Nauka /Interperiodica
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COO ] n , decompo- sition of LiPF 6 , and dissolution of the active material of the positive electrode. After a 40-day storage, the impedance of the negative carbon electrode increased by 8, 28, and 35% and the reversible capacity decreased by 5, 12, and 18% at storage temperatures of 50, 65, and 75°ë. It proved possible to considerably improve the capacity characteristics of LIB and their stability dur- ing exploitation at elevated temperatures by adding VC in the electrolyte [131, 171]. Using the chronopotenti- ometry, electrochemical quartz microbalance, imped- ance, infrared spectroscopy, and x-ray diffraction anal- ysis methods, Aurbach et al. [115] established that the presence of VC reduces the irreversible capacity of lithiated carbon electrodes at elevated temperatures, increases their stability during cycling, and diminishes impedance. The authors of [115] linked the said effects with the capability of VC to form, during electroreduc- tion, dense elastic polymer films on the surface of the carbon negative electrode. The said films strongly adhere to the carbon surface and provide for the passi- vation of this surface, which is better than that in their absence. The oligomer films that form on the surface of positive electrodes in the presence of VC hamper direct interaction of the material of the said electrodes with products of decomposition and hydrolysis of LiPF 6 . The degradation of LIB and the decrease in the their capacity after storage at elevated temperatures (up to 70°ë) may be caused not only by destructive processes on negative electrodes but also by quite a number of processes occurring on positive electrodes. Aurbach et al. [130] showed that, during prolonged storage and/or cycling at elevated temperatures in an electrolyte containing LiPF 6 , positive electrodes based on lithium cobaltite undergo noticeable degradation. An analysis of an electrolyte solution testifies to the presence of a considerable amount of Co 2+ , which may discharge and undergo deposition on the counterelec- trode surface, worsening the counterelectrode charac- teristics. However, the major reason for the degradation of a battery, in the opinion of the authors of [130] is not so much the change in the composition of the active mass of the positive electrode as the processes occur- ring on its surface. The latter are caused by the forma- tion on a cobaltite electrode of a film of LiF, which forms as a result of interaction of lithium cobaltite with traces of hydrofluoric acid. The said film is responsible for the increase in the impedance of the positive elec- trode, which is connected with the difficultness of migration of lithium ions through a solid-electrolyte film on the electrode surface. Amine et al. [16] were studying the conservation of the capacity and stability of LIB the size 18650 of the system graphite–LiNi 0.8 Co 0.2 O 2 with electrolyte LiPF 6 in an equimolar mixture of EC and DEC, which were stored at temperatures ranging from 40 to 70°ë. The observed degradation of LIB (in the first place, the decrease in the discharge capacity) was accompanied by a considerable increase in the impedance of the pos- itive electrode, which was connected, in opinion of the authors of [16], with an excessive increase in the thick- ness of the solid-electrolyte film on the electrode. The correctness of this assertion is confirmed by the results obtained in [172, 173], whose authors used a variety of methods to investigate the properties and composition of surface films on the positive electrode based on LiNi 0.8 Co 0.2 O 2 after a sufficiently long storage at ele- vated temperatures in an electrolyte based on lithium hexafluorophosphate. It was established that after stor- age the solid-electrolyte film contained a large amount of LiF; in so doing, the weight of the film after storing LIB at 70°ë was greater than that after storage at 50°ë by 10%. With the aim of increasing stability, the authors of [172, 173] think it necessary to replace lith- ium hexafluorophosphate by some other salt. Dokko et al. [174] used an ingenious microvoltam- metric method of investigation to investigate the elec- trochemical stability of individual particles of various cathodic materials (LiMn 2 O 4 , LiNi 0.85 Co 0.15 O 2 , Li 1.10 Cr 0.048 Mn 1.852 O 4 , LiëÓé 2 ) during cycling in per- chlorate, tetrafluoborate, and hexafluorophosphate electrolytes based on a two-component solvent (PC– EC) at temperatures of 25 and 50°ë. It was established that lithium–manganese spinel possesses good stability in such electrolytes as LiClO 4 /PC–EC and LiBF 4 /PC– EC at both room temperature and an elevated tempera- ture (after 50 charge–discharge cycles the stability exceeds 95%) but undergoes degradation when heated in the Li êF 6 /PC–EC (the more so in an insufficiently desiccated electrolyte). Doping the lithium–manganese spinel with chromium allows one to achieve a suffi- ciently high stability in a lithium hexafluorophosphate electrolyte. The stability of lithium cobaltite cycled in the potential region extending from 3.6 to 4.3 V in the LiClO 4 /PC–EC heated to 50 °C is unsatisfactory; but narrowing the cycling range to 3.6–4.0 V leads to a sub- stantial bettering of characteristics. Roughly speaking, the behavior of LiNi 0.85 Co 0.15 O 2 is identical to that of lithium cobaltite. During storage at elevated temperatures and when discharged by high currents, when the temperature inside LIB may exceed 80°ë, there can occur a phase 12 RUSSIAN JOURNAL OF ELECTROCHEMISTRY Vol. 41 No. 1 2005 KANEVSKII, DUBASOVA transformation of cobaltate and a disproportionation of Li 0.5 ëÓO 2 to Li ëÓO 2 and ëÓ 3 O 4 [175]. When stored in conditions of an elevated tempera- ture, a lithium–manganese spinel also may be subjected to disproportionation ( 2Mn 3+ Mn 4+ + Mn 2+ ) [80, 94]. In the presence of hydrofluoric acid, which forms as a result of hydrolysis of LiPF 6 , at an elevated temperature the spinel undergoes dissolution via the reaction 2LiMn 2 O 4 + 4H + 3 λ-MnO 2 + Mn 2+ + 2Li + + 2H 2 O [109, 169]. Water generated in this reaction accelerates the electrode degradation and the capacity sharply decreases. The problem of stability of positive electrodes may be solved by replacing LiPF 6 by other salts, for exam- ple, by LiClO 4 , LiBF 4 , or LiAsF 6 , which form no acid components as a result of hydrolysis. A very perspective electrolyte salt for LIB is thought to be lithium bis(perfluoroethylsulfonyl)imide LiN (C 2 F 5 SO 2 ) 2 (LiBETI), which possesses a very high thermal stability and is insensitive to the action of water [41, 52, 99]. An electrolyte on its basis possesses a high stability up to 60°ë and provides for stable characteris- tics of LIB even in the presence of moderate humidifi- cation. It is the opinion of the authors of [52] that a compos- ite electrolyte based on LiF and a complexing agent, specifically, tris(hexafluorophenyl)boran (ë 6 F 6 ) 3 B, possesses characteristics that are optimum for LIB. This electrolyte is tolerant with respect to water and thermally stable. It ensures a high electroconductance of solutions in a broad temperature interval [176]. The efficiency of the cycling of electrochemical cell Li /LiMn 2 O 4 with the composite electrolyte LiF – (ë 6 F 6 ) 3 B in an equimolar mixture of EC and DMC in a three-hour discharge in the interval of 10–50 cycles at 55 °C not only did not decrease but even increased somewhat and amounted to nearly 97% (the efficiency of similar cycling in an electrolyte based on LiPF 6 within the same time period dropped from 97 to 40%). Authors explain the reason for the high stability both by a high thermal stability of components LiF and (ë 6 F 6 ) 3 B of the electrolyte and by the fact that acid products that bring about the degradation of the mate- rial of the positive electrode fail to form even in the case of decomposition of the electrolyte. The authors of [177–179] reported about a new syn- thesized salt, namely, lithium bis(oxalate)borate LiB (C 2 O 4 ) 2 . The chelated borate anion of this salt has a unique structure containing no hydrogen or labile fluo- rine. According to the data presented in [176], an elec- trolyte based on the said salt is not subjected to any transformations on the negative and positive electrodes and provides for stable discharge characteristics of LIB in conditions of elevated temperatures; besides, it pos- sesses passivating properties with respect to an alumi- num current lead and does not activate its corrosion. After 80 charge–discharge cycles, in a LIB with an electrolyte based on LiPF 6 , at a temperature of 50°ë , the capacity of LIB amounted to 0.56 mA h cm –2 , and in a LIB with an electrolyte based on LiB ( C 2 O 4 ) 2 it was equal to 1 mA h cm –2 at 60 ° C and 0.97 mA h cm –2 at 70°ë . With the aim of developing an optimum electrolyte that would ensure a satisfactory workability of LIB in a broad interval of temperatures extending from –30 to 60°ë , performed were capacity tests of LIB [20] with different electrolytes based on three salts, specifically, LiBF 4 and LiB ( C 2 O 4 ) 2 , which ensure a high and suffi- ciently stable capacity at an elevated temperature, and LiPF 6 , which possesses no such quality. It was estab- lished that a multicomponent electrolyte 1 M LiB ( C 2 O 4 ) 2 in a 1 : 1 : 1 mixture of PC, EC, and EMC made it possible to realize sufficiently stable operation of LIB in a wide temperature interval. CONCLUSIONS Analyzing the above literature data devoted to investigations of stability of energetic characteristics of LIB, one can draw the following conclusions. The reason for the decrease in capacity during the cycling of LIB is various chemical and electrochemical reactions that proceed on electrodes as well as in the bulk electrolyte. The major processes that are responsi- ble for the worsening of characteristics of LIB can be as follows: (1) the overcharge, which leads to the oxida- tion of electrolyte on the positive electrode and the dep- osition of metallic lithium on the negative electrode, (2) the electroreduction of electrolyte components (both the solvent and the salt) and various impurities on the negative electrode, (3) self-discharge of electrodes, and (4) the dissolution and phase alterations of the active material of the positive electrode. Some factors or others may prevail in each particu- lar case; these factors determine parameters of stability of the system. 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