From Li-Ion Batteries toward Na-Ion Chemistries: Challenges and Opportunities

被引:480
作者
Chayambuka, Kudakwashe [1 ,2 ,3 ]
Mulder, Grietus [2 ,3 ]
Danilov, Dmitri L. [1 ,4 ]
Notten, Peter H. L. [1 ,4 ,5 ]
机构
[1] Eindhoven Univ Technol, Postbus 513, NL-5600 MB Eindhoven, Netherlands
[2] VITO, Boeretang 200, B-2400 Mol, Belgium
[3] EnergyVille, Thor Pk 8310, B-3600 Genk, Belgium
[4] Forschungszentrum Julich, Fundamental Electrochem IEK 9, D-52425 Julich, Germany
[5] Univ Technol Sydney, Sydney, NSW 2007, Australia
基金
欧盟地平线“2020”;
关键词
battery commercialization; lithium-ion batteries; sodium-ion batteries; ELECTRICAL ENERGY-STORAGE; CAPACITY ANODE MATERIALS; LITHIUM-ION; ELECTROCHEMICAL INTERCALATION; RECHARGEABLE BATTERIES; CATHODE MATERIALS; SODIUM; FUTURE; ELECTRODE; LIMITS;
D O I
10.1002/aenm.202001310
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
Among the existing energy storage technologies, lithium-ion batteries (LIBs) have unmatched energy density and versatility. From the time of their first commercialization in 1991, the growth in LIBs has been driven by portable devices. In recent years, however, large-scale electric vehicle and stationary applications have emerged. Because LIB raw material deposits are unevenly distributed and prone to price fluctuations, these large-scale applications have put unprecedented pressure on the LIB value chain, resulting in the need for alternative energy storage chemistries. The sodium-ion battery (SIB) chemistry is one of the most promising "beyond-lithium" energy storage technologies. Herein, the prospects and key challenges for the commercialization of SIBs are discussed. By comparing the technological evolutions of both LIBs and SIBs, key differences between the two battery chemistries are unraveled. Based on outstanding results in power, cyclability, and safety, the path toward SIB commercialization is seen imminent.
引用
收藏
页数:11
相关论文
共 116 条
[71]   Exploring the Economic Potential of Sodium-Ion Batteries [J].
Peters, Jens F. ;
Cruz, Alexandra Pena ;
Weil, Marcel .
BATTERIES-BASEL, 2019, 5 (01)
[72]   Lithium ion, lithium metal, and alternative rechargeable battery technologies: the odyssey for high energy density [J].
Placke, Tobias ;
Kloepsch, Richard ;
Duehnen, Simon ;
Winter, Martin .
JOURNAL OF SOLID STATE ELECTROCHEMISTRY, 2017, 21 (07) :1939-1964
[73]   Post-Li batteries: promises and challenges [J].
Ponrouch, Alexandre ;
Rosa Palacin, M. .
PHILOSOPHICAL TRANSACTIONS OF THE ROYAL SOCIETY A-MATHEMATICAL PHYSICAL AND ENGINEERING SCIENCES, 2019, 377 (2152)
[74]   In search of an optimized electrolyte for Na-ion batteries [J].
Ponrouch, Alexandre ;
Marchante, Elena ;
Courty, Matthieu ;
Tarascon, Jean-Marie ;
Rosa Palacin, M. .
ENERGY & ENVIRONMENTAL SCIENCE, 2012, 5 (09) :8572-8583
[75]   The re-emergence of sodium ion batteries: testing, processing, and manufacturability [J].
Roberts, Samuel ;
Kendrick, Emma .
NANOTECHNOLOGY SCIENCE AND APPLICATIONS, 2018, 11 :23-33
[76]  
[容晓晖 Rong Xiaohui], 2020, [储能科学与技术, Energy Storage Science and Technology], V9, P515
[77]  
Saft Batteries, 2020, MAK MOST NORD WIND P
[78]   A Brief Review: Past, Present and Future of Lithium Ion Batteries [J].
Schipper, Florian ;
Aurbach, Doron .
RUSSIAN JOURNAL OF ELECTROCHEMISTRY, 2016, 52 (12) :1095-1121
[79]   LITHIUM ROCKING CHAIR BATTERIES - AN OLD CONCEPT [J].
SCROSATI, B .
JOURNAL OF THE ELECTROCHEMICAL SOCIETY, 1992, 139 (10) :2776-2781
[80]   History of lithium batteries [J].
Scrosati, Bruno .
JOURNAL OF SOLID STATE ELECTROCHEMISTRY, 2011, 15 (7-8) :1623-1630