Birger Horstmann
Birger Horstmann
Deutsches Zentrum für Luft- und Raumfahrt / Universität Ulm / Helmholtz-Institut Ulm
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Cited by
Rate-Dependent Morphology of Li2O2 Growth in Li–O2 Batteries
B Horstmann, B Gallant, R Mitchell, WG Bessler, Y Shao-Horn, MZ Bazant
The journal of physical chemistry letters 4 (24), 4217-4222, 2013
The passivity of lithium electrodes in liquid electrolytes for secondary batteries
X He, D Bresser, S Passerini, F Baakes, U Krewer, J Lopez, CT Mallia, ...
Nature Reviews Materials 6 (11), 1036-1052, 2021
Rechargeable batteries of the future—the state of the art from a BATTERY 2030+ perspective
M Fichtner, K Edström, E Ayerbe, M Berecibar, A Bhowmik, IE Castelli, ...
Advanced Energy Materials 12 (17), 2102904, 2022
Strategies towards enabling lithium metal in batteries: interphases and electrodes
B Horstmann, J Shi, R Amine, M Werres, X He, H Jia, F Hausen, ...
Energy & Environmental Science 14 (10), 5289-5314, 2021
Hawking radiation from an acoustic black hole on an ion ring
B Horstmann, B Reznik, S Fagnocchi, JI Cirac
Physical review letters 104 (25), 250403, 2010
Noise-driven dynamics and phase transitions in fermionic systems
B Horstmann, JI Cirac, G Giedke
Physical Review A 87 (1), 012108, 2013
A flexible framework for modeling multiple solid, liquid and gaseous phases in batteries and fuel cells
JP Neidhardt, DN Fronczek, T Jahnke, T Danner, B Horstmann, ...
Journal of The Electrochemical Society 159 (9), A1528, 2012
Revealing SEI morphology: in-depth analysis of a modeling approach
F Single, B Horstmann, A Latz
Journal of The Electrochemical Society 164 (11), E3132, 2017
Modeling nucleation and growth of zinc oxide during discharge of primary zinc-air batteries
J Stamm, A Varzi, A Latz, B Horstmann
Journal of Power Sources 360, 136-149, 2017
Identifying the mechanism of continued growth of the solid-electrolyte interphase
F Single, A Latz, B Horstmann
ChemSusChem 11 (12), 1950-1955, 2018
Rational development of neutral aqueous electrolytes for zinc–air batteries
S Clark, A Latz, B Horstmann
ChemSusChem 10 (23), 4735-4747, 2017
Solid-Electrolyte Interphase During Battery Cycling: Theory of Growth Regimes
L von Kolzenberg, A Latz, B Horstmann
ChemSusChem 13 (15), 3901-3910, 2020
Innovative zinc-based batteries
N Borchers, S Clark, B Horstmann, K Jayasayee, M Juel, P Stevens
Journal of Power Sources 484, 229309, 2021
Review on multi-scale models of solid-electrolyte interphase formation
B Horstmann, F Single, A Latz
Current Opinion in Electrochemistry 13, 61-69, 2019
Dynamics and morphology of solid electrolyte interphase (SEI)
F Single, B Horstmann, A Latz
Physical Chemistry Chemical Physics 18 (27), 17810-17814, 2016
Precipitation in aqueous lithium–oxygen batteries: a model-based analysis
B Horstmann, T Danner, WG Bessler
Energy & Environmental Science 6 (4), 1299-1314, 2013
A review of model-based design tools for metal-air batteries
S Clark, A Latz, B Horstmann
Batteries 4 (1), 5, 2018
Theory of impedance spectroscopy for lithium batteries
F Single, B Horstmann, A Latz
The Journal of Physical Chemistry C 123 (45), 27327-27343, 2019
Towards rechargeable zinc–air batteries with aqueous chloride electrolytes
S Clark, AR Mainar, E Iruin, LC Colmenares, JA Blázquez, JR Tolchard, ...
Journal of materials chemistry A 7 (18), 11387-11399, 2019
Designing aqueous organic electrolytes for zinc–air batteries: method, simulation, and validation
S Clark, AR Mainar, E Iruin, LC Colmenares, JA Blázquez, JR Tolchard, ...
Advanced Energy Materials 10 (10), 1903470, 2020
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