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Reaction and transport in Ag/Ag2O gas diffusion electrodes of aqueous Li-O2 batteries: Experiments and modeling (2014)

Danner, Timo ; Horstmann, Birger ; Wittmaier, Dennis ; Wagner, Norbert ; Bessler, Wolfgang G.

Insight into lithium-sulfur batteries: Elementary kinetic modeling and impedance simulation (2013)

Fronczek, David Norman ; Bessler, Wolfgang G.

Cell design concepts for aqueous lithium-oxygen batteries: A model-based assessment (2015)

Grübl, Daniel ; Bessler, Wolfgang G.

Multi-methodology modeling and design of lithium-air cells with aqueous electrolyte (2014)

Grübl, Daniel ; Danner, Timo ; Schulz, Volker P. ; Latz, Arnulf ; Bessler, Wolfgang G.

Mechanistic modeling of capacity loss and polysulfide shuttle in lithium-sulfur batteries (2014)

Hofmann, Andreas F. ; Fronczek, David Norman ; Bessler, Wolfgang G.

Precipitation in aqueous lithium-oxygen batteries: A model-based analysis (2013)

Horstmann, Birger ; Danner, Timo ; Bessler, Wolfgang G.

Rate-Dependent Morphology of Li2O2 Growth in Li–O2 Batteries (2013)

Horstmann, Birger ; Gallant, Betar ; Mitchell, Robert ; Bessler, Wolfgang G. ; Shao-Horn, Yang ; Bazant, Martin Z.

Compact solid discharge products enable energy storage devices with high gravimetric and volumetric energy densities, but solid deposits on active surfaces can disturb charge transport and induce mechanical stress. In this Letter, we develop a nanoscale continuum model for the growth of Li2O2 crystals in lithium–oxygen batteries with organic electrolytes, based on a theory of electrochemical nonequilibrium thermodynamics originally applied to Li-ion batteries. As in the case of lithium insertion in phase-separating LiFePO4 nanoparticles, the theory predicts a transition from complex to uniform morphologies of Li2O2 with increasing current. Discrete particle growth at low discharge rates becomes suppressed at high rates, resulting in a film of electronically insulating Li2O2 that limits cell performance. We predict that the transition between these surface growth modes occurs at current densities close to the exchange current density of the cathode reaction, consistent with experimental observations.

An Agglomerate Model of Lithium-Ion Battery Cathodes (2016)

Lueth, Sabine ; Sauter, Ulrich S. ; Bessler, Wolfgang G.

n this work a mathematical model for describing the performance of lithium-ion battery electrodes consisting of porous active material particles is presented. The model represents an extension of the Newman-type model, accounting for the agglomerate structure of the active material particles, here Li(Ni1/3Co1/3Mn1/3)O2 (NCM) and Li(Ni1/3Co1/3Al1/3)O2 (NCA). To this goal, an additional pore space is introduced on the active material level. The space is filled with electrolyte and a charge-transfer reaction takes place at the liquid-solid interface within the porous active material particles. Volume-averaging techniques are used to derive the model equations. A local Thiele modulus is defined and provides an insight into the potentially limiting factors on the active material level. The introduction of a liquid-phase ion transport within the active material reduces the overall transport losses, while the additional active surface area within the agglomerate lowers the charge-transfer resistance. As a consequence, calculated discharge capacities are higher for particles modeled as agglomerates. This finding is more pronounced in the case of high C-rates

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