Perspectives for electrochemical capacitors and related devices
P. Simon and Y. Gogotsi Nature Materials (2020) doi:10.1038/s41563-020-0747-z.

A general Lewis acidic etching route for preparing MXenes with enhanced electrochemical performance in non-aqueous electrolyte
Y. Li, H. Shao, Z. Lin, J. Lu, L. Liu, B. Duployer, P. O. Å. Persson, P. Eklund, L. Hultman, M. Li, K. Chen, X.-H. Zha, S. Du, P. Rozier, Z. Chai, E. Raymundo-Piñero, P.L. Taberna, P. Simon*, Q. Huang*, Nature Materials 19,(2020) 894–899.

Fast Charging Materials for High Power Applications
B. Babu, P. Simon, A. Balducci, Advanced Energy Materials (2020) 10 2001128.

Dual-Cation Electrolytes for High-Power and High-Energy LTO//AC Hybrid Capacitors
Y. Chikaoka, E. Iwama, Ts. Ueda, N. Miyashita, S. Seto, M. Sakurai, W. Naoi, T. H. R. McMahon, P. Simon, and K. Naoi, J. Phys. Chem. C (2020), 124, 12230−12238.

MXenes as High-Rate Electrodes for Energy Storage
Z. Lin, H. Shao, K. Xu, P.L. Taberna and P. Simon, Trends in Chemistry 2 (7), (2020) 654-664.

Self-supported binder-free hard carbon electrodes for sodium-ion batteries: insights into their sodium storage mechanisms
A Beda, C Villevieille, P.L. Taberna, P Simon, CM Ghimbeu, Journal of Materials Chemistry A 8 (11), 5558-5571.

Nanoporous carbon for electrochemical capacitive energy storage
H. Shao, Y.-C. Wu, Z. Lin, P.-L. Taberna and P. Simon, Chemical Society Reviews 2020, 49, 3005-3039.

Interlayer gap widened α-phase molybdenum trioxide as high-rate anodes for dual-ion-intercalation energy storage devices
M. Yu, H. Shao, G. Wang, F. Yang, C. Liang, P. Rozier, C.-Z. Wang, X. Lu, P. Simon, X. Feng, Nature Communications 11, 1348 (2020).

Noncrystalline Nanocomposites as a Remedy for the Low Diffusivity of Multivalent Ions in Battery Cathodes
Y. Orikasa, K. Kisu, E. Iwama, W. Naoi, Y. Yamaguchi, Y. Yamaguchi, N. Okita, K. Ohara, T. Munesada, M.i Hattori, K. Yamamoto, P. Rozier, P. Simon, K. Naoi, Chemistry of Materials 2020, 32, 3, 1011–1021.

Ionic liquids under confinement: From systematic variations of the ion and pore sizes towards an understanding of structure and dynamics in complex porous carbons
H. El Lahrar, A. Belhboub, P. Simon, C. Merlet, ACS Appl. Mater. Interfaces 2020, 12, 1, 1789–1798.

Modifications of MXene layers for supercapacitors
Y. Zhu, K. Rajoo, S. Le Vot, O. Fontaine, P. Simon, F. Favier, Nano Energy (2020) 104734.

Facile and scalable preparation of RuO2-based flexible micro-supercapacitors
K. Brousse, S. Pinaud, S. Nguyen, P.F. Fazzini, R.Makarem, R. C. Josse, Y. Thimont, B. Chaudret, P.L. Taberna, M. Respaud and P. Simon, Advanced Energy Materials (2019) 1903136.

In-situ magnetic resonance probing of a complete supercapacitor giving additional insights of the role of nanopores
G. Oukali, E. Salager, M. Ramzi Ammar, C.-E. Dutoit, V. Sarou-Kanian, P. Simon, E. Raymundo-Piñero, M. Deschamps, ACS Nano 11 (2019) 12810-12815.

Charge Storage Mechanisms of Single Layer Graphene in Ionic Liquid
J. Ye, Y.-C. Wu, K. Xu, K. Ni, N. Shu, P.-L. Taberna, Y. Zhu and P. Simon Journal of the American Chemical Society 141 (42) (2019) 16559-16563.

On the development of an original mesoscopic model to predict the capacitive properties of carbon-carbon supercapacitors
A. Belhboub; E. H. Lahrar; P. Simon, C. Merlet Electrochimica Acta 327, 10 (2020), 110586.

Non - electrochemical Na – deintercalation from O3NaVO2
D. Iermakova, P. Rozier, J. Y. Chane-Ching, P. -L. Taberna , P. Simon, Materials Research Bulletin 121, (2020), 110586.