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1.
系统研究了电解质锂盐对磷酸铁锂电极高温性能的影响, 并探讨了相关的作用机理. 差示扫描量热仪测试显示, 与LiPF6相比, 二(三氟甲基磺酰)亚胺锂(LiTFSI)和LiBF4具有对水份稳定且热稳定性好的优点, 更适合高温条件下使用. 应用等离子体发射光谱考察LiFePO4在55 ℃和不同电解液体系中铁离子溶出程度, 结果表明, 在LiTFSI和无氟锂盐电解液中LiFePO4的铁很少溶出, 而在LiPF6电解液中却溶出严重, 且FePO4的铁溶出量高于LiFePO4. 循环伏安和光学显微镜测试结果显示少量LiBF4的加入能有效抑制LiTFSI对集流体铝箔的腐蚀. 以LiTFSI和LiBF4作为混合锂盐配成的电解液能显著改善LiFePO4/Li电池的高温电化学性能, 在55 ℃和1 C倍率下循环40次后放电比容量达147.7 mAh/g. 相似文献
2.
制备并表征了双(三氟乙氧基磺酰)亚胺{[N(SO2OCH2CF3)2]-,TFESI-}和双(六氟异丙氧基磺酰)亚胺({N[SO2OCH(CF3)2]2}-,HFPSI-)2个阴离子的10种碱金属盐,并采用示差扫描量热仪(DSC)和热重分析仪(TGA)研究了其相变行为和热稳定性.测试了LiTFESI和LiHFPSI与碳酸乙烯酯(EC)/碳酸甲乙酯(EMC)(3∶7,体积比)组成的电解液的电导率、氧化电位及对铝箔的腐蚀性.结果表明,所制备的碱金属盐均具有较高的纯度和热分解温度(200℃)及较低的熔点(117~211℃);LiTFESI-EC/EMC和LiHFPSIEC/EMC电解液均具有较高的电导率和氧化电位,并对铝箔具有良好的钝化性能,有可能作为锂离子电池的导电盐或添加剂. 相似文献
3.
通过简单、易于工业化的重结晶方法制备了高纯1-甲基-1-乙基吡咯烷鎓双(三氟甲基磺酰)亚胺盐(P12TFSI)塑晶化合物. 在此化合物中加入30% (摩尔分数, x)双(氟磺酰)亚胺锂(LiFSI)后, 得到P12TFSI/LiFSI 塑晶基离子液体. 采用循环伏安法、恒电压极化法及恒电流充放电法等电化学方法考察了该离子液体的电化学窗口、铝箔集流体的腐蚀性及电池性能. 结果表明, 该离子液体电解质具有5.00 V的电化学窗口, 室温离子电导率达到0.92 mS·cm-1, 且不腐蚀Al 集流体. 以该塑晶离子液体作为电解液组装的实验电池LiCoO2/Li 表现出良好的充放电特性及循环性能, 在较低倍率下能够和使用碳酸酯类电解液组装的实验电池的性能相媲美. 在4.50 V高电压下, 循环20周后, 容量仍能保持在175 mAh·g-1, 容量保持率为95.1%. 这些结果说明该离子液体在高性能锂二次电池中具有良好的应用前景. 相似文献
4.
采用分子动力学模拟方法, 研究了新型绝缘介质三氟甲基磺酰氟(CF3SO2F)的理化特性, 为高压电气设备应用CF3SO2F替代SF6气体提供了理论依据. 基于量子化学计算的分子结构、 内转动、 偶极矩和振动频率等优化设计了mPCFF力场模型, 计算了243~323 K温度范围内CF3SO2F的各种气-液相平衡性质(饱和蒸汽压、 密度、 热容、 蒸发焓和临界参数等)与关键输运特性(扩散系数、 介电常数、 黏度和热导率等)基础参数, 并考察了CF3SO2F与N2或CO2形成混合气体的理化特性. 通过对比SF6以及C4/CO2混合环保绝缘气体, 针对混合比、 液化温度、 扩散和热导等因素提出了CF3SO2F的电气设备应用建议. 相似文献
5.
制备了1种高纯度的新型锂盐三氟甲基三氟硼酸锂(Li[CF3BF3]),通过核磁共振(NMR)、元素分析(EA)及离子色谱(IC)对其结构进行表征和杂质分析.采取示差扫描量热(DSC)、交流阻抗(EIS)、循环伏安(CV)和扫描电镜(SEM)等方法研究了1 mol/L Li[CF3BF3]-EC/EMC/DMC(体积比5∶3∶2)电解液的物化和电化学性质.结果表明,Li[CF3BF3]基电解液的电导率和Li+迁移数远高于LiBF4,氧化电位高达5.91 V(vs.Li+/Li),在镍电极表面能观察到可逆的锂沉积-溶出过程,并对Al箔表现出优良的钝化性能.研究了Li[CF3BF3]基电解液的电导率与温度和浓度、黏度与浓度的变化规律,以及一系列浓度电解液的相变规律.Li/C半电池测试结果表明,—CF3取代LiBF4的1个F原子后,其衍生产物Li[CF3BF3]明显改善了电解液与人造石墨的相容性. 相似文献
6.
提高电压是提高锂离子电池比能量的重要途径之一。例如,LiNi0.5Mn1.5O4(4.7 V)、LiNiPO4(5.1 V)和富锂锰基等电极材料在较高的充电截止电压下表现出较高的能量密度和较低的成本,具有很好的应用前景。另外,提高LiCoO2和三元电池体系的充电截止电压是提升电池能量密度的简单有效措施。但是,当电池充电截止电压提高时,不仅会造成电解液在正极/电解液界面的氧化分解,还会加速正极中金属阳离子在电解液中的溶解,造成电池循环性能和安全性下降。采用不同的正极界面修饰用电解液添加剂,既可以有效钝化正极/电解液界面,抑制电解液的分解,还可以有效抑制正极结构的破坏。本文从添加剂的分子结构出发,介绍了磺酸酯、硼酸酯、磷酸酯、氟代碳酸酯、腈类、酸酐和锂盐等添加剂在正极界面的相关研究成果,并对不同添加剂的作用机理进行了详细的解释和归纳;另外,介绍了添加剂的联用技术在不同电池体系中的最新研究成果;最后,对新型正极界面修饰用电解液添加剂的开发进行了展望。 相似文献
7.
二氟二草酸硼酸锂对LiFePO4/石墨电池高温性能的影响 总被引:2,自引:0,他引:2
研究了二氟二草酸硼酸锂(LiODFB)作为锂盐加入到碳酸丙烯酯(PC)+碳酸乙烯酯(EC)+碳酸甲乙酯(EMC)(质量比为1:1:3)混合溶剂中对LiFePO4/石墨电池高温(60 ℃)循环性能的影响. 用线性扫描伏安法(LSV)测试了电解液的电化学窗口. 通过等离子发射光谱(ICP)和能量散射光谱(EDS)对LiFePO4材料高温条件下在不同电解液中的稳定性进行了研究; 并用扫描电镜(SEM)和电化学交流阻抗谱(EIS)分析了石墨负极表面的固体电解液相界面(SEI)膜的热稳定性. 结果表明: 一方面LiODFB基电解液能抑制LiFePO4材料在高温条件下Fe(II)的溶解, 防止溶解的Fe(II)在石墨上还原, 有效地降低电池阻抗; 另一方面, 在LiODFB基电解液中形成的石墨负极表面SEI膜具有更好的热稳定性, 能显著提高LiFePO4/石墨电池的高温循环性能. 相似文献
8.
采用简单的溶液浇铸法制备出由双(三氟甲基磺酰)亚胺钠(NaTFSI)/聚氧乙烯(PEO)构筑的固态聚合物电解质(SPE),并针对其相转变、结晶性、热稳定性、电导率以及电化学稳定性等基础理化及电化学性质进行了系统表征。结果表明,NaTFSI/PEO([EO]/[Na+]=15)SPE具有相对高的电导率(σ ≈ 10-3 S·cm-1,80℃)、高的耐氧化能力(4.86 V vs Na+/Na)和热稳定性高达350℃。电池测试结果表明,该NaTFSI基SPE不仅对金属钠电极能够呈现出优异的界面稳定性,而且在Na|SPE|NaCu1/9Ni2/9Fe1/3Mn1/3O2电池中展现出良好的循环和倍率性能。 相似文献
9.
合成了五种新的1-烷基-2,3-二甲基咪唑二(三氟甲基磺酰)亚胺离子液体(alkyl-DMimTFSI).以离子液体作为Li/LiFeO4电池电解液,分别考察不同烷基(正丁基、正戊基、正辛基、异辛基和正癸基)对电解液理化性质、界面性质和电池行为的影响.结果表明离子液体的电化学窗口都可以达到5.6V(-0.4~5.2Vvs.Li+/Li),显示它们具有较好的电化学稳定性.加入碳酸亚乙烯酯作为添加剂后,离子液体电解液在Li负极形成稳定的固体电解质相界面膜(SEI),从而提高了Li负极的稳定性,保护了Li片不受腐蚀.电化学阻抗和循环伏安分析进一步揭示LiFeO4正极与离子液体电解液也有良好的兼容性.此外,研究还表明离子液体中烷基种类严重影响它们的电池行为.采用butyl-DMimTFSI和amyl-DMimTFSI电解液体系的电池充放电容量和可逆性明显优于另外三种离子液体,它们的首次放电容量分别达到145和152.6mAh/g,并表现出良好的充放电循环性能.因粘度最大,采用isooctyl-DMimTFSI电解液的电池首次放电容量仅为8.3mAh/g,但添加碳酸丙烯酯(质量比1∶1)稀释后首次放电容量上升至132.4mAh/g. 相似文献
10.
金属锂电池被认为是具有良好前景的下一代高能量密度电池。然而,传统的碳酸酯类电解液与锂的亲和性差,在循环过程中由于锂枝晶的生长和固体电解质膜(SEI)的不稳定导致金属锂电池性能快速衰减。采用1.2 mol/L六氟磷酸锂(LiPF6)/二氟草酸硼酸锂(LiDFOB)/氟代碳酸乙烯酯(FEC)/碳酸二乙酯(DEC),并添加了双三氟甲磺酰亚胺锂(LiTFSI)作为电解液,对其在LiNi0.6Mn0.2Co0.2O2/40 μm-Li(单位面积上负/正极材料的实际容量的比N/P=2.85)电池中的电化学性能进行了研究。LiNi0.6Mn0.2Co0.2O2/40 μm-Li电池表现出优异的循环稳定性(循环120圈后,容量保持率>93%)和倍率性能(3C倍率下放电比容量为110 mA·h/g)。良好的电化学性能主要归因于该电解液可以在金属锂表面形成致密且稳定的SEI,并抑制锂枝晶的产生。 相似文献
11.
H. G. Ang S. G. Ang S. W. Du B. H. Sow A. L. Rheingold 《Journal of organometallic chemistry》1996,510(1-2):13-24
Reaction of [Ru3(CO)12 with (CF3)2P---P(CF3)2 in p-xylene at 140°C yielded the compounds [Ru4(CO)13{μ-P(CF3)2}2] (1), [Ru4(CO)14{μ-P(CF3)2}2] (2) and [Ru4(CO)11{μ-P(CF3)2}4] (3). Reaction with [(μ-H)4Ru4(CO)12] under similar conditions yielded [(μ-H)3Ru4(CO)12{μ-P(CF3)2}] (4). All four compounds have been characterised by X-ray crystallography. The fluxional behaviour of the hydrides in 4 has also been studied by variable-temperature NMR spectroscopy. Compounds 1, 2 and 4 were also obtained from the reactions of Ru3(CO)12 with (CF3)2PH in dichloromethane at 80°C. 相似文献
12.
S.C. Nunes V. de Zea Bermudez D. Ostrovskii Nuno V. Martins 《Journal of Molecular Structure》2008,879(1-3):72-80
Fourier Transform infrared (FT-IR) and Raman (FT-Raman) spectroscopies and Scanning Electron Microscopy (SEM) were used to investigate ionic association, hydrogen bonding and morphology in a family of sol–gel derived lithium triflate (LiCF3SO3)-doped di-urethane cross-linked poly(ε-caprolactone) (PCL(530))/siloxane hybrid electrolytes. The materials studied, with compositions ∞ > n 0.5 (where n – composition – expresses the molar ratio of PCL(530) ester repeat units per Li+ ion), are non-porous and homogeneous. The Li+ ions interact with the urethane and ester carbonyl oxygen atoms within the whole range of salt concentration analyzed, promoting the formation of hydrogen-bonded aggregates. The composition dependence of the relative concentration of “free” anions and coordinated anions (weakly coordinated anions, ion pairs or [Li(CF3SO3)2]− triplets, aggregates I ([Li2(CF3SO3)]+) and aggregates II ([Li3(CF3SO3)]2+) in all the samples is in perfect agreement with the values of the room temperature ionic conductivity reported previously. 相似文献
13.
Robert Toreki Richard R. Schrock William M. Davis 《Journal of organometallic chemistry》1996,520(1-2):69-78
Photolysis of compounds of the type [Re(CCMe2R)(OR′)2] (R = Me or Ph; OR′ = O′Bu, OCMe2(CF3), or OCMe(CF3)2) in benzene with a medium pressure mercury lamp yields compounds of the type [Re(OR′)2]2(μ-CCMe2R)2 in an intramolecular and irreversible manner. [Re(CCMe2R)(OR′)2]2 and [Re(OR′)2]2(μ-CCMe2R)2 (OR′ = O′Bu or OCMe2(CF3)2) both react with excess carbon monoxide in several solvents to afford the dimers [Re(OR′)2(CO)]2(μ-CCMe2R)2 quantitatively. An X-ray study of [Re(OtBu)2(CO)]2 (μ-CtBu)2 shows it to consist of two distorted trigonal bipyramids connected by two symmetrically bridging neopentylidyne ligands. The unbridged dimers of general formula [Re(CCMe2R)(OR′)2]2 do not react readily with simple substrates such as phosphines, olefins, or acetylenes, although [Re(CCMe2R)(OtBu)2]2 can be oxidized by iodine to yield Re(CCMe2R)(OtBu)2I2 in good yield. In contrast, {Re[OCMe(CF3)2]2}2(μ-CtBu)2 reacts with one equivalent of phenylacetylene to give a species in which one of the two bridging alkylidyne ligands is retained. 相似文献
14.
The η3-allyliridium complexes [Ir(η3-2-RC3H4)(PiPr3)2] (2, 3) have been prepared in a one-pot reaction from [IrCl(C2H4)2]2, 2-RC3H4Li and PiPr3 in 70% yield. Compounds 2 and 3 react spontaneously with H2 to give [IrH5(PiPr3)2] (7) and with excess PhC=CH and MeCCH to give [Ir(CCPh)3(PiPr3)2] (5) and [Ir(CCMe)2(CMe=CH2)(PiPr3)2] (6), respectively. From 2 (or 3) and two equivalents of PhCCH the complex [IrH(CCPh)2(PiPr3)2] (4) has been obtained. Treatment of 2 or 3 with CF3CO2H does not lead to a cleavage of the allyl-metal bond but affords the allyl(hydrido)-iridium(III) complexes [IrH(η3-2-RC3H4)(η1-P2CCF3)(PiPr3)2] (8, 9) in almost quantitative yield. 相似文献
15.
合成并考察了N-甲基-N-乙(丙,丁)基哌啶-二( 三氟甲基磺酰) 亚胺三种离子液体( PP12(3,4)TFSI )作为电解液添加剂的影响. 使用热分析和电化学技术研究了离子液体混合电解液的热稳定性和电化学性能.实验表明,哌啶型离子液体可以提高有机电解液的热稳定性,并且侧链的长短对 LiCoO2 电极的电化学性能有重要的影响.当以PP13TFSI配成的混合电解液,在3.0~4.35 V之间、电流密度为150 mA•g-1时, LiCoO2 电极的首次放电容量为156.6 mAh•g-1,200周循环后容量为133.9mAh•g-1,容量保持率为85.5%,远远优于在传统有机电解液中的循环性能. 相似文献
16.
The reaction between metallic barium and fluoroisopropanol or alcoholysis of [Ba(OPri)2] produces a pentanuclear fluoroalkoxide. Its X-ray structure determination showed its formulation to correspond to Ba5(μ5-OH)[μ3-OCH(CF3)2]4[μ2-OCH(CF3)2]4 [OCH(CF3)2](THF)4(H2O)·THF. The metallic core is based on a square pyramid encapsulating an hydroxo ligand. In addition to the barium---alkoxide bonds [2.53(3)–2.86(3) Å] neutral O-donors, four THF [2.82(2)–2.86(3) Å] and one H2O [2.79(3) Å] and secondary barium---fluorine interactions [2.99(2)–3.31(2) Å] ensure high coordination numbers, from 9 to 11 for the metal centers. Hydrogen bonding between the apical fluoroisopropoxide, the water molecule and one THF molecule, non-bonded to a metal center, accounts for the stability of the hydrate and illustrates the Lewis acidity of fluoroalkoxides. Thermal decomposition leads to BaF2. 相似文献
17.
The interaction of [(η5-C5H4But)2YbCl · LiCl] with one equivalent of Li[(CH2) (CH2)PPh2] in tetrahydrofuran gave [Ph2PMe2][(η5-C5H4But)2Li] (1) and [(η5-C5H4But)2Yb(Cl)CH2P(Me)Ph2] (2) in 10% and 30% yields, respectively. 1 could also be prepared in 70% yield from the reaction of [Ph2PMe2][CF3SO3] with two equivalents of (C5H4But)Li. Both compounds have been fully characterized by analytical, spectroscopic and X-ray diffraction methods. The solid state structure of 1 reveals a sandwich structure for the [(η5-C5H4But)2Li]− anion. 相似文献
18.
The ground-state and low-lying excited electronic states in mononuclear, {H2B[3,5-(CF3)2Pz]2M(2,4,6-Cn)} (M1) and dinuclear {[3,5-(CF3)2Pz]M(2,4,6-Cn)}2, (M2) (Pz = pyrazole, Cn = collidine and M = Cu, Ag), are studied using DFT approach. Electronic properties are calculated using B3LYP, while excited singlet and triplet-states are examined using TD-B3LYP. All the calculated low-lying transitions are categorized as 1MLCT transitions. A good agreement was found between experimental spectra and predicted emission wavelengths (λem), the corresponding emissive states being assigned as 3MLCT for Cu1 and Ag2, 3MLLCT for Ag1 and 3LLCT for Cu2. 相似文献
19.
Franco Cecconi Carlo A. Ghilardi Stefano Midollini Annabella Orlandini Alberto Vacca 《Journal of organometallic chemistry》1996,510(1-2):153-156
Both ionic [HgR(DMSO)][CF3SO3] (R = Me or Ph) and covalent HgMeI organomercury(II) compounds react with the tripodal ligand N(CH2CH2PPh2)3 (np3) to yield as ultimate products Hg(II) complexes, the new five-coordinated [Hg(OSO2CF3)(np3)]+ or the known tetrahedral [HgI(np3)]+ and symmetric diorganomercurials respectively. Monitoring of the reactions by 1H, 31P and 13C NMR spectroscopy has shown that the mechanistic pathways depend on the nature of the reagents. 相似文献