂对BiFeO_3-PbTiO_3-Bi(Zn_(1/2)Ti_(1/2))O_3-PbZrO_3陶瓷组织与性能的影响

采用固相烧结法制备MnO2掺杂的BiFeO3-PbTiO3-Bi（Zn1/2Ti1/2）O3-PbZrO3（BF-PT-BZT-PZ）压电陶瓷,研究了不同MnO2掺杂量对材料结构及压电介电性能的影响。实验结果表明,适量的MnO2掺杂,不仅能使晶粒长大,提高晶界强度,而且可以改善材料的介电压电性能。当MnO2掺杂量为0.1mol%时,880℃（5h）烧结的陶瓷样品性能参数为：d33=97pC/N,kp=0.29,kt=0.37,εr=390,tanδ~0.02。

MnO_2掺杂Bi(Mg_(1/2)Ti_(1/2))O_3-0.38PbTiO_3陶瓷的介电压电性能研究

研究了不同MnO2含量掺杂对Bi(Mg1/2Ti1/2)O3-0.38PbTiO3压电陶瓷结构和介电压电性能的影响。随着MnO2掺杂量增加,试样的三方相结构特征越来越明显,压电性能明显下降,居里温度附近介电常数εm明显降低;同时,当测试温度大于100℃后,MnO2掺杂试样介电损耗整体明显降低,说明适量的MnO2掺杂能提高BMT-0.38PT陶瓷在高温下的性能稳定性。

MnO_2掺杂对Sr_(1.95)Ca_(0.05)NaNb_5O_(15)无铅压电陶瓷微观结构及电学性能的影响

采用固相反应法制备了MnO2掺杂Sr1.95Ca0.05NaNb5O15+ywt%MnO2(SCNNM)无铅压电陶瓷。研究了MnO2掺杂对SCNNM陶瓷显微结构及电学性能的影响。结果表明:当y≤0.7时,SCNNM陶瓷为单一的四方钨青铜结构,当y≥1.0时有第二相生成;少量MnO2掺杂能有效降低烧结温度,促进晶粒长大,显著提高SCNNM陶瓷的介电、压电性能,降低矫顽场和居里温度,当y>0.7时,陶瓷烧结恶化,性能降低。当y=0.5时,SCNNM陶瓷具有较好的介电、压电和铁电性能:介电系数εr=2123,介电损耗tanδ=0.038,平面伸缩振动机电耦合系数Kp=13.4%,厚度伸缩振动机电耦合系数Kt=36.5%,矫顽场Ec=12.68 kV/cm,剩余极化强度Pr=4.76μC/cm2,压电系数d33=190 pC/N,机械品质引因数Qm=1455,居里温度Tc=260oC。

可充碱锰电池MnO_2正极添加剂的研究进展

结合近年来可充碱锰(RAM)电池的发展,综述了碱性MnO2正极材料方面的掺杂改性研究;简要介绍了Bi、Ti和Pb等掺杂的MnO2正极的电化学性能及掺杂机理;展望了RAM电池的发展前景。

MnCO_3/MnO_2共掺杂对(Ba,La,Ca)TiO_3基陶瓷材料介电性能的影响

采用水热法制备了Ba0.7La0.2Ca0.1TiO3陶瓷材料,研究了MnCO3/MnO2共掺杂对陶瓷材料介电性能的影响及相关的影响规律。随着nMnCO3/nMnO2的增加,材料的介电常数开始增大随后减小,而介电损耗先减小再增大后开始波动,击穿场强先增大后减小。当nMnCO3/nMnO2为3∶1时介电常数最大,得到了介电常数(εr)为4661,介质损耗(tanδ)为0.0165,击穿场强(Eb)为12.58kV/mm,绝缘电阻(R)为3.7×1013Ω的高介电低损耗陶瓷粉体材料。最后探讨了MnCO3/MnO2共掺杂改性的有关机理。

Microstructure and magnetic properties of Ni-Zn ferrites doped with MnO_2

To improve the performance of Ni-Zn ferrites for power field use,the influence of MnO2 additive on the properties of Ni-Zn ferrites was investigated by the conventional powder metallurgy.The results show that MnO2 does not form a visible second phase in the doping mass fraction range of（0-2.0%）.The average grain size,sintering density and real permeability gradually decrease with the increase of the MnO2 content.And the DC resistivity continuously increases with the increase of MnO2 content.The saturation magnetization（magnetic moment in unit mass） first increases slightly when mass fraction of MnO2 is less than 0.4% MnO2,and then gradually decreases with increasing the MnO2 mass fraction due to the exchange interaction of the cations.When the excitation frequency is less than 1 MHz,the power loss（Pcv） continuously increases with increasing the MnO2 content due to the decrease of average grain size.However,when the excitation frequency exceeds 1 MHz,eddy current loss gradually becomes the predominant contribution to Pcv.And the sample with a higher resistivity favors a lower Pcv,except for the sample with 2.0% MnO2.The sample without additive has the best Pcv when worked at frequencies less than 1 MHz;and the sample with 1.6% MnO2 additive has the best Pcv when worked at frequencies higher than 1 MHz.

MnO_2和Co_2Y联合添加对Ni-Zn铁氧体磁损耗的影响

采用传统陶瓷工艺制备了MnO2和Co2Y联合添加的Ni0.8Zn0.2Fe2O4铁氧体材料,研究了材料的结构与功耗。结果表明,随着MnO2添加量的增多,Ni-Zn铁氧体的损耗经历增大-减小-增大的变化,最佳添加量为1.2wt%。进一步研究表明,与不添加MnO2的材料相比,最佳添加时铁氧体的磁滞损耗系数与涡流损耗系数都减小,但剩余损耗系数有所增大。

Effect of Ni-doping on electrochemical capacitance of MnO_2 electrode materials

Mn/Ni composite oxides as active electrode materials for supercapacitors were prepared by solid-state reaction through the reduction of KMnO4 with manganese acetate and nickel acetate at low temperature. The products were characterized by X-ray diffractometry(XRD) and transmission electron microscopy(TEM). The electrochemical characterizations were performed by cyclic voltammetry (CV) and constant current charge-discharge in a three-electrode system. The effects of different potential windows, scan rates, and cycle numbers on the capacitance behavior of Mn0.8Ni0.2Ox composite oxide were also investigated. The results show that the composite oxides are of nano-size and amorphous structure. With increasing the molar ratio of Ni, the specific capacitance goes through a maximum at molar fraction of Ni of 20%. The specific capacitance of Mn0.8Ni0.2Ox composite oxide is 194.5 F/g at constant current discharge of 5 mA.

MnO2对(Zr0.8Sn0.2)Ti1+δO4+2δ微波介质陶瓷的结构与介电性能的影响

研究掺杂0-0.2wt.%Mn O2的(Zr0.8Sn0.2)Ti1+δO4+2δ(δ=-0.2-0.2)微波介质陶瓷(ZST)的结构和介电性能。固相法制备陶瓷粉料,采用XRD和SEM手段分析陶瓷的晶相和显微结构,并用平行板谐振器法测试样品的微波介电性能。结果表明,未掺杂Mn O2的(Zr0.8Sn0.2)Ti1+δO4+2δ(δ≠0)存在第二相,且(Zr0.8Sn0.2)Ti1.2O4.8陶瓷的微波介电性能最差;掺杂0.2wt.%Mn O2极大地改善了(Zr0.8Sn0.2)Ti1.2O4.8陶瓷的介电性能,Q×f从25.40 THz升高至43.63 THz,频率温度系数从39.0 ppm/℃降至16.8 ppm/℃。

二氧化锰掺杂氧化碲粉体的制备及微观结构表征研究

用球磨法与液相沉淀法两种方法分别制备了MnO_2掺杂TeO_2超细粉体,并通过X射线衍射(XRD)、扫描电子显微镜(SEM)和X射线激发发射光谱(XEL)对样品的物相组成、形貌等微观结构和发光性能进行了测试表征。结果表明,通过增加球磨混合时间和改变球磨介质,用球磨法可制得3～4μm的TcO_2粉体。相比球磨法,用液相沉淀法可制得更加均匀和细小的超细粉体,所得粉体的平均颗粒尺寸约为1μm,其发光强度更高。