Lithium–silicon battery
Lithium–silicon batteries are a lithium-ion battery technology under development that employ a silicon anode.[1] Silicon has a much larger energy density than currently used anode materials, but the large volume change of silicon when lithium is inserted is the main obstacle to commercialization this type of anode material.
History
The first laboratory experiments with lithium-silicon batteries took place in the late 1990s.[2] The large volume change of silicon when lithium is inserted is the main obstacle to commercialization this type of anode material.[3]
Silicon-graphite composite electrodes
Test sample production of batches of batteries using a silicon-graphite composite electrode started by the company Amprius in 2014.[4] The same company claims to have sold several hundred thousands of these batteries as of 2014.[5] In 2016, Stanford University researchers presented a method of encapsulating silicon microparticles in a graphene shell, which confines fractured particles and also acts as a stable solid electrolyte interface layer. These microparticles reached an energy density of 3,300 mAh/g.[6]
Also in 2014, a company called Enevate presented a battery using an unknown monolithic silicon-composite anode with a low cell resistance.[7] These batteries leave 25% of the capacity unused, most likely to reduce fast degrading of the cell.[8] For this technology it was named an Innovation Award Honoree in three categories at 2016's Consumer Electronics Show (CES).[9] Shortly after CES 2016, it was announced that Sonim Technologies (a company selling rugged mobile phones) will be using Enevate's lithium-silicon batteries in its products.[10]
Specific capacity
Anode material | Specific capacity (mAh/g) | Volume change |
---|---|---|
Li | 3862 | - |
LiC 6 |
372 | 10% |
Li 13Sn 5 |
990 | 252% |
Li 9Al 4 |
2235 | 604% |
Li 22Si 5 |
4200 | 320% |
A crystalline silicon anode has a theoretical specific capacity of 4200 mAh/g, more than ten times that of anodes such as graphite (372 mAh/g).[3] Each silicon atom can bind up to 4.4 lithium atoms in its fully lithiated state Li
4.4Si, compared to the one lithium atom per 6 carbon atoms for the fully lithiated state of graphite, LiC
6.[13]
Silicon swelling
The lattice distance between silicon atoms multiplies as it accommodates lithium ions (lithiation), reaching 320% of the original volume.[3] The expansion causes large anisotropic stresses to occure within the electrode material, leading to fractures and crumbling of the silicon material and ill-fated detachment from the current collector.[14] Prototypical lithium-silicon batteries lose most of their capacity in as little as 10 charge-discharge cycles.[2][15]
Solid electrolyte interface layer
Another factor that prevents commercialization of lithium-silicon batteries is the development of an unstable solid electrolyte interface SEI layer consisting of decomposed electrolyte material.[16]
The SEI layer would normally form a layer impenetratable for electrolyte, which prevents further growth. However, due to the swelling of the silicon, the SEI layer cracks and become porous.[17] Thus, it can grow to into thicker layers. A thick SEI layer results in a higher cell resistance, which decreases the cell efficiency.[18][19]
The SEI layer on silicon is composed of reduced electrolyte and lithium.[18] At the operating voltage of the battery, the electrolyte is unstable and decomposes.[16] The consumption of lithium in the formation of the SEI layer further decreases the battery capacity.[19] Limited growth of the SEI layer is therefore an important property needed to design commercial lithium-silicon batteries.
See also
References
- ^ Nazri, Gholam-Abbas; Pistoia, Gianfranco, eds. (2004). Lithium Batteries - Science and Technology. Kluwer Academic Publishers. p. 259. ISBN 1-4020-7628-2.
- ^ a b Bourderau, S; Brousse, T; Schleich, D.M (1999). "Amorphous silicon as a possible anode material for Li-ion batteries". Journal of Power Sources. 81–82: 233. doi:10.1016/S0378-7753(99)00194-9.
- ^ a b c d Mukhopadhyay, Amartya; Sheldon, Brian W. (2014). "Deformation and stress in electrode materials for Li-ion batteries". Progress in Materials Science. 63: 58. doi:10.1016/j.pmatsci.2014.02.001.
- ^ St. John, Jeff (2014-01-06). "Amprius Gets $30M Boost for Silicon-Based Lithium-Ion Batteries". Greentechmedia. Retrieved 2015-07-21.
- ^ Bullis, Kevin (10 January 2014). "Startup Gets $30 Million to Bring High-Energy Silicon Batteries to Market". MIT Technology Review.
- ^ Li, Yuzhang; Yan, Kai; Lee, Hyun-Wook; Lu, Zhenda; Liu, Nian; Cui, Yi (2016). "Growth of conformal graphene cages on micrometre-sized silicon particles as stable battery anodes". Nature Energy. 1 (2): 15029. doi:10.1038/nenergy.2015.29. ISSN 2058-7546.
- ^ "9 December 2014". Enevate Announces HD-Energy® Technology for Li-ion Batteries.
{{cite web}}
: Check date values in:|date=
(help) - ^ Demerjian, Charlie (26 January 2016). "Enevate introduces a Silicon-Lithium-Ion battery".
- ^ "Enevate Named as CES 2016 Innovation Awards Honoree in Multiple Categories". 12 February 2016.
- ^ "Sonim picks Enevate batteries for ultra-rugged smartphones". 17 February 2016.
- ^ Besenhard, J.; Daniel, C., eds. (2011). Handbook of Battery Materials. Wiley-VCH.
- ^ Nazri, Gholam-Abbas; Pistoia, Gianfranco, eds. (2004). Lithium Batteries - Science and Technology. Kluwer Academic Publishers. p. 117. ISBN 1-4020-7628-2.
- ^ Tarascon, J.M.; Armand, M. (2001). "Issues and challenges facing rechargeable lithium batteries". Nature. 414 (6861): 359–67. doi:10.1038/35104644. PMID 11713543.
- ^ Berla, Lucas A.; Lee, Seok Woo; Ryu, Ill; Cui, Yi; Nix, William D. (2014). "Robustness of amorphous silicon during the initial lithiation/delithiation cycle". Journal of Power Sources. 258: 253. doi:10.1016/j.jpowsour.2014.02.032.
- ^ Jung, H (2003). "Amorphous silicon anode for lithium-ion rechargeable batteries". Journal of Power Sources. 115 (2): 346. doi:10.1016/S0378-7753(02)00707-3.
- ^ a b Chan, Candace K.; Ruffo, Riccardo; Hong, Seung Sae; Cui, Yi (2009). "Surface chemistry and morphology of the solid electrolyte interphase on silicon nanowire lithium-ion battery anodes". Journal of Power Sources. 189 (2): 1132–1140. doi:10.1016/j.jpowsour.2009.01.007. ISSN 0378-7753.
- ^ Fong, Rosamaría (1990). "Studies of Lithium Intercalation into Carbons Using Nonaqueous Electrochemical Cells". Journal of The Electrochemical Society. 137 (7): 2009. doi:10.1149/1.2086855. ISSN 0013-4651.
- ^ a b Ruffo, Riccardo; Hong, Seung Sae; Chan, Candace K.; Huggins, Robert A.; Cui, Yi (2009). "Impedance Analysis of Silicon Nanowire Lithium Ion Battery Anodes". The Journal of Physical Chemistry C. 113 (26): 11390–11398. doi:10.1021/jp901594g. ISSN 1932-7447.
- ^ a b Oumellal, Y.; Delpuech, N.; Mazouzi, D.; Dupré, N.; Gaubicher, J.; Moreau, P.; Soudan, P.; Lestriez, B.; Guyomard, D. (2011). "The failure mechanism of nano-sized Si-based negative electrodes for lithium ion batteries". Journal of Materials Chemistry. 21 (17): 6201. doi:10.1039/c1jm10213c. ISSN 0959-9428.