Volume 5 Issue 3 Cryoporometry for short T₂ samples: A T₁ filter method applied to battery electrode characterization
Published 01 December, 2025
The pore size distribution is often an important parameter for transport processes in porous media. Cryoporometry experiments can provide such data in the meso and macropore size up to 1 μm providing the sample temperature is finely controlled. We use a Peltier based system inserted directly into the NMR probe to control the temperature within 0.05 °C and impose temperature ramps down to 0.002 °C/min, necessary to characterize the largest pore sizes. The pore size information in the macropore range cannot be obtained from gas adsorption techniques while mercury injection is questionable for the material considered here. For porous materials made of paramagnetic minerals such as lithium-iron phosphate (LiFePO4, LFP) or nickel-manganese-cobalt oxides (NMC) and saturated with octamethylcyclotetrasiloxane (OMCTS), the T2 relaxation times are very short such as protons from the liquid and frozen phases cannot be separated. Hence the usual cryoporometry experiment cannot be performed. Instead, we propose to use the T1 contrast to separate these phases. The method is studied in detail along with some temperature effects linked with the T1 variation of the bulk frozen OMCTS. We show an example on two cathode materials part of industrial battery product.
Marc Fleury
Marc Fleury obtained an engineering degree in Physics at the Ecole Polytechnique de Lausanne (Switzerland), a PhD degree from the Fourier University of Grenoble (France) in Fluid Mechanics and a professorial thesis (HDR) in 2013. He joined IFP Energies nouvelles in 1992 and has been working in the field of Petrophysics and NMR since then. He received the SCA Darcy award in 2008 from the Society of Core Analysts for various innovative work. He uses NMR for the characterization of porous media for a large variety of applications (geothermal energy, CO2 storage, nuclear industry, catalysis, electrochemistry).
Thibaud Chevalier
Thibaud Chevalier received his PhD in Mechanical Engineering in 2013 under the guidance of P. Coussot from Paris-East University. After two postdoctoral stays, first with L. Talon at the University of Paris-South (now named Paris-Saclay University), and secondly with A. Puisto, M. Alava at Aalto University, and S. Santucci at ENS Lyon, he joined IFP Energies nouvelles in 2016 as a NMR research engineer in the Physics and Analysis Division. His research focused on the characterization of porous media and the transport of complex fluids for applications in new energies using low-field NMR approaches. Since 2024, he has been working in the Applied Physico-chemistry and Mechanics Division as a Fluid Mechanics Engineer, focusing on CO2 storage and geothermal energy.
Benjamin Nicot
Benjamin Nicot has a PhD in NMR petrophysics from IFP. He started his career with Schlumberger where he worked in research in Saudi Arabia, and in wireline acquisition in Brazil. In 2013 he joined Total and is now working in the area of special core analysis.
Quentin Denoyelle
Quentin Denoyelle received his engineering degree from Grenoble-INP Phelma in 2017. He obtained his PhD in 2021 from the University of Bordeaux, on lithium-ion solid-state micro-batteries. He is now a research engineer at Saft, Bordeaux, France. He is working on lithium-ion batteries, specifically on electrode formulation and process
Julien Bernard
Julien Bernard received the Engineering degree from the Ecole Nationale Supérieure d'Électrochimie et d'Électrométallurgie de Grenoble (ENSEEG) in 2002. He obtained his doctorate in electrochemistry from INP Grenoble in 2005. After a postdoctoral research period, he was recruited in 2007 by IFP Energies nouvelles within the Electrochemistry and Materials department to set up the research activities in the field of batteries for mobility. As Battery Project Manager for IFPEN's Mobility Business Unit since 2009, he is leading research activities on battery modelling and characterization.