magali gauthier

Magali GAUTHIER

Nanosciences et Innovation pour les Matériaux, la Biomédecine et l'Énergie - UMR CEA-CNRS NIMBE

Laboratoire d'Etude des Eléments Légers (LEEL)

+33 1 69 08 45 30
+33 1 69 08 69 23

orcid.org/0000-0002-8108-4597

Research ID: B-4590-2016

POSITION

CEA researcher since January 2016

RESEARCH INTERESTS

Magnesium-ion batteries
Metal-air batteries
Interfaces and aging mechanisms in electrochemical systems

CV

2014-2016 Postdoctoral associate, Massachusetts Institute of Technology (MIT), Cambridge, USA
2010-2013 PhD, University of Nantes, FRANCE and INRS University, Montreal, CANADA
2009-2010 Master 2 New and Renewable Energies, University of Nantes, FRANCE

AWARDS & DISTINCTIONS

Technological Innovation award and special award of the jury at the Energia Challenge, Quebec Association for the Control of Energy (AQME), 2015
Best thesis in cotutelle between France and Quebec 2014, Consulat of France in Quebec, 2014
“Student-researcher star” Award, Quebec’s research funding, 2013
Participation to the Lindau Nobel Laureates Meeting 2013 on chemistry
Best poster award, 3^rd German-French Summer School on Electrochemistry&Nanotechnologies, 2011

PUBLICATIONS

Mes publications récentes (base HAL CEA)

17. Reactivity with Water and Bulk Ruthenium Redox of Lithium Ruthenate in Basic Solutions, R. R. Rao, M. Tułodziecki, B. Han, M. Risch, A. Abakumov, Y. Yu, P. Karayaylali, M. Gauthier, M. Escudero‐Escribano, Y. Orikasa, Y. Shao‐Horn, Adv. Funct. Mater., https://doi.org/10.1002/adfm.202002249.

16. Electrochemical reactivity of In-Pb solid solution as a negative electrode for rechargeable Mg-ion batteries, L. Blondeau, S. Surblé, E. Foy, H. Khodja, M. Gauthier, Journal of Energy Chem., 55, 124-128 (2021)

15. Revealing Electronic Signature of Lattice Oxygen Redox in Lithium Ruthenates and Implications for High-Energy Li-ion Battery Material Designs.

Y. Yu, P. Karayaylali, S. H. Nowak, L. Giordano, M. Gauthier, W. Hong, R. Kou, Q. Li, J. Vinson, T. Kroll, D. Sokaras, C-J. Sun, N. Charles, F. Maglia, R. Jung, Y. Shao-Horn, Chem. Mater., 31, 7864–7876 (2019)

14. Unexpected Behavior of the InSb Alloy in Mg-Ion Batteries: Unlocking the Reversibility of Sb.

L. Blondeau, E. Foy, H. Khodja, M. Gauthier, J. Phys. Chem. C,123, 1120–1126 (2019)

13. Coupled LiPF6 decomposition and carbonate dehydrogenation enhanced by highly covalent metal oxides in high-energy Li-ion batteries.

Y. Yu, P. Karayaylali, Y. Katayama, L. Giodano, M. Gauthier, F. Maglia, R. Jung, I. Lund, Y. Shao-Horn, J. Phys. Chem. C, 122, 27368-27382 (2018)

12. Operando analysis of lithium profiles in Li-ion batteries using nuclear microanalysis.

S. Surblé, C. Paireau, J.-F. Martin, V. Tarnopolskiy, M. Gauthier, H. Khodja, L. Daniel, S. Patoux, J. Power Sources, 393, 37-42 (2018)

11. Probing surface chemistry changes using LiCoO₂-only electrodes in Li-Ion batteries.

M. Gauthier, P. Karayaylali, L. Giordano, S. Feng, S. F. Lux, F. Maglia, P. Lamp and Y. Shao-Horn, J .Electrochem. Soc., 7, 165, A1377-A1387 (2018)

10. One-Electron Mechanism in a Gel–Polymer Electrolyte Li–O₂ Battery.

C. V. Amanchukwu, H-H. Chang, M. Gauthier, S. Feng, T. P. Batcho and P. T. Hammond, Chem. Mater. 28, 19, 7167-7177 (2016)

9. Evaluation and stability of PEDOT polymer electrodes for Li–O₂ batteries.

C. V. Amanchukwu, M. Gauthier, T. P. Batcho, C. Symister, Y. Shao-Horn, J. M. D’Arcy and Paula T. Hammond, J. Phys. Chem. Lett. 7, 19, 3770-3775 (2016)

8. Electrode–electrolyte interface in Li-Ion batteries: current understanding and new insights.

M. Gauthier, T. J. Carney, A. Grimaud, L. Giordano, N. Pour, H-H. Chang, D. P. Fenning, S. Lux, O. Paschos, C. Bauer, F. Maglia, S. Lupart, P. Lamp and Y. Shao-Horn, J. Phys. Chem. Lett. 6, 4653 (2015)

7. Very high surface capacity with Si negative electrodes embedded in copper foam as 3D current collector.

D. Mazouzi, D. Reyter, M. Gauthier, P. Moreau, D. Guyomard, L. Roué and B. Lestriez, Adv. Energy Mater., 4, 1301718 (2014)

6. From Si wafers to cheap and efficient Si electrodes for Li-ion batteries.

M. Gauthier, S. Rousselot, D. Mazouzi, D. Reyter, B. Lestriez, P. Moreau, D. Guyomard and L. Roué, J. Power Sources, 256, 32 (2014)

5. Electrochemically roughened Cu current collector for Si-based electrode in Li-ion batteries.

D Reyter, S. Rousselot, D. Mazouzi, M. Gauthier, B. Lestriez, P. Moreau, D. Guyomard and L. Roué, J. Power Sources, 239, 308, (2013)

4. A low-cost and high-energy density Si-based negative electrode for Li-ion batteries.

M. Gauthier, D. Mazouzi, D. Reyter, B. Lestriez, P. Moreau, D. Guyomard and L. Roué, Energy Environ. Sci., 6, 2145, (2013)

3. Nanoscale compositional changes during first delithiation of Si negative electrodes.

M. Gauthier, J. Danet, B.Lestriez, L. Roué, D. Guyomard, P. Moreau, J. Power Sources, 227, 237, (2013)

2. New insights into the silicon-based electrode’s irreversibility along cycle life through simple gravimetric method.

D. Mazouzi, N. Delpuech, Y. Oumellal, M. Gauthier, M. Cerbelaud, P. Moreau, N. Dupré, J. Gaubicher, D. Guyomard, L. Roué and B. Lestriez, J. Power Sources, 220, 180, (2012)

1. Synthesis of boron-doped Si particles by ball milling and application in Li-ion batteries.

S. Rousselot, M. Gauthier, D. Mazouzi, B. Lestriez, D. Guyomard and L. Roué, J. Power Sources, 202, 262, (2012)