Vasily Artemov
EPFL STI IBI-STI LBEN
BM 2124 (Bâtiment BM)
Station 17
1015 Lausanne
Web site: Web site: https://lben.epfl.ch/
Fields of expertise
Broadband Dielectric and Terahertz Spectroscopy (📡)
Fuel cells, Batteries, Supercapacitors (🔋)
Electrodynamics of water and ice (💧❄️)
Soft matter dynamics (🧊)
Aqueous interfaces (🌊)
Complex systems (🧩)
Electrochemistry (⚡)
Nanofluidics (🌌)
Fuel cells, Batteries, Supercapacitors (🔋)
Electrodynamics of water and ice (💧❄️)
Soft matter dynamics (🧊)
Aqueous interfaces (🌊)
Complex systems (🧩)
Electrochemistry (⚡)
Nanofluidics (🌌)
Biography
My research focuses on understanding aqueous interfaces and developing electrochemical technologies for clean and sustainable energy generation, conversion, and storage, including the water-energy nexus and water-cleaning systems. My goal is to develop new paradigms in electrochemical material design using fundamental knowledge of water and aqueous interfaces from atomic to device scale and linking basics to applications.Education:
🎓 Masters - Moscow Institute of Physics and Technology - 2007.
🎓 Ph.D. - Prokhorov Institute of General Physics - 2011.
Research Focus:
🔬 Fundamental Properties of Water
🔬 Electrodynamics of Water and Ice
🔬 Broadband Dielectric and Terahertz Spectroscopy
🔬 Nanofluidics
🔬 Electrochemical Systems for Energy Generation and Storage
Published Author:
📚 Vasily Artemov "Electrodynamics of Water and Ice" Springer 2021.
Join me in the relentless pursuit of knowledge and groundbreaking innovation in water science, electrochemistry, and sustainable energy solutions.
Education
Ph. D.
Condensed matter physics
Prokhorov Institute of General Physics (GPI)
2011
Master
Applied Physics and Mathematics (graduated with honors)
Moscow Institute of Physics and Technology (MIPT)
2007
Publications
Selected publications
| V. Artemov Springer Series in Chemical Physics 124, 2021 |
The Electrodynamics of Water and Ice (book) |
| S. Melnik, A. Ryzhov, A. Kiselev, A. Radenovic, T. Weil, K. J. Stevenson, and V. Artemov J. Phys. Chem. Lett. 14, 29, 6572-6576 (2023) |
Confinement-Controlled Water Engenders Unusually High Electrochemical Capacitance |
| V. Artemov, L. Frank, R. Doronin, P. Stärk, A. Schlaich, A. Andreev, T. Leisner, A. Radenovic, and A. Kiselev J. Phys. Chem. Lett. 14, 20, 4796-4802 (2023) |
The Three-Phase Contact Potential Difference Modulates the Water Surface Charge |
| V. Artemov, A. Ryzhov, H. Ouerdane, K. J. Stevenson J. Phys. Chem. B 127, 1, 261-268 (2023) |
Ionization Difference between Weak and Strong Electrolytes as Perturbed by Conductivity Spectra Analysis |
| V. Artemov, E. Uykur, S. Roh, A. Pronin, H. Ouerdane, and M. Dressel Scientific Reports, 10, 11320 (2020). |
Revealing excess protons in the infrared spectrum of liquid water |
| V. Artemov, E. Uykur, P. O. Kapralov, A. Kiselev, K. Stevenson, H. Ouerdane, M. Dressel J. Phys. Chem. Lett., 11, 3623-3628 (2020) |
Anomalously High Proton Conduction of Interfacial Water |
| V. Artemov Phys. Chem. Chem. Phys., 21, pp. 8067 – 8072 (2019) |
A unified mechanism for ice and water electrical conductivity from direct current to terahertz |
| V. Artemov et al. Eur. Phys. Lett. 109, 26002 (2016) |
Conductivity of aqueous HCl, NaOH and NaCl solutions: Is water just a substrate? |