The determination of lithium in rocks by the method of stable isotope dilution

A method is described for the determination of lithium in rocks by the method of stable isotope dilution. 50 mg to 500 mg of the sample are used for each determination. The sample is mixed with a known quantity of enriched lithium and is then decomposed by a mixture of hydrofluoric and perchloric acids. The separation of the alkali metals from iron and aluminium is based on the thermal decomposition of the perchlorates. For mass spectrometric measurements it is not necessary to separate the lithium from the other alkali metals.The values obtained for the lithium contents of two standard rocks are: G-I, 21.3 p.p. m. ; W-I, 12.6 p.p.m. Independent determinations, made using both lithium 6 and lithium 7 as tracers, have established that no significant systematic errors are caused by isotopic fractionation.Results obtained for two clay samples containing 0.1–0.3% of lithium show good agreement with spectrographic values.     

柱状金属锂沉积物:电解液添加剂的影响

二次电池的能量密度已成为推动电动汽车和便携式电子产品技术向前发展的重要指标。使用石墨负极的锂离子电池正接近其理论能量密度的天花板,但仍难以满足高端储能设备的需求。金属锂负极因其极高的理论比容量和极低的电极电位,受到了广泛关注。然而,锂沉积过程中枝晶的生长会导致电池安全性差等问题。电解液对金属锂的沉积有着至关重要的影响。本文设计了一种独特的电解槽体系来进行柱状锂的沉积,研究了不同电解液体系(1mol·L^-1LiPF6-碳酸乙烯酯/碳酸二乙酯(EC/DEC,体积比为1:1)、1 mol·L^-1 LiPF6-氟代碳酸乙烯酯(FEC,体积分数5%)-EC/DEC (体积比为1:1))对金属锂沉积的影响。对两种电解液中金属锂沉积物长径比的研究表明,电解液的组分可以显著地影响金属锂的沉积形貌,在加入氟代碳酸乙烯酯(FEC)添加剂之后,柱状锂的直径从0.3–0.6μm增加到0.7–1.3μm,长径比从12.5下降到5.6。长径比的降低有助于减小金属锂和电解液的反应面积,提高金属锂负极的利用率和循环寿命。通过考察循环后锂片的表面化学性质,发现FEC的分解增加了锂表面固态电解质界面层中氟化锂(LiF)组分的比例,提高了界面层中锂离子的扩散速率,减少了锂的成核位点,从而给予锂核更大的生长空间,降低了沉积出的柱状锂的长径比。     

Reduction of bowl-shaped hydrocarbons: dianions and tetraanions of annelated corannulenes

[structure: see text] The reduction of several annelated corannulene derivatives was undertaken using lithium and potassium metals. It was found that annelation affects the annulenic character of corannulene by changing its charge distribution; the dianions of derivatives that are annelated with six-membered rings have less annulenic character and are less paratropic than corannulene dianion. This effect is even more pronounced in corannulenes that are peri-annelated with five-membered rings. The alkali metal used in the reduction process has a great influence on the outcome, especially on the degree of reduction. Most derivatives get reduced to tetraanions only with potassium, and not with lithium, the exception being systems that can stabilize the tetraanion with lithium by special means, such as aggregation or dimerization. One such system is cyclopenta[bc]corannulene (acecorannulylene), which gives a coordinative dimer that consists of two cyclopentacorannulene tetraanions, bound together in a convex-convex fashion by lithium cations. The points of contact in this dimer are two rehybridized carbons from each cyclopentacorannulene unit, which are bridged together by two lithium cations.     

Atomicm absorption spectrometric determination of the isotopic composition of lithium by an ultimate absorbance-ratio technique

The conventional absorbance-ratio technique for determining the isotopic composition of lithium by atomic absorption spectrometry is improved by the use of “ultimate absorbance ratios” of sample solutions. These ratios are obtained by extrapolating the linear portion of lithium content/absorbance-ratio plots to the intercept at 0 mol m^?3 lithium. These graphs are obtained measuring the absorbances of solutions of known ⁶Li abundance and of various lithium contents with natural and ⁶Li-enriched lithium hollow-cathode lamps. Linear calibration is attained over the range 0.0–99.3% ⁶Li, and the lithium isotopic abundance can be determined with an absolute error of ±0.7% ⁶Li for > 0.01 mol m^?3 lithium solutions. The method requires neither prior measurement of the total lithium content in sample solutions nor adjustment of the content to match that in the standard solutions.     

Stereochimie de la deprotonation et de la reaction d'aldolisation des dithioesters

Cis lithium thioenolates are preferentially formed by deprotonation of dithiopropanoates with lithium diisopropylamide in tetrahydro-furan at -78°C. The cis selectivity observed, is unproved by increasing the alkylthio group size or by the ability of this group to chelate the lithium cation. When more bulkier bases such as lithium 2,2,6,6-tetramethylpiperi-dide or lithium hexamethyldisilazane are used, the selectivity is lowered. This lowering of selectivity is suppressed when the deprotonation is performed in presence of 12-crown-4. Addition of hexamethyl phosphoramide to the base does not invert the selectivity as it uas reported for the deprotonation of esters ; a rather better cis selectivity is reached in the case of methoxymethyl dithiopropanoate. These original results are well understood in terms of an open transition state model. Preformed lithium thioenolates are reacted uith a variety of aldehydes and afford stereo-specifically syn aldols. The influence of hexamethylphosphoramide and reaction time is also examined.     

A computational study of lithium enolate mixed aggregates

Ab initio calculations were performed to examine the formation of mixed dimer and trimer aggregates between the lithium enolate of acetaldehyde (lithium vinyloxide, LiOV) and lithium chloride, lithium bromide, and lithium amides. Gas-phase calculations showed that in the absence of solvation effects, the mixed trimer 2LiOV.LiX is the most favored species. Solvation in ethereal solvents was modeled by a combination of specific coordination of dimethyl ether ligands on each lithium and "dielectric solvation" (DSE, dielectric solvation energies), immersion of each molecule in a cavity within a continuous dielectric having the dielectric constant of THF at room temperature. DSE is less important for aggregates (reduced dipoles or quadrupoles) than monomers (dipoles) and is also reduced for the coordinatively solvated species. Both solvation terms reduce the exothermicity of aggregation. In many cases, lithium salts that are three- rather than four-coordinate have significant populations at room temperature. The strongly basic lithium amides prefer mixed aggregates with weaker bases than homoaggregates. The computational results are consistent with the limited experimental data available.     

Quantitative analysis of the hydration of lithium salts in water using multivariate curve resolution of near-infrared spectra

The hydration process of lithium iodide, lithium bromide, lithium chloride and lithium nitrate in water was analyzed quantitatively by applying multivariate curve resolution alternating least squares (MCR-ALS) to their near infrared spectra recorded between 850 nm and 1100 nm. The experiments were carried out using solutions with a salt mass fraction between 0% and 72% for lithium bromide, between 0% and 67% for lithium nitrate and between 0% and 62% for lithium chloride and lithium iodide at 323.15 K, 333.15 K, 343.15 K and 353.15 K, respectively. Three factors were determined for lithium bromide and lithium iodide and two factors for the lithium chloride and lithium nitrate by singular value decomposition (SVD) of their spectral data matrices. These factors are associated with various chemical environments in which there are aqueous clusters containing the ions of the salts and non-coordinated water molecules. Spectra and concentration profiles of non-coordinated water and cluster aqueous were retrieved by MCR-ALS. The amount of water involved in the process of hydration of the various salts was quantified. The results show that the water absorption capacity increases in the following order LiI < LiBr < LiNO₃ < LiCl. The salt concentration at which there is no free water in the medium was calculated at each one of the temperatures considered. The values ranged between 62.6 and 65.1% for LiBr, 45.5–48.3% for LiCl, 60.4–61.2% for LiI and 60.3–63.7% for LiNO₃. These values are an initial approach to determining the concentration as from which crystal formation is favored.     

Electrochemical Intercalation of Lithium into Carbon: A Relaxation Study

Basic kinetic parameters of electrochemical intercalation of lithium into thin carbon films are determined by relaxation methods of current and potential steps. The overall electrode polarization is theoretically and experimentally divided into kinetic and diffusion constituents. The former is connected with the hindered ion transfer in a surface solid-electrolyte layer. The latter is due to the slow diffusion of lithium inside the carbon matrix. Concentration dependences of parameters of a solid-electrolyte layer and those of the diffusion coefficient for lithium in carbon are determined at lithium concentrations in the electrode varied from 2 to 16 M. The kinetic current is dependent on polarization in the interval 0.01 to 2.5 V, the dependence being identical to that for a lithium electrode.     

电感耦合等离子体原子发射光谱(ICP-AES)法测定岩矿中锂的含量

采用氢氟酸+高氯酸分解试样,硝酸浸取,电感耦合等离子体原子发射光谱法测定岩矿中的锂含量.锂测定范围0.10％ ～10.0％.通过不同混合酸溶样效果比较,仪器测定条件的优化、干扰元素的影响等实验,建立了一种电感耦合等离子体原子发射光谱(IC P-A ES)法测定岩矿中锂量的方法,完全能够满足岩矿中锂含量的检验工作.经加标...     

锂离子电池正极材料的晶体结构及电化学性能

正极材料是锂离子电池的重要组成部分。作为提供自由脱嵌锂离子的正极材料,其晶体结构的特点决定了锂离子脱嵌路径方式的不同,并对锂离子电池的电化学性能等产生明显影响。本文根据正极材料的晶体结构和锂离子“脱嵌/嵌入”路径方式的不同,重点讨论了一维隧道结构、二维层状结构和三维框架结构正极材料的晶体结构特点、锂离子“脱嵌/嵌入”路径和其电化学性能之间的关系,主要包括一维隧道结构正极材料LiFePO₄,二维层状结构正极材料LiMO₂(M=Co, Ni, Mn)、Li_1+xV₃O₈和Li₂MSiO₄ (M=Fe, Mn) 以及三维框架结构正极材料LiMn₂O₄和Li₃V₂(PO₄)₃。揭示了目前锂离子电池正极材料的研究现状和存在问题,并对今后的发展方向进行了评述。     

Electrothermal atomic absorption spectrometric determination of chromium,iron and nickel in lithium metal

Graphite-furnace atomic absorption spectrometry is applied to the determination of traces of Cr, Fe and Ni in lithium metal, after dissolution as lithium chloride. Direct determination is applied to lithium samples containing higher levels of impurities, but determination in pure lithium samples requires preliminary separation by lanthanum hydroxide coprecipitation. With this enrichment, detection limits of 0.02–0.25 μg g^-1 are obtained using 0.5-g samples of lithium. The accuracy of the procedure was checked by analysis of lithium samples by the proposed coprecipitation method, by direct determination, and by determination after extraction, atomic absorption spectrometry being used in all cases.     

Bio‐Inspired Stable Lithium‐Metal Anodes by Co‐depositing Lithium with a 2D Vermiculite Shuttle

Progress in lithium‐metal batteries is severely hindered by lithium dendrite growth. Lithium is soft with a mechanical modulus as low as that of polymers. Herein we suppress lithium dendrites by forming soft–hard organic–inorganic lamella reminiscent of the natural sea‐shell material nacres. We use lithium as the soft segment and colloidal vermiculite sheets as the hard inorganic constituent. The vermiculite sheets are highly negatively charged so can absorb Li⁺ then be co‐deposited with lithium, flattening the lithium growth which remains dendrite‐free over hundreds of cycles. After Li⁺ ions absorbed on the vermiculite are transferred to the lithium substrate, the vermiculite sheets become negative charged again and move away from the substrate along the electric field, allowing them to absorb new Li⁺ and shuttling to and from the substrate. Long term cycling of full cells using the nacre‐mimetic lithium‐metal anodes is also demonstrated.     

Mechanisms of lithium transport in amorphous polyethylene oxide

We report calculations using a previously reported model of lithium perchlorate in polyethylene oxide in order to understand the mechanism of lithium transport in these systems. Using an algorithm suggested by Voter, we find results for the diffusion rate which are quite close to experimental values. By analysis of the individual events in which large lithium motions occur during short times, we find that no single type of rearrangement of the lithium environment characterizes these events. We estimate the free energies of the lithium ion as a function of position during these events by calculation of potentials of mean force and thus derive an approximate map of the free energy as a function of lithium position during these events. The results are consistent with a Marcus-like picture in which the system slowly climbs a free energy barrier dominated by rearrangement of the polymer around the lithium ions, after which the lithium moves very quickly to a new position. Reducing the torsion forces in the model causes the diffusion rates to increase.     

Origin of the detrimental effect of lithium halides on an enantioselective nucleophilic alkylation of aldehydes

The effect of lithium halides on the enantioselectivity of the addition of methyllithium on o-tolualdehyde, in the presence of chiral lithium amides derived from chiral 3-aminopyrrolidines (3APLi), has been investigated. The enantiomeric excess of the resulting 1-o-tolylethanol was found to drop upon addition of significant amounts of LiCl, introduced before the aldehyde. The competitive affinity between the lithium amide, the methyllithium, and the lithium halides in THF was examined by multinuclear NMR spectroscopy and DFT calculations. The results showed that the original mixed aggregate of the chiral lithium amide and methyllithium is rapidly, totally, and irreversibly replaced by a similar 1:1 complex involving one lithium chloride or bromide and one lithium amide. While the MeLi/LiX substitution occurs with some degree of epimerization at the nitrogen for the endo-MeLi:3APLi complex, it is mostly stereospecific for the exo-type arrangements of the aggregate. The thermodynamic preference for mixed aggregates between 3APLi and LiX was confirmed by static DFT calculations: the data show that the LiCl and LiBr aggregates are more stable than their MeLi counterparts by more than 10 kcal.mol(-1) provided THF is explicitly taken into account. These results suggest that a sequestration of the source of chirality by the lithium halides is at the origin of the detrimental effect of these additives on the ee of the model reaction.     

A density functional treatment of organolithium compounds: Comparison to ab initio,semiempirical, and experimental results

Density functional calculations on several classes of organolithium compounds are described. The compounds studied include lithium bonds to carbon, oxygen, and nitrogen and are representative of most types of organolithium compounds that have appeared in the recent literature. The computational results are compared to those using MNDO, which has been shown to have some serious deficiencies in compounds involving carbon–lithium bonds, and to PM3 results, which offer some improvement over MNDO for many organolithium compounds. Most of the density functional calculations with a large basis set are in good agreement with available ab initio and experimental data. Calculated carbon–lithium bond lengths were slightly shorter than those calculated by other ab initio methods and were substantially longer than those calculated by MNDO, which is known to underestimate carbon–lithium bond lengths severely. Dimerization energies of methyllithium, calculated by DMol, were also in good agreement with those of other ab initio calculations. Lithium–nitrogen bonds in lithium amides were calculated to be slightly shorter by DMol than by MNDO, although the two methods were in qualitative agreement for this type of compound. © 1995 by John Wiley & Sons, Inc.     

Phase Formation and Kinetics of Electrochemical Intercalation of Lithium into Intermetallic Compounds MgCd and MgCd3

Electrochemical intercalation of lithium into intermetallic compounds (IMC) MgCd and MgCd₃ out of propylene carbonate solutions of LiBF₄ is studied. According to chronopotentiometry data, during the intercalation, lithium forms compounds with cadmium: Li₃Cd on MgCd or LiCd and Li₃Cd on MgCd₃. Reactions of solid-phase substitution, which occur on the electrodes, are accompanied by the destruction of initial IMC and generation of magnesium atoms. Chronoamperometry of MgCd–(Li) and MgCd₃–(Li) shows the lithium intercalation to be limited by nonstationary diffusion of lithium in the solid phase. The lithium diffusion in MgCd is slower and that in MgCd₃is faster than in Cd. The calculated potential dependences of the diffusion coefficient for lithium in MgCd and MgCd₃ are linear in semilogarithmic coordinates.     

火焰原子吸收光谱法测定电解铝用冰晶石中锂

含锂冰晶石取代锂盐添加到电解质中被广泛应用于电解铝工业,其质量直接影响到电解铝工业的电解效率、吨铝能耗高低和电解铝产品质量优劣。控制冰晶石中锂含量是保证产品质量和应对废旧电解质再生对氟化盐市场冲击的一个重要举措。通过在铂坩埚中加入一定量高氯酸在高温条件下加热冒烟赶氟后再加入盐酸酸化至盐类完全溶解,建立了波长670.80 nm处采用火焰原子吸收光谱法测定铝用冰晶石中锂含量的方法,避免了大量氟基体的干扰,选择一定量的铝钠基体匹配来保证测试灵敏度和准确性;通过加标回收实验得知锂的回收率为102%;锂元素校准曲线线性相关系数≥0.9994;锂的检出限为0.0065μg/mL;不同含量含锂冰晶石的锂标准偏差均小于0.01%,与电感耦合等离子体原子发射光谱(ICP-AES)法测定结果相一致。方法准确可靠、简单易操作,满足铝电解工业生产分析的需要。     

Lithium storage mechanisms and effect of partial cobalt substitution in manganese carbonate electrodes

A promising group of inorganic salts recently emerged for the negative electrode of advanced lithium-ion batteries. Manganese carbonate combines low weight and significant lithium storage properties. Electron paramagnetic resonance (EPR) and magnetic measurements are used to study the environment of manganese ions during cycling in lithium test cells. To observe reversible lithium storage into manganese carbonate, preparation by a reverse micelles method is used. The resulting nanostructuration favors a capacitive lithium storage mechanism in manganese carbonate with good rate performance. Partial substitution of cobalt by manganese improves cycling efficiency at high rates.     

铌酸锂晶体性能的组成依赖性(英文)

总结了铌酸锂晶体的各项性能指标,显示了其对晶体实际组成的强烈依赖性.利用化学键模型定量地解释了这种依赖性产生的根源,从而说明了制约该晶体性能提高的关键因素是晶体结构中的缺陷控制.     

The determination of lithium in lithium-magnesium alloys

An ion exchange method has been developed for the determination of lithium in lithium-magnesium alloys. Lithium is separated from magnesium by eluting lithium from a strongly acidic cation exchange resin with 0.5N hydrochloric acid. Attention is drawn to the fact that considerable quantities of unusual mixtures of lithium isotopes are in existence, and may cause significant errors if their composition is unknown to the analyst.