TY - JOUR
T1 - Horizons for Li-Ion Batteries Relevant to Electro-Mobility
T2 - High-Specific-Energy Cathodes and Chemically Active Separators
AU - Susai, Francis Amalraj
AU - Sclar, Hadar
AU - Shilina, Yuliya
AU - Penki, Tirupathi Rao
AU - Raman, Ravikumar
AU - Maddukuri, Satyanarayana
AU - Maiti, Sandipan
AU - Halalay, Ion C.
AU - Luski, Shalom
AU - Markovsky, Boris
AU - Aurbach, Doron
N1 - Publisher Copyright: © 2018 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim
PY - 2018/10/11
Y1 - 2018/10/11
N2 - Li-ion batteries (LIBs) today face the challenge of application in electrified vehicles (xEVs) which require increased energy density, improved abuse tolerance, prolonged life, and low cost. LIB technology can significantly advance through more realistic approaches such as: i) stable high-specific-energy cathodes based on Li1+ xNiyCozMnwO2 (NCM) compounds with either Ni-rich (x = 0, y → 1), or Li- and Mn-rich (0.1 < x < 0.2, w > 0.5) compositions, and ii) chemically active separators and binders that mitigate battery performance degradation. While the stability of such cathode materials during cell operation tends to decrease with increasing specific capacity, active material doping and coatings, together with carefully designed cell-formation protocols, can enable both high specific capacities and good long-term stability. It has also been shown that major LIB capacity fading mechanisms can be reduced by multifunctional separators and binders that trap transition metal ions and/or scavenge acid species. Here, recent progress on improving Ni-rich and Mn-rich NCM cathode materials is reviewed, as well as in the search for inexpensive, multifunctional, chemically active separators. A realistic overview regarding some of the most promising approaches to improving the performance of rechargeable batteries for xEV applications is also presented.
AB - Li-ion batteries (LIBs) today face the challenge of application in electrified vehicles (xEVs) which require increased energy density, improved abuse tolerance, prolonged life, and low cost. LIB technology can significantly advance through more realistic approaches such as: i) stable high-specific-energy cathodes based on Li1+ xNiyCozMnwO2 (NCM) compounds with either Ni-rich (x = 0, y → 1), or Li- and Mn-rich (0.1 < x < 0.2, w > 0.5) compositions, and ii) chemically active separators and binders that mitigate battery performance degradation. While the stability of such cathode materials during cell operation tends to decrease with increasing specific capacity, active material doping and coatings, together with carefully designed cell-formation protocols, can enable both high specific capacities and good long-term stability. It has also been shown that major LIB capacity fading mechanisms can be reduced by multifunctional separators and binders that trap transition metal ions and/or scavenge acid species. Here, recent progress on improving Ni-rich and Mn-rich NCM cathode materials is reviewed, as well as in the search for inexpensive, multifunctional, chemically active separators. A realistic overview regarding some of the most promising approaches to improving the performance of rechargeable batteries for xEV applications is also presented.
KW - Li-ion batteries
KW - Mn dissolution
KW - Mn-rich oxide cathodes
KW - chemically active separators
KW - high-capacity Li
KW - high-capacity Ni-rich oxide cathodes
UR - http://www.scopus.com/inward/record.url?scp=85050407701&partnerID=8YFLogxK
U2 - https://doi.org/10.1002/adma.201801348
DO - https://doi.org/10.1002/adma.201801348
M3 - مقالة مرجعية
C2 - 30015994
SN - 0935-9648
VL - 30
JO - Advanced Materials
JF - Advanced Materials
IS - 41
M1 - 1801348
ER -