@misc{escorihuela_intensification_of_2022, 
author={Escorihuela, S., Cerdá-Moreno, C., Weigelt, F., Remiro-Buenamanana, S., Escolástico, S., Tena, A., Shishatskiy, S., Brinkmann, T., Chica, A., M. Serrra, J.},
title={Intensification of catalytic CO2 methanation mediated by in-situ water removal through a high-temperature polymeric thin-film composite membrane},
year={2022},
howpublished = {journal article},
doi = {https://doi.org/10.1016/j.jcou.2021.101813},
abstract = {Catalytic CO2 methanation technology can be improved by process intensification, i.e. enabling higher energy efficiency and process sustainability. Here, thin-film composite membranes (TFCM) were developed for in-situ water removal in a catalytic membrane reactor (CMR) for the Sabatier process. The selective separation layer (1.4 μm-thick) of the composite membrane is made of the polyimide 6FDA-6FpDA, a glassy polyimide, which exhibits high permeability and selectivity together with stable function at unprecedented high temperatures (>200 °C), compared to polyimides reported until now (90 °C), thus matching the temperature range of Sabatier reactors. Remarkably, TFCM developed in this work, allow to extract an outstanding amount of water up to 1 m3/(m2·h·bar) at 260 °C. TFCM was implemented for the water removal from the methanation reaction in a CMR operated at 260 °C and using Ni-Todorokite as catalyst. The TFCM-mediated water-extraction enabled to raise both catalytic stability and activity during CMR operation. CO2 conversion stability was greatly improved exhibiting a conversion value of 72 % during the course of the reaction (21 % increase in CO2 conversion), with a water removal of 12.5 % and specific flux of ∼100 g·h−1 m−2.},
note = {Online available at: \url{https://doi.org/10.1016/j.jcou.2021.101813} (DOI). Escorihuela, S.; Cerdá-Moreno, C.; Weigelt, F.; Remiro-Buenamanana, S.; Escolástico, S.; Tena, A.; Shishatskiy, S.; Brinkmann, T.; Chica, A.; M. Serrra, J.: Intensification of catalytic CO2 methanation mediated by in-situ water removal through a high-temperature polymeric thin-film composite membrane. Journal of CO2 Utilization. 2022. vol. 55, 101813. DOI: 10.1016/j.jcou.2021.101813}}