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Surface reactivity of Li2MnO3: Structural and morphological impact
(Applied Surface Science. vol. 542, pp. 148514, 2021)Article de revue -
Effect of particle size on LiNi0.6Mn0.2Co0.2O2 layered oxide performance in Li-Ion batteries
(ACS Applied Energy Materials. vol. 5, n° 5, pp. 5617–5632, 2022)Article de revue -
Relating the electrochemical behavior of Birnessite to the morphology and specific surface: interest of studying the surface reactivity
(ACS Applied Energy Materials. vol. 5, n° 10, pp. 12359-12372, 2022-10-24)Article de revue -
A direct evidence of solute interactions with a moving ferrite/austenite interface in a model Fe-C-Mn alloy
(Scripta Materialia. vol. 121, pp. 61-65, 2016)Article de revue -
Surface reactivity of Li2MnO3: first-principles and experimental study
(ACS Applied Materials & Interfaces. vol. 9, n° 50, pp. 44222-44230, 2017)Article de revue -
Surface reactivity and surface characterization of the layered β(III)-CoOOH material: an experimental and computational study
(Journal of Physical Chemistry C. vol. 125, n° 16, pp. 8570-8581, 2021)Article de revue -
Reactivity at the electrode-electrolyte interfaces in Li-ion and gel electrolyte lithium batteries for LiNi0.6Mn0.2Co0.2O2 with different particle sizes
(ACS Applied Materials & Interfaces. vol. 5, n° 5, pp. 5617–5632., 2022)Article de revue -
Microstructures resulting from the interaction between ferrite recrystallization and austenite formation in dual-phase steels
(Journal of Materials Science. vol. 50, n° 1, pp. 374-381, 2015)Article de revue -
La précipitation à la solidification du monoborure de titane dans l'alliage de titane (Ti-6Al-4V) peut-elle modifier sa microstructure et son comportement mécanique ?
(Université Sciences et Technologies - Bordeaux I)Thèses de doctorat -
Lithium secondary batteries working at very high temperature: capacity fade and understanding of aging mechanisms
(Journal of Power Sources. vol. 236, pp. 265-275, 2013)Article de revue