High-power lithium-ion batteries

DIAGNOSTIC EVALUATION OF POWER FADE PHENOMENA AND CALENDAR LIFE REDUCTION IN HIGH-POWER LITHIUM-ION BATTERIES... [Pg.453]

High-power lithium-ion batteries are promising alternatives to the nickel metal hydride batteries which are currently used for energy storage in hybrid electric vehicles (HEVs). Currently, Li(Ni,Co)02-based materials are the most widely studied cathode materials for the high-power lithium-ion batteries [1-4]. Although Li(Ni,Co)02-based materials meet the initial power requirement for the HEY application, however, it has been reported that they... [Pg.510]

The development of low cost LiFeP04-based high power lithium-ion batteries. [Pg.77]

Kostecki R., Lei J., McLamon R, Shim J., Striebel K. Diagnostic Evaluation of Detrimental Phenomena in High-Power Lithium-Ion Batteries, J. Electrochem. Soc. 2006,153, A669-A672. [Pg.361]

Chen CH, Liu J, Stoll ME, Henriksen G, Vissers DR, Amine K (2004) Aluminum-doped lithium nickel cobalt oxide electrodes for high-power lithium-ion batteries. J Power Sources 128 278-285... [Pg.38]

Kostecki R, Lei J, McLamon F, Shim J, Striebel K (2006) Diagnostic evaluation of detrimental phenomena in high-power lithium-ion batteries. J Electrochem Soc 153 A669-A672... [Pg.38]

H. Horie, Y. Tanjo, T. Abe, K. Katayama, J. Shigetomi, Development of a High Power Lithium-Ion Battery System for HEV, EVS14, 1997. [Pg.95]

H. Horie, O. Shimamura, T. Saito, T. Abe, Y. Ohsawa, M. Kawai, H. Sugawara, Development of Ultra-High Power lithium-ion Batteries, 12th IMLB, Nara, Japan, 27 June, 2004. [Pg.95]

Jia H et al (2011) Novel three dimensional mesoporous silicon for high power lithium ion battery anode material. Adv Energy Mater 1(6) 1036-1039 Jiang Z et al (2013) Facile fabrication of three dimensional Si/SiC composites via one step magnesiothermic reduction at relative low temperature. Mater Res Bull 48 4139-4145 Jung DS et al (2013) Recycling rice husks for high capacity lithium battery anodes. Proc Natl Acad SciUS A 110 12229-12234... [Pg.621]

D. Andre, M. Meiler, K. Steiner, H. Walz, T. Soczka-Guth, and S.D.U., Characterization of high-power lithium-ion batteries by electrochemical impedance spectroscopy. ii modelling, Journal of Power Sources, vol. 196, pp. 5349-5356, 2011. [Pg.16]

Analysis of Cell Impedance FOR THE Designof A High-Power Lithium-Ion Battery... [Pg.73]

Figure 9. Typical potential (or cathodic polarization) transients during the cathodic pulse discharging for 10 s at different rates, obtained from the fresh cell (solid line) and the aged cell (dashed line). Figure la in D.-K. Kang and H.-C. Shin, Investigation on cell impedance for high-power lithium-ion batteries. Journal of Solid State Electrochemistry 11 (2007) 1405-1410, Copyright (2007), with kind permission of Springer Science and Business.

Shen L, Li H, Uchaker E et al (2012) General strategy for designing core-shell nanostructured materials for high-power lithium ion batteries. Nano Lett 12 5673—5678... [Pg.184]

Eddahech A, Briat O, Vinassa J-M (2016) Thermal characterization of a high-power lithium-ion battery potentiometric and calorimetric measurement of entropy changes. 61 432-439... [Pg.454]

Hierarchically porous monolithic LiFeP04/carbon composite electrode materials for high power lithium ion batteries. Chem. Mater., 21 (21), 5300-5306. [Pg.1115]

Santhanam, R., Jones, P., Sumana, A., and Rambabu, B. (2010) Influence of lithium content on high rate cyclability of layered Lii+ Nio,3oCoo,3oMno,4o02 cathodes for high power lithium-ion batteries. /. Power Sources, 195 (21), 7391-7396. [Pg.1141]

Cheng, R, Wang, S., Lu, A.H., Li, W.C. 2013. immobilization of nanosized LiFeP04 spheres by 3D coralloid carbon structure with large pore volume and thin walls for high power lithium ion batteries. l owerSourc. 229 249-257. [Pg.123]

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