Li嵌入Mg2Ge的反应次序和电子结构变化

Mg2Ge有望成为新的锂离子电池负极材料.使用基于平面波展开的第一性原理赝势法,计算并得到了Li嵌入Mg2Ge负极材料时的反应次序.Li首先占据其中的间隙位置,占满间隙位置后随着嵌Li量的进一步增加,Li将逐步替位Mg2Ge中一半的Mg位置,直到生成Li2MgGe.计算结果表明,在整个嵌Li过程中主体材料的体积先膨胀后收缩.体积胀缩量很大,这是导致Mg2Ge作为锂离子电池电极材料循环性能较差的重要原因.对材料电子结构的分析表明,随着Li嵌入量的增加,主体材料发生了从半导体性到金属性、又到半金属性的转化.     

Sb、Ce掺杂Mg2Ge的第一性原理研究

此文用基于密度泛函理论(DFT)的第一性原理赝势平面波方法系统的计算了Sb、Ce掺杂Mg₂Ge的能带结构、态密度以及光学性质,获得了Mg₂Ge掺杂Sb后,费米面进入导带,呈现n型导电;Mg₂Ge掺杂Ce后,上自旋电子在费米能级附近处的价带和导带有一部分重叠,呈现半金属特性,进入导带电子数目增多,导电性增强. Sb、Ce掺杂Mg₂Ge后,其主要吸收峰都小于未掺杂Mg₂Ge,在可见光区域的透过率增大;Sb掺入后,在能量低于2.6 eV反射谱出现红移,Ce掺入后Mg₂Ge的吸收范围明显宽于本征Mg₂Ge;掺杂改善了Mg₂Ge对红外光子的吸收等有益结果.     

锂离子电池负极材料CuSn的Li嵌入性质的研究

使用基于混合基表示的第一原理赝势法，研究了锂离子电池非碳类负极材料CuSn的Li嵌入时的形成能以及相应的电子结构.还给出了Li嵌入时的体积变化，能带结构、电子态密度以及电荷密度分布等性质, 并讨论了CuSn作为负极材料的特点.计算发现，Cu-Sn化合物在闪锌矿结构时，Li嵌入主体材料时的嵌入形成能大致在3.5eV附近. 关键词： 锂离子电池 负极材料 CuSn 电子结构     

InSb的锂嵌入形成能第一原理计算

InSb材料在近来的锂离子电池负极材料研究中受到了重视.使用基于局域密度泛函理论的第一原理赝势法，计算了锂离子电池非碳类负极材料InSb各种锂嵌入情况时的形成能以及相应的电子结构.讨论了锂嵌入时的体积变化、能带结构、电子态密度以及电荷分布等性质.计算发现，闪锌矿结构的InSb材料，锂嵌入到主体材料的间隙位置时的形成能平均每个锂原子都在2.2eV左右. 关键词： InSb 锂嵌入形成能 电子结构 第一原理计算     

石墨/Li（Ni1/3Co1/3Mn1/3）O2电池充放电过程中电极材料的XRD研究

利用XRD系统地研究了石墨/Li（Ni_1/3Co_1/3Mn_1/3）O₂ 18650型锂离子电池充放电过程中正负极活性材料的晶体结构和微结构的变化.已观测到,由于Li原子的脱嵌,使得LiMO₂点阵参数a缩小,c增大,微应变增大,衍射强度比I₁₀₄/I₁₀₁和I₀₁₂/I₁₀₁降低;此外,由于Li原子的嵌入,2H-石墨的点阵参数a和c,以及微应变ε和堆垛无序度P都增加.同时,讨论了活性材料Li（Ni_1/3Co_1/3Mn_1/3）O₂和石墨在电池充放电过程中的嵌脱锂的物理机理.在充电时,正极Li（Ni_1/3Co_1/3Mn_1/3）O₂中处于（000）位的Li原子优先脱离晶体点阵,继后才是位于（2/3 1/3 1/3）和（1/3 2/3 2/3）位的Li原子离开点阵.锂嵌入石墨,优先进入碳原子六方网格面间的间隙位置,当负极的堆垛无序度达到一定值后,3R相逐渐析出.当电池满充或过充时,在六方石墨中形成LiC₁₂和LiC₆相.放电时,与上述过程相反,但并非是完全可逆的. 关键词： 锂离子电池 微结构 X射线衍射 嵌脱锂物理机理     

Cd、Sr掺杂Mg2Ge电子结构和光学性质的第一性原理研究

此文用基于密度泛函理论(DFT)的第一性原理计算方法,分别研究了本征、掺Cd、掺Sr的Mg₂Ge的能带结构、电子态密度和光学性质.研究结果表明,本征Mg₂Ge是一种间接带隙半导体,带隙值为0.228eV.Sr的掺入使其变成带隙为0.591 eV的直接带隙半导体,Cd掺杂Mg₂Ge后表现出半金属性质.掺杂后的主要吸收峰减小,吸收谱范围增加.在可见光能量范围内,掺杂的Mg₂Ge有更低的反射率,对可见光的利用率增强.此外,掺杂还提高了高能区的光电导率.     

Si-Li合金嵌锂性能和弹性性能的第一性原理计算

采用基于密度泛函理论的第一性原理平面波赝势方法,计算了锂离子电池硅负极材料在嵌Li过程中形成Li_xSi合金相(0≤x≤4.4)的形成能、嵌Li电位、晶体结构、电子结构和弹性性能.计算结果表明,随着嵌Li量的增加,Li_xSi合金体系总量能逐渐降低,Li_xSi合金相的形成能均为负值,表明硅负极材料的嵌Li反应在热力学可以自发进行;随着嵌Li量的增加,Li_xSi合金相的平均嵌Li电位逐渐降低,体积膨胀率逐渐增大,这与实验测得的结果具有良好的一致性.Li_xSi合金相在费米能级附近的电子主要由Si原子的p电子和Li原子的s电子共同贡献,Li_xSi合金相的费米能态密度随着嵌Li量的增加在整体上呈现增大趋势,电子导电性增强.随着嵌Li量的增加,Li_xSi合金相的体积模量(B)、剪切模量(G)和杨氏模量(E)逐渐降低,G/B值表明Li_xSi合金相均呈脆性,导致硅在嵌Li过程容易发生脆性结构破坏.     

Si-Li合金相嵌锂性能和弹性性能的第一性原理计算

采用基于密度泛函理论的第一性原理平面波赝势方法,计算了锂离子电池硅负极材料在嵌Li过程中形成LixSi合金相(0≤x≤4.4)的形成能、嵌Li电位、晶体结构、电子结构和弹性性能。计算结果表明,随着嵌Li量的增加,LixSi合金体系总量能逐渐降低,LixSi合金相的形成能均为负值,表明硅负极材料的嵌Li反应在热力学可以自发进行;随着嵌Li量的增加,LixSi合金相的平均嵌Li电位逐渐降低,体积膨胀率逐渐增大,这与实验测得的结果具有良好的一致性。LixSi合金相在费米能级附近的电子主要由Si原子的p电子和Li原子的s电子共同贡献,LixSi合金相的费米能态密度随着嵌Li量的增加在整体上呈现增大趋势,电子导电性增强。随着嵌Li量的增加,LixSi合金相的体积模量(B)、剪切模量(G)和杨氏模量(E)逐渐降低,G/B值表明LixSi合金相均呈脆性,导致硅在嵌Li过程容易发生脆性结构破坏。     

Si-Li合金相嵌锂性能和弹性性能的第一性原理计算

采用基于密度泛函理论的第一性原理平面波赝势方法,计算了锂离子电池硅负极材料在嵌Li过程中形成LixSi合金相(0≤x≤4.4)的形成能、嵌Li电位、晶体结构、电子结构和弹性性能。计算结果表明,随着嵌Li量的增加,LixSi合金体系总量能逐渐降低,LixSi合金相的形成能均为负值,表明硅负极材料的嵌Li反应在热力学可以自发进行;随着嵌Li量的增加,LixSi合金相的平均嵌Li电位逐渐降低,体积膨胀率逐渐增大,这与实验测得的结果具有良好的一致性。LixSi合金相在费米能级附近的电子主要由Si原子的p电子和Li原子的s电子共同贡献,LixSi合金相的费米能态密度随着嵌Li量的增加在整体上呈现增大趋势,电子导电性增强。随着嵌Li量的增加,LixSi合金相的体积模量(B)、剪切模量(G)和杨氏模量(E)逐渐降低,G/B值表明LixSi合金相均呈脆性,导致硅在嵌Li过程容易发生脆性结构破坏。     

Sn3InSb4合金嵌Li性能的第一性原理研究

采用第一性原理超软赝势平面波方法计算了Sn₃InSb₄的嵌Li性能,得到各种嵌Li相的嵌Li形成能、理论质量比容量、体积膨胀率、能带结构、态密度和差分电荷密度等.从能量角度分析,Li在嵌入时,优先占据晶胞的四面体间隙位置,然后逐步挤出处于节点位置的Sn原子和In原子.在嵌Li过程中,材料表现出较大的体积膨胀率(11.74%-43.40%),这是导致Sn₃InSb₄作为Li离子电极材料循环性能差的重要原因.态密度计算表明,体系的导电性能首先随嵌Li量的增加而增加,当所有的间隙位置被Li填满,发生Sn的替换反应时,富Li态合金相的导电性反而下降.     

Lithium insertion into Co3O4: A preliminary investigation

Lithium has been inserted into the spinel Co₃O₄ both chemically and electrochemically. During lithiation the tetrahedral A-site Co²⁺ cations are displaced into neighbouring empty octahedral sites: the incoming Li⁺ ions occupy the remaining interstitial octahedra of the spinel structure to produce the partially ordered rocksalt compound LiCo₃O₄. The octahedral B-site cations of the A[B₂]X₄ spinel are unperturbed by this reaction: the oxide lattice expands by 8.6%. Lithium analyses and powder X-ray diffraction spectra indicate that further lithiation is possible. However, it is demonstrated that a fast lithiation in excess of LiCo₃O₄ is followed by a slow extrusion of B-site cobalt at 50°C until all the Li on the 8a sites has moved to the octahedral vacancies thus created.     

石英玻璃衬底上纤锌矿Mg0.25Zn0.75O薄膜的结构及光学性能

Mg_xZn_1-xO材料是一种新型光电功能材料.采用溶胶凝胶法在石英玻璃上制备了Mg_0.25Zn_0.75O薄膜,理论结合实验研究了Mg_0.25Zn_0.75O薄膜的结构和光学性能.研究表明,石英玻璃衬底上Mg_0.25Zn_0.75O薄膜呈六方纤锌矿结构,薄膜均匀,平均粒径约为20nm.吸收光谱表明吸收带边始于3 关键词： 0.25Zn_0.75O薄膜')" href="#">Mg_0.25Zn_0.75O薄膜 溶胶凝胶法 石英玻璃衬底 紫外发光     

H2在MgO团簇吸附的从头计算研究

根据最稳定幻数MgO团簇的结构特点,对H₂在岩盐和管状结构(MgO)_9,12表面的吸附性质进行了从头计算研究.结果表明H₂可以在处于团簇不同位置的Mg正离子或氧负离子上发生物理吸附;在Mg离子上H₂以侧位方式吸附并向Mg转移电子,在O离子上H₂以端位方式吸附并被明显极化.吸附的稳定性主要依赖于吸附离子的位置即配位数,Mg/O离子的配位数越低则吸附越强;在配位数相同时,H₂在M 关键词： 团簇 MgO 2吸附')" href="#">H₂吸附 DFT     

In situ 119Sn Mössbauer spectroscopy used to study lithium insertion in c-Mg2Sn

The electrochemical reactions of Li with c-Mg₂Sn have been investigated by in situ Mössbauer spectroscopy of ¹¹⁹Sn and X-ray diffraction. The lithiation transforms initially c-Mg₂Sn part into Li _x Mg₂Sn alloy (x?2MgSn ternary alloy. In situ Mössbauer spectroscopy provides valuable information on local environment of tin and swelling behavior and cracking of the particles during discharge and charge processes.     

Substitutional site of Co2+ ion in RbMgF3 crystal

The spin-Hamiltonian (SH) parameters (g factors g _//, g _⊥ and hyperfine structure constants A _//, A _⊥) for Co²⁺ ions at the trigonal Mg²⁺ (I) and Mg²⁺ (II) sites of RbMgF₃ crystal are calculated from the second-order perturbation formulas based on the cluster approach for 3d⁷ ions in trigonal symmetry. From the calculations, it is found that the calculated SH parameters for Co²⁺ ion at the Mg²⁺ (I) site are in poor agreement with, but those for Co²⁺ at the Mg²⁺ (II) site are close to, the experimental values. Therefore, we suggest that Co²⁺ in RbMgF₃ crystal substitutes for Mg²⁺ (II) ion. The results are discussed.     

Antisite defects and Mg doping in LiFePO<Subscript>4</Subscript>: a first-principles investigation

Atomic and electronic structures of LiFePO₄ with the antisite defect and Mg doping at Li and Fe sites have been investigated using first-principles density-functional theory with the on-site Coulomb interaction taken into account. It is demonstrated that the most favorable antisite defect type is the exchange defect, in which Li and Fe ions exchange positions. The resultant longer Fe–O bond and narrower band gap drop a hint that the electronic and ionic transport properties may be improved. For the case of Mg doping, Mg is preferentially doped at the Fe site instead of the Li site to form a new LiFe_1−y Mg _y PO₄ solid solution, leading to a higher ionic conductivity. Moreover, the dependence of the electrochemical properties on the concentration of Mg dopant has also been discussed.     

Ge Nanoparticles Encapsulated in Interconnected Hollow Carbon Boxes as Anodes for Sodium Ion and Lithium Ion Batteries with Enhanced Electrochemical Performance

A carbothermal reaction route to Ge nanoparticle homogeneously encapsulated hollow carbon boxes from NH₄H₃Ge₂O₆/resorcinol formaldehyde precursors is designed, using NH₄H₃Ge₂O₆ as a Ge precursor from commercial GeO₂ and NH₄OH. The Ge/C hybrid anode for sodium ion battery displays a higher Na⁺ storage capacity of 346 mA h g^?1 after 500 cycles at a current density of 100 mA h g^?1, almost approaching the theoretical capacity of Ge. Furthermore, Ge/C anode shows significantly improved electrochemical performance for Li⁺ storage, showing a higher initial Coulombic efficiency of 85.1% and a superior reversible capacity of 1336 mA h g^?1 at a high current density of 200 mA g^?1 after 150 cycles. An excellent rate capability with a capacity of 825 mA h g^?1 at a current density of 4.0 A g^?1 can be obtained based on Ge/C anodes. The enhanced electrochemical performance can be attributed to the unique microstructures of Ge/C hybrid anode. The internal void space of hollow carbon boxes can accommodate the volume expansion of Ge during lithiation or sodiation process, thus preserving the structural integrity of electrode material. The interconnected carbon shell can increase the electronic conductivity of the electrode, resulting in the high rate capability and cycling stability.     

Tuning electrochemical potential of LiCoO2 with cation substitution: first-principles predictions and electronic origin

With a goal to improve the performance of LiCoO₂ as a cathode material in Li-ion batteries, we simulate substitution of various elements (X = Be, Mg, Al, Ga, Si and Ti) for Co using first-principles density functional theory and predict changes in its electrochemical potential. While the electrochemical potential of LiCoO₂ is enhanced with substitution of Be, Mg, Al and Ga for Co, an opposite effect is predicted of Si and Ti substitution. We determine the electronic origin of these changes in electrochemical potential using (a) Bader method of topological analysis of charge density, (b) partial density of electronic states to estimate oxidation states of metal and oxygen, and charge re-distribution upon lithiation. We find that the distribution of electronic charge donated by Li is influenced by the nature of the X–O bond. A larger electron transfer to O (in XO₆ octahedron) upon lithiation leads to stronger Li intercalation and thereby higher electrochemical voltage. Our findings provide a platform for a rational design of cathode materials in Li batteries with enhanced voltage.     

Lithium insertion into nanometer-sized rutile-type TixSn1 − xO2 solid solutions

The electrochemical properties of rutile-type Ti_xSn_1?xO₂ solid solutions (x = 0–1.0) as an anode for a lithium–ion battery were investigated using nanosized crystals prepared by an aqueous solution process. The reduction of the crystal size to nanoscale allowed a smooth lithium insertion into the rutile framework at room temperature. The lithium-insertion behavior of TiO₂, SnO₂, and the solid solutions was evaluated without any structural change of the rutile-type crystal structure in the potential range of 1.2–3.5 V (versus Li/Li⁺). The interstitial spaces for lithium ions were found to be derived from the crystal structure of the rutile framework and independent of the metal species.