Abstract
Li-metal batteries are attracting a lot of attention nowadays. However, they are merely an attempt to enhance energy densities by employing a negative Li-metal electrode. Usually, when a Li-metal cell is charged, a certain amount of sacrificial lithium must be added, because irreversible losses per cycle add up much more unfavourably compared to conventional Li-ion cells. When liquid electrolytes instead of solid ones are used, additional electrolyte must also be added because both the lithium of the positive electrode and the liquid electrolyte are consumed during each cycle. Solid electrolytes may present a clever solution to the issue of saving sacrificial lithium and electrolyte, but their additional intrinsic weight and volume must be considered. This poses the important question of if and how much energy density can be gained in realistic scenarios if a switch from Li-ion to rechargeable Li-metal cells is anticipated. This paper calculates various scenarios assuming typical losses per cycle and reveals future e-mobility as a potential application of Li-metal cells. The paper discusses the trade-off if, considering only the push for energy density, liquid electrolytes can become a feasible option in large Li-metal batteries vs. the solid-state approach. This also includes the important aspect of cost.
Highlights
Existing conventional lithium-ion battery (LIB) technology is reaching its performance limits, as electric vehicle (EV) manufacturers aim to offer new EVs with extended driving range
This paper aims to present various realistic scenarios in order to answer how much energy density can be gained by the technology transition from LIBs to
The energy density of a battery is mainly limited by two elements of a battery cell: the cathode and anode materials
Summary
Existing conventional lithium-ion battery (LIB) technology is reaching its performance limits, as electric vehicle (EV) manufacturers aim to offer new EVs with extended driving range. To achieve this goal, the first approach was to increase nickel content in the cathode. Within the scope of this article, we will discuss different Li-ion excesses, with different anode and cathode thicknesses to understand the effect of different numbers and parameters on the columbic efficiencies and the energy density. Achieving long cycle life and long driving distance range with a reasonable excess lithium: Different EV battery capacities and different energy consumption scenarios. At the end the cost aspect will be reflected on
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