FILMING MECHANISM OF LITHIUM-CARBON ANODES IN ORGANIC AND INORGANIC ELECTROLYTES

被引：569

作者：

BESENHARD, JO ^{[1
]}

WINTER, M ^{[1
]}

YANG, J ^{[1
]}

BIBERACHER, W ^{[1
]}

机构：

[1] WALTHER MEISSNER INST TIEFTEMPERATURFORSCH, D-85748 GARCHING, GERMANY

来源：

JOURNAL OF POWER SOURCES | 1995年 / 54卷 / 02期

关键词：

CARBON FILMING; DILATOMETRY; INORGANIC ELECTROLYTE ADDITIVES; INORGANIC PROTECTIVE FILMS; LITHIUM CARBON ANODES; LITHIUM GRAPHITE INTERCALATION COMPOUNDS; SOLVATED GRAPHITE INTERCALATION COMPOUNDS;

D O I：

10.1016/0378-7753(94)02073-C

中图分类号：

O64 [物理化学（理论化学）、化学物理学];

学科分类号：

070304 ; 081704 ;

摘要：

To study the filming mechanism of graphite-based LiCn, electrodes, electrochemical reduction of graphite materials was carried out in 1 M LiClO4/ethylene carbonate (EC)-1,2-dimethoxyethane (DME) (1:1 by volume). Due to film forming a peak at potentials around 0.8 V versus Li/Li+ was observed during the first reduction. The reversibility of this peak was examined by cyclic voltammetry; in addition, the crystal expansion/contraction was checked by means of dilatometry. The results indicate that ternary solvated graphite-intercalation compounds (GICs) were formed at those potentials leading to drastic expansion of the graphite matrix (>150%). These Li(EC)(y1)(DME)(y2)C-n-GICs decompose and build up a protective layer on the graphite that prevents further solvent co-intercalation. The beneficial effect of EC-containing electrolytes on the stability of lithium-carbon anodes seems to be related to inorganic films formed via secondary chemical decomposition of electrochemically formed EC-GICs. The key-role of inorganic films is also demonstrated by the fact that inorganic additives, such as carbon dioxide, suppress the formation of solvated GICs. Furthermore, it can be seen that lithium-carbon negatives can even be operated in inorganic electrolytes such as SO2 and SOCl2.

引用

页码：228 / 231

页数：4

共 8 条

[1] THE BEHAVIOR OF LITHIUM ELECTRODES IN PROPYLENE AND ETHYLENE CARBONATE - THE MAJOR FACTORS THAT INFLUENCE LI CYCLING EFFICIENCY [J].

AURBACH, D ;

GOFER, Y ;

BENZION, M ;

APED, P .

JOURNAL OF ELECTROANALYTICAL CHEMISTRY, 1992, 339 (1-2) :451-471

[2]

BESENHAR.JO, 1974, J ELECTROANAL CHEM, V53, P329, DOI 10.1016/S0022-0728(74)80146-4

[3] ELECTROCHEMICAL PREPARATION AND PROPERTIES OF IONIC ALKALI METAL- AND NR4-GRAPHITE INTERCALATION COMPOUNDS IN ORGANIC ELECTROLYTES [J].

BESENHARD, JO .

CARBON, 1976, 14 (02) :111-115

[4]

BESENHARD JO, 1993, J POWER SOURCES, V43, P413

[5] A HIGH-RESOLUTION DILATOMETER FOR INSITU STUDIES OF THE ELECTROINTERCALATION OF LAYERED MATERIALS [J].

BIBERACHER, W ;

LERF, A ;

BESENHARD, JO ;

MOHWALD, H ;

BUTZ, T .

MATERIALS RESEARCH BULLETIN, 1982, 17 (11) :1385-1392

[6] RECHARGEABLE LICOO2 IN INORGANIC ELECTROLYTE SOLUTION [J].

DREHER, J ;

HAAS, B ;

HAMBITZER, G .

JOURNAL OF POWER SOURCES, 1993, 44 (1-3) :583-587

[7] FORMATION OF LITHIUM-GRAPHITE INTERCALATION COMPOUNDS IN NONAQUEOUS ELECTROLYTES AND THEIR APPLICATION AS A NEGATIVE ELECTRODE FOR A LITHIUM ION (SHUTTLECOCK) CELL [J].

OHZUKU, T ;

IWAKOSHI, Y ;

SAWAI, K .

JOURNAL OF THE ELECTROCHEMICAL SOCIETY, 1993, 140 (09) :2490-2498

[8] EFFECT OF 12 CROWN-4 ON THE ELECTROCHEMICAL INTERCALATION OF LITHIUM INTO GRAPHITE [J].

SHU, ZX ;

MCMILLAN, RS ;

MURRAY, JJ .

JOURNAL OF THE ELECTROCHEMICAL SOCIETY, 1993, 140 (06) :L101-L103

← 1 →