Optimizing the performance of lithium titanate spinel paired with activated carbon or iron phosphate

TY - JOUR

T1 - Optimizing the performance of lithium titanate spinel paired with activated carbon or iron phosphate

AU - Stewart, Sarah

AU - Albertus, Paul

AU - Srinivasan, Venkat

AU - Plitz, Irene

AU - Pereira, Nathalie

AU - Amatucci, Glenn

AU - Newman, John

PY - 2008

Y1 - 2008

N2 - Here we describe a model for lithium titanate spinel paired with an activated carbon electrode: an asymmetric hybrid supercapacitor. The model is compared to experimental results. The performance of this system is compared to a lithium titanate spinel/lithium iron phosphate battery. The model is used to study the performance of these chemistries and to assist in cell optimization. A Ragone plot is generated for various cell designs in order to assess the ability of the chemistries to achieve the U.S. Department of Energy goals for hybrid-electric vehicles. The specific energy of a cell is maximized by optimizing the design for a fixed time of discharge. The thickness and porosity of both electrodes are varied, while holding constant the capacity ratio for the two electrodes, as well as the properties of the separator. The capacity ratio can also be optimized for each time of discharge. A 41% increase in specific power is seen when one optimizes the capacity ratio of a lithium titanate spinel/iron phosphate battery. The optimized designs derived here can be used as a starting point for battery manufacturers and to help decrease the time to commercialization.

AB - Here we describe a model for lithium titanate spinel paired with an activated carbon electrode: an asymmetric hybrid supercapacitor. The model is compared to experimental results. The performance of this system is compared to a lithium titanate spinel/lithium iron phosphate battery. The model is used to study the performance of these chemistries and to assist in cell optimization. A Ragone plot is generated for various cell designs in order to assess the ability of the chemistries to achieve the U.S. Department of Energy goals for hybrid-electric vehicles. The specific energy of a cell is maximized by optimizing the design for a fixed time of discharge. The thickness and porosity of both electrodes are varied, while holding constant the capacity ratio for the two electrodes, as well as the properties of the separator. The capacity ratio can also be optimized for each time of discharge. A 41% increase in specific power is seen when one optimizes the capacity ratio of a lithium titanate spinel/iron phosphate battery. The optimized designs derived here can be used as a starting point for battery manufacturers and to help decrease the time to commercialization.

UR - https://www.scopus.com/pages/publications/38349193672

UR - https://www.scopus.com/pages/publications/38349193672#tab=citedBy

U2 - 10.1149/1.2830552

DO - 10.1149/1.2830552

M3 - Article

SN - 0013-4651

VL - 155

SP - A253-A261

JO - Journal of the Electrochemical Society

JF - Journal of the Electrochemical Society

IS - 3

ER -