Lithium ion, lithium metal, and alternative rechargeable battery technologies: the odyssey for high energy density

被引:892
作者
Placke, Tobias [1 ]
Kloepsch, Richard [1 ]
Duehnen, Simon [1 ]
Winter, Martin [1 ,2 ]
机构
[1] Univ Munster, Inst Phys Chem, MEET Battery Res Ctr, Corrensstr 46, D-48149 Munster, Germany
[2] Forschungszentrum Julich GmbH, Helmholtz Inst Munster, IEK-12,Corrensstr 46, D-48149 Munster, Germany
关键词
Lithiumion batteries; Lithium metal batteries; Post-lithium ion batteries; Energy density; History of batteries; SOLID-ELECTROLYTE INTERPHASE; GEL POLYMER ELECTROLYTE; HIGH-VOLTAGE SPINEL; HIGH-CAPACITY; CATHODE MATERIALS; ALLOY ANODES; ELECTROCHEMICAL INTERCALATION; PROPYLENE CARBONATE; SECONDARY BATTERIES; ANION INTERCALATION;
D O I
10.1007/s10008-017-3610-7
中图分类号
O646 [电化学、电解、磁化学];
学科分类号
081704 ;
摘要
Since their market introduction in 1991, lithium ion batteries (LIBs) have developed evolutionary in terms of their specific energies (Wh/kg) and energy densities (Wh/L). Currently, they do not only dominate the small format battery market for portable electronic devices, but have also been successfully implemented as the technology of choice for electromobility as well as for stationary energy storage. Besides LIBs, a variety of different technologically promising battery concepts exists that, depending on the respective technology, might also be suitable for various application purposes. These systems of the "next generation," the so-called post-lithium ion batteries (PLIBs), such as metal/sulfur, metal/air or metal/oxygen, or "post-lithium technologies" (systems without Li), which are based on alternative single (Na+, K+) or multivalent ions (Mg2+, Ca2+), are currently being studied intensively. From today's point of view, it seems quite clear that there will not only be a single technology for all applications (technology monopoly), but different battery systems, which can be especially suitable or combined for a particular application (technology diversity). In this review, we place the lithium ion technology in a historical context and give insights into the battery technology diversity that evolved during the past decades and which will, in turn, influence future research and development.
引用
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页码:1939 / 1964
页数:26
相关论文
共 225 条
[11]   POLYMER SOLID ELECTROLYTES - AN OVERVIEW [J].
ARMAND, M .
SOLID STATE IONICS, 1983, 9-10 (DEC) :745-754
[12]   THE HISTORY OF POLYMER ELECTROLYTES [J].
ARMAND, M .
SOLID STATE IONICS, 1994, 69 (3-4) :309-319
[13]   POLYMER ELECTROLYTES [J].
ARMAND, MB .
ANNUAL REVIEW OF MATERIALS SCIENCE, 1986, 16 :245-261
[14]   Nonaqueous magnesium electrochemistry and its application in secondary batteries [J].
Aurbach, D ;
Weissman, I ;
Gofer, Y ;
Levi, E .
CHEMICAL RECORD, 2003, 3 (01) :61-73
[15]   On the Surface Chemical Aspects of Very High Energy Density, Rechargeable Li-Sulfur Batteries [J].
Aurbach, Doron ;
Pollak, Elad ;
Elazari, Ran ;
Salitra, Gregory ;
Kelley, C. Scordilis ;
Affinito, John .
JOURNAL OF THE ELECTROCHEMICAL SOCIETY, 2009, 156 (08) :A694-A702
[16]   Inorganic Solid-State Electrolytes for Lithium Batteries: Mechanisms and Properties Governing Ion Conduction [J].
Bachman, John Christopher ;
Muy, Sokseiha ;
Grimaud, Alexis ;
Chang, Hao-Hsun ;
Pour, Nir ;
Lux, Simon F. ;
Paschos, Odysseas ;
Maglia, Filippo ;
Lupart, Saskia ;
Lamp, Peter ;
Giordano, Livia ;
Shao-Horn, Yang .
CHEMICAL REVIEWS, 2016, 116 (01) :140-162
[17]  
BAGOUIN M, 1966, CR ACAD SCI C CHIM, V262, P557
[18]   Electrochemistry of liquids vs. solids: Polymer electrolytes [J].
Baril, D ;
Michot, C ;
Armand, M .
SOLID STATE IONICS, 1997, 94 (1-4) :35-47
[19]  
Basu S, 1981, U.S. Patent, Patent No. [4,304,825, 4304825]
[20]   Influence of dry mixing and distribution of conductive additives in cathodes for lithium ion batteries [J].
Bauer, Werner ;
Noetzel, Dorit ;
Wenzel, Valentin ;
Nirschl, Hermann .
JOURNAL OF POWER SOURCES, 2015, 288 :359-367