钨掺杂对锂离子电池LiNiO2正极材料性能的影响

采用溶胶-凝胶法制备了钨掺杂镍酸锂正极材料(LiNi_(1-x)W_xO_2,x=1%、3%),研究了钨掺杂对LiNiO_2正极材料电化学性能的影响。结果表明,钨掺杂明显地改善了LiNiO_2的充放电循环性能,在100 mA·g~(-1)的电流密度和2.5～4.5 V电压范围的测试条件下,LiNi_(0.99)W_(0.01)O_2材料循环400次后的容量保持率为62.51%,而LiNiO_2在相同循环条件下的保持率仅为47.06%。同时,钨掺杂也提升了LiNiO_2的充放电倍率性能,掺杂材料在每一个倍率下放电比容量均高于未掺杂材料。     

LiCoO2梯度包覆LiNi0.96Co0.04O2电极材料的电化学性能

镍钴酸锂(LiNi0.8Co0.2O2)与目前商业用锂离子电池正极材料钴酸锂(LiCoO2)相比,具有成本低、实际比容量高和环境友好等优势。但LiNi0.8Co0.2O2的充放循环性能还有待提高,对其进行阳离子掺杂或表面修饰可以改善其电化学性能,这方面的研究已经成为热点。Fey等人[1]用溶胶凝胶法制     

Ti掺杂的MgH2和Mg2NiH4的放氢性能

以TiF₃和Ti(OBu-n)₄为催化剂, 研究了Ti离子掺杂对MgH₂和Mg₂NiH₄放氢性能的影响. 结果表明, 未掺杂的MgH₂起始放氢温度为420 ℃, 掺杂TiF₃和Ti(OBu-n)₄后分别降低到360和410 ℃; Mg₂NiH₄在掺杂TiF₃后放氢温度由230 ℃降低到220 ℃, 而掺杂Ti(OBu-n)₄后没有变化. 可见无论对MgH₂或Mg₂NiH₄, 在降低放氢温度方面TiF₃都明显优于Ti(OBu-n)₄. 另外, 研究还发现, TiF₃掺杂对MgH₂放氢动力学有显著的提高, 但对Mg₂NiH₄没有明显的提高. 结合XRD和FTIR的测试分析, 我们认为: 催化作用很大程度上取决于氢化物自身的晶体结构和催化剂的电子结构; 降低氢化物放氢温度和提高动力学性能的原因是催化剂与氢化物之间的相互作用削弱了氢化物中Mg—H或Ni—H键, 使得活泼的H…H原子对容易形成, 从而有利于H₂的释出.     

N掺杂对TiO2形态结构及光催化活性的影响

以TiCl₄为钛源,采用酸催化水解法合成TiO₂前驱体,在NH₃/N₂气氛下经不同温度处理制得浅黄色的N掺杂TiO₂(TON)光催化剂。以苯酚为模型物,考察了催化剂在紫外光区、可见光区及太阳下催化活性;采用DRS、XPS、XRD、FTIR、SEM及低温氮物理吸附对光催化剂的晶相结构、光谱特征和表面结构等进行表征。系统研究了N掺杂对TiO₂形态结构及光催化活性的影响。结果表明,掺杂N以阴离子形式进入TiO₂体相中置换晶格中的O,适宜温度下制得适量N掺杂的TON在紫外光区、可见光区及太阳光下均表现出较高的活性。N掺杂在TiO₂表面生成Ti-O-N键,形成新的能级结构,使催化剂的吸收红移至450～550 nm,诱发TiO₂可见光催化活性。同时高温下煅烧,N掺杂可抑制TiO₂晶粒生长,减缓TiO₂粒子间团聚,提高锐钛矿相向金红石相转变温度,减缓相转化速度。     

预氧化固气法合成LiNiO2的研究

LiNiO₂ was prepared by reaction of stoichiometric amounts of thoroughly-mixed LiOH·H₂O and preoxidation nanometer-scale Ni₃O₂(OH)₄ powders in O₂ at the temperature of 700℃ for 6h. The products were tested by XRD， XPS， SEM and electrochemistry methods. It was shown that product was LiNiO₂ single-phase， and the valence of nickel was +3; the average size of it was 40nm; its initial charge specific capacity is 168mAh·g^-1 and the coulomb efficiency is 90%; the second charge specific capacity is 160mAh·g^-1 and the coulomb efficiency is 96%.     

Bi2O3掺杂对Ag(Nb0.8Ta0.2)O3陶瓷结构和介电性能的影响

本文研究了Bi₂O₃掺杂对Ag(Nb_0.8Ta_0.2)O₃陶瓷的结构和介电性能的影响。X射线衍射(XRD)结果表明,Bi₂O₃的掺杂可以使陶瓷中Ag⁺被还原并析出,且银析出的量随Bi₂O₃掺杂量的增加而不断增加,这可能源自于Bi³⁺对Ag⁺的取代。在一定范围内增大Bi₂O₃掺杂量可提高Ag(Nb_0.8Ta_0.2)O₃陶瓷的室温介电常数,降低介电损耗,并使温度系数向负值方向移动。当Bi₂O₃的掺杂量约为3.5wt%时,样品具有较大的介电常数(ε=672)和较小的介电损耗(tanδ=7.3×10^-4)。     

Ru掺杂SnO2半导体固溶体的电子结构研究

运用基于密度泛函理论的第一性原理方法,建立了SnO₂以及不同比例Ru掺杂的SnO₂超胞模型,在对其进行几何优化后计算了Sn_1-xRu_xO₂(x=0,1/16,1/12,1/8,1/6,1/4,1/2)半导体的电子结构,并讨论了其晶格参数、电荷密度、能带结构和态密度(包括分态密度)等性质。结果表明,掺杂后,晶格参数随掺杂量的增加线性减小,与实验值的偏差在4%以内;掺杂后,在费米能级处可以提供更多的填充电子,使得电子跃迁至导带更容易,固溶体的导电性增强。为Sn_1-xRu_xO₂固溶体电极材料的发展和应用提供了理论基础。     

电化学沉积技术制备LiNiO2薄膜及表征

Well-crystallized LiNiO₂ thin films were prepared directly on nickel substrates in LiOH solution by constant current electrochemical deposition technique at 95 ℃. The as-prepared LiNiO₂ thin films were characterized by using XRD, SEM and XPS, and the results reveal that the as-prepared LiNiO₂ thin films are dense and uniform in surface and show hexagonal structure. The influence of processing parameters such as reaction temperature, duration, electrical current density as well as the concentration of LiOH solution on the structure and morphologies of as-prepared LiNiO₂ thin films were studied，and the preferable electrochemical processing conditions for preparing LiNiO₂ thin films were suggested.     

Ru掺杂SnO2半导体固溶体的电子结构研究

运用基于密度泛函理论的第一性原理方法,建立了SnO₂以及不同比例Ru掺杂的SnO₂超胞模型,在对其进行几何优化后计算了Sn_1-xRu_xO₂(x=0,1/16,1/12,1/8,1/6,1/4,1/2)半导体的电子结构,并讨论了其晶格参数、电荷密度、能带结构和态密度(包括分态密度)等性质。结果表明,掺杂后,晶格参数随掺杂量的增加线性减小,与实验值的偏差在4%以内;掺杂后,在费米能级处可以提供更多的填充电子,使得电子跃迁至导带更容易,固溶体的导电性增强。为Sn_1-xRu_xO₂固溶体电极材料的发展和应用提供了理论基础。     

掺杂铁酸盐的制备、结构及其催化分解CO2成C的性能

采用混合离子共沉淀法制备掺杂铁酸盐,采用XRD,TGA和H2-TPR等手段对其结构进行了表征,并考察了其直接催化分解CO2成C的性能.研究结果表明,用混合离子共沉淀法能够制备出纳米级晶粒、且为单一尖晶石结构的Cr3+掺杂的NiFe2O4.所掺杂的Cr3+进入NiFe2O4的晶格B位,极大地促进了NiFe2O4在还原氧化过程中结构的稳定性,分解CO2反应后,NiFe2O4的结构易恢复,从而明显地提高了其分解CO2成C反应的循环寿命(35次以上)和积炭量(25.3%).     

Charge density measurement and bonding character in LiNiO2

Accurate low-order structure factors of LiNiO₂ were measured by quantitative convergent-beam electron diffraction (QCBED), and then transformed into X-ray structure factors with Mott formula. Combining the structure factors measured by electron diffraction with the structure factors from X-ray diffraction measurements, accurate charge density maps based on a multipole model were obtained. The parameters of the bond critical points (BCP) were calculated for topological analyses. It shows that closed-shell interactions exist between Ni and O atoms, and that the Ni-O and Ni-Ni bonds exhibit some covalent character. The calculated d-orbital occupancies show the charge deficiency at e_g(e_g) orbital and charge surplus at e_g(t_2g) orbital. The remaining 29.12% population of e_g(e_g) is also an indication of covalent component in the Ni-O bond. The unusual small κ_defv value of the O atom is also discussed.     

First-principle investigation of Jahn-Teller distortion and topological analysis of chemical bonds in LiNiO2

First-principle GGA+U calculations were performed on the undistorted rhombohedral R3?m model, the collinear Jahn-Teller distorted monoclinic C2/m model, and six non-collinear Jahn-Teller distortion ordering models of LiNiO₂. The zigzag and C2/m models are found to be the most stable and the next most stable structural models, respectively. An energy gap appears for the C2/m and zigzag structures, whereas no energy gap appears for the R3?m structure. Topological analyses were performed on the R3?m, C2/m and zigzag models using the atoms-in-molecules theory and the electron localization function. The results show that the Ni-O interaction is the transit closed-shell interaction, in which the net electron transfer occurs from the Ni ion to the ligand O ions. The Ni-O bond possesses the σ dative bond character and is polarized toward the O ions. In the distorted structures, the bonding electrons around the oxygen atom are strongly polarized toward the long Ni-O bond.     

掺杂Fe2O3对吸附相反应技术制备TiO2的形貌和光催化性能的影响

利用吸附相反应技术制备得到了掺杂不同浓度的Fe₂O₃的TiO₂复合光催化剂。通过透射电子显微镜(TEM)、紫外可见光谱和X射线衍射(XRD)研究不同掺杂浓度对TiO₂形貌和结晶过程的影响,并利用3种波长光源下的甲基橙光降解实验考评了各个复合光催化剂的催化活性。结果表明,掺杂后复合光催化剂中Fe₂O₃分散性较好较均匀。在TiO₂紫外可见吸收光谱中由于Fe₂O₃的掺杂而出现了红移,而且随着掺杂浓度增加红移越来越明显,复合光催化剂的禁带宽度也越来越小。在焙烧过程中无定形Fe₂O₃或Fe³⁺进入了TiO₂的晶格结构,从而抑制了TiO₂的结晶过程。半导体禁带宽度的减少以及TiO₂结晶过程的抑制作用,都导致紫外光下复合光催化剂催化活性的降低。但Fe₂O₃的掺杂也使得复合光催化剂在可见光区出现了一定的光催化活性。     

钴掺杂镍酸锂的密度泛函计算及电化学性能

LiNiO₂ and LiNi_0.5Co_0.5O₂ cathodes for lithium-ion batteries were synthesized with co-precipitation method and their electrochemical property was characterized by Galvanostatic cycling. Meanwhile, plane-wave pseudopotential method base on density functional theory was used to calculate average cell voltage and the electronic structure of LiNiO₂ and LiNi_0.5Co_0.5O₂. The experimental and computational results showed that the average voltage of the cell decreased as Li-ion intercalated to the host cathode (discharge); The potential of Li_xNi_0.5Co_0.5O₂ was higher than that of Li_xNiO₂ (when 0.25≤x≤0.5). The calculations also indicated that the distortion of the NiO₆ octahedron in Li_xNiO₂ was decreased by Co-doped. During the Li-ion intercalates to the host cathode, the micro-structures of NiO₆ and CoO₆ in the Li_xNi_0.5Co_0.5O₂ were mutually stabilized, the Jahn-Teller effect was weakened and the electrochemical properties of the materials were enhanced.     

MgAl2O4尖晶石对锂离子电池正极材料LiMn2O4的循环性能影响研究

MgAl₂O₄ spinel doping into cathode materials LiMn₂O₄ was used to improve the cyclic performance of the cathode. X-ray analysis results showed, when MgAl₂O₄ precursors were mixed with LiMn₂O₄ and sintered at 770 ℃ for 12 hour, MgAl₂O₄-LiMn₂O₄ mulriple spinel with the same physical characteristics as pure LiMn₂O₄ were synthesized. The electro-chemical performance testing showed, comparing with pure LiMn₂O₄, the first charge-discharge capacity of doping materials somewhat reduced, but the cyclic performance improved. The mechanism for doping material was also discussed.     

溶剂热法合成Fe-CeO2与N-Fe-CeO2纳米粉体及其光催化性能

采用溶剂热法合成了不同Fe掺杂含量的Fe-CeO_2纳米粉体及不同氮源掺杂的N-10%Fe-CeO_2(n_(Fe)/(n_(Fe)+n_(Ce))=10%)纳米粉体。利用TEM、XRD、XPS、Raman和UV-Vis等技术对其微观结构与形貌进行了表征,并通过降解亚甲基蓝溶液对其光催化性能进行了研究。结果表明,Fe掺杂可以提高CeO_2的光催化性能,以10%Fe-CeO_2催化效率最高,对亚甲基蓝的降解率从纯CeO_2的67%提高到95%。而N的掺杂可调节10%Fe-CeO_2催化性能。以浓氨水为氮源的N-10%Fe-CeO_2(NH_3·H_2O-N-10%Fe-CeO_2)的降解率可进一步提高到97%,并且具有较好的稳定性,经5次循环使用,对亚甲基蓝的光催化降解率仍高达89%。CeO_2催化活性的提高主要由于掺杂Fe和N改变了CeO_2的晶体结构与能带结构,促进了光生电子与空穴的产生与催化反应。