Runge-Metzger, A., A clean planet for all a European strategic long term vision for a prosperous, modern, competitive and climate neutral economy. 2018.
Chauvy, R., Meunier, N., Thomas, D., de Weireld, G., Selecting emerging CO2 utilization products for short- to mid-term deployment. Appl Energy 236 (2019), 662–680, 10.1016/J.APENERGY.2018.11.096.
EMBER, Carbon price tracker. https://ember-climate.org/data/data-tools/carbon-price-viewer/, 2023 (accessed March 13, 2023).
Theo, W.L., Lim, J.S., Hashim, H., Mustaffa, A.A., Ho, W.S., Review of pre-combustion capture and ionic liquid in carbon capture and storage. Appl Energy 183 (2016), 1633–1663, 10.1016/J.APENERGY.2016.09.103.
Hu, Y., Yan, J., Characterization of flue gas in oxy-coal combustion processes for CO2 capture. Appl Energy 90 (2012), 113–121, 10.1016/J.APENERGY.2011.03.005.
Dubois, L., Thomas, D., Comparison of various configurations of the absorption-regeneration process using different solvents for the post-combustion CO2 capture applied to cement plant flue gases. Int J Greenh Gas Control 69 (2018), 20–35, 10.1016/j.ijggc.2017.12.004.
Brandl, P., Bui, M., Hallett, J.P., mac Dowell N., Beyond 90% capture: possible, but at what cost?. Int J Greenh Gas Control, 2021, 105, 10.1016/j.ijggc.2020.103239.
Ben-Mansour, R., Habib, M.A., Bamidele, O.E., Basha, M., Qasem, N.A.A., Peedikakkal, A., et al. Carbon capture by physical adsorption: materials, experimental investigations and numerical modeling and simulations – a review. Appl Energy 161 (2016), 225–255, 10.1016/J.APENERGY.2015.10.011.
Castel, C., Bounaceur, R., Favre, E., Membrane processes for direct carbon dioxide capture from air: possibilities and limitations. Front Chem Eng, 2021, 3, 10.3389/fceng.2021.668867.
Voldsund, M., Gardarsdottir, S.O., De Lena, E., Pérez-Calvo, J.F., Jamali, A., Berstad, D., et al. Comparison of technologies for CO2 capture from cement production—part 1: technical evaluation. Energies (Basel), 12, 2019, 559, 10.3390/en12030559.
Onyeaka, H., Miri, T., Obileke, K., Hart, A., Anumudu, C., Al-Sharify, Z.T., Minimizing carbon footprint via microalgae as a biological capture. Carbon Capture Sci Technol, 1, 2021, 100007, 10.1016/j.ccst.2021.100007.
Xia, L., Lenaghan, S.C., Zhang, M., Wu, Y., Zhao, X., Burris, J.N., et al. Characterization of English ivy (Hedera helix) adhesion force and imaging using atomic force microscopy. J Nanopart Res 13 (2011), 1029–1037, 10.1007/s11051-010-0091-3.
Krzywanski, J., Ashraf, W.M., Czakiert, T., Sosnowski, M., Grabowska, K., Zylka, A., et al. CO2 capture by virgin ivy plants growing up on the external covers of houses as a rapid complementary route to achieve global GHG reduction targets. Energies (Basel), 2022, 15, 10.3390/en15051683.
Lockwood, T., Developments in oxyfuel combustion of coal. 2014, IEA Clean Coal Centre.
Kolster, C., Mechleri, E., Krevor, S., Mac, Dowell N., The role of CO2 purification and transport networks in carbon capture and storage cost reduction. Int J Greenh Gas Control 58 (2017), 127–141, 10.1016/j.ijggc.2017.01.014.
Jin, B., Zhao, H., Zheng, C., Optimization and control for CO2 compression and purification unit in oxy-combustion power plants. Energy 83 (2015), 416–430, 10.1016/j.energy.2015.02.039.
Magli, F., Spinelli, M., Fantini, M., Romano, M.C., Gatti, M., Techno-economic optimization and off-design analysis of CO2 purification units for cement plants with oxyfuel-based CO2 capture. Int J Greenh Gas Control, 115, 2022, 103591, 10.1016/j.ijggc.2022.103591.
Luyben, W.L., Simple control structure for a compression purification process in an oxy-combustion power plant. AIChE J 61 (2015), 1581–1588, 10.1002/aic.14754.
Koohestanian, E., Sadeghi, J., Mohebbi Kalhori, D., Shahraki, F., Samimi, A., New process flowsheet for CO2 compression and purification unit; dynamic investigation and control. J Chem Chem Eng Res 40 (2021), 593–604, 10.30492/ijcce.2020.37779.
Shah, M.M., Carbon dioxide (CO2) compression and purification technology for oxy-fuel combustion. Oxy-fuel combustion for power generation and carbon dioxide (CO2) capture. 2011, Woodhead Publishing Limited, 228–255, 10.1533/9780857090980.2.228.
Jin, B., Zhao, H., Zheng, C., Thermoeconomic cost analysis of CO2 compression and purification unit in oxy-combustion power plants. Energ Conver Manage 106 (2015), 53–60, 10.1016/j.enconman.2015.09.014.
Li, H., Hu, Y., Ditaranto, M., Willson, D., Yan, J., Optimization of cryogenic CO2 purification for oxy-coal combustion. Energy Procedia 37 (2013), 1341–1347, 10.1016/j.egypro.2013.06.009.
Phillips, I., Tucker, A., Granstrom, P.-O., Bozzini, G., Gent, C., Capello, P.J., et al. Network technology: Guidance for CO2 transport by ship. 2022.
Chambron, N., Terrien, P., Capture de CO2 par unité cryogénique sur une centrale de type gazéification intégrée à cycle combiné. FR2997866A3, 2014.
Béasse, G., Bourhy-Weber, C., Daeden, S., Granados, L., Lockwood, F., Moreschini, P., et al. Callide oxyfuel project callide oxyfuel project results from the CPU. Ponferrada, 2013.
Stanley, M.W., Selection and design, Butterwoths series in chemical engineering. Chemical process equipment. 1990.
Thome, J., Alpema - the standards of the brazed aluminium plate-fin heat exchanger manufacturers’ association. 2021.
Fanchon, K., Modélisation d'un module de perméation en phase gazeuse pour utilisation dans le logiciel de simulation Hysys. 1998, UMons.
Fernandes, Rodrigues D., Model development of a membrane gas permeation unit for the separation of hydrogen and carbon. 2009.
Gorissen, H., Temperature changes involved in membrane gas separations. Chem Eng Process 22 (1987), 63–67, 10.1016/0255-2701(87)80032-6.
Kulkarni, S., Hasse, D., Sanders, E., Chaubey, T., CO2 capture by sub-ambient membrane operation. 2013.
Hao, J., Tanaka, K., Kita, H., Okamoto, K.-I., Synthesis and properties of polyimides from thianthrene-2,3,7,8-tetracarboxylic dianhydride-5,5,10,10-tetraoxide. J Polym Sci A Polym Chem 36 (1998), 485–494, 10.1002/(SICI)1099-0518(199802)36:3<485::AID-POLA12>3.0.CO;2-J.
Laribi, S., Dubois, L., Duprez, M.E., De Weireld, G., Thomas, D., Simulation of the sour-compression unit (SCU) process for CO2 purification applied to flue gases coming from oxy-combustion cement industries. Comput Chem Eng 121 (2019), 523–539, 10.1016/j.compchemeng.2018.11.010.
Murciano, L.T., White, V., Petrocelli, F., Chadwick, D., Sour compression process for the removal of SOx and NOx from oxyfuel-derived CO2. Energy Procedia 4 (2011), 908–916, 10.1016/j.egypro.2011.01.136 Elsevier Ltd.
Chen, H., Wu, W., Chen, D., Feng, Y., Comparative study of carbon-deNOx process by different sewage sludge chars. Chemosphere, 318, 2023, 137981, 10.1016/j.chemosphere.2023.137981.
Deng, Ansart, Baeyens, Zhang, Flue gas desulphurization in circulating fluidized beds. Energies (Basel), 12, 2019, 3908, 10.3390/en12203908.
Miller, B.G., Emissions control strategies for power plants. Clean coal engineering technology. 2011, Elsevier, 375–481, 10.1016/b978-1-85617-710-8.00009-1.
Robinson, D.B., Peng, D.-Y., The characterization of the heptanes and heavier fractions for the GPA Peng-Robinson programs. 1978, Gas processors association.
Lasala, S., Chiesa, P., Privat, R., Jaubert, J.N., VLE properties of CO2 – based binary systems containing N2, O2 and Ar: experimental measurements and modelling results with advanced cubic equations of state. Fluid Phase Equilib 428 (2016), 18–31, 10.1016/J.FLUID.2016.05.015.
Privat, R., Mutelet, F., Jaubert, J.-N., Addition of the hydrogen sulfide group to the PPR78 model (Predictive 1978, Peng–Robinson equation of state with temperature dependent k ij calculated through a group contribution method). Ind Eng Chem Res 47 (2008), 10041–10052, 10.1021/ie800799z.
Xu, X., Privat, R., Jaubert, J.-N., Addition of the sulfur dioxide group (SO2), the oxygen group (O2), and the nitric oxide group (NO) to the E-PPR78 model. Ind Eng Chem Res 54 (2015), 9494–9504, 10.1021/acs.iecr.5b02639.
Rezk, A., Al-Dadah, R., Mahmoud, S., Elsayed, A., Characterisation of metal organic frameworks for adsorption cooling. Int J Heat Mass Transf 55 (2012), 7366–7374, 10.1016/J.IJHEATMASSTRANSFER.2012.07.068.
Ghannadzadeh, A., Thery-Hetreux, R., Baudouin, O., Baudet, P., Floquet, P., Joulia, X., General methodology for exergy balance in ProSimPlus® process simulator. Energy 44 (2012), 38–59, 10.1016/j.energy.2012.02.017.
Kotas, T.J., Tadeusz, J., The exergy method of thermal plant analysis. 1985, Butterworths.
Szargut, J., Chemical exergies of the elements. Appl Energy 32 (1989), 269–286, 10.1016/0306-2619(89)90016-0.
Rivero, R., Garfias, M., Standard chemical exergy of elements updated. Energy 31 (2006), 3310–3326, 10.1016/J.ENERGY.2006.03.020.
Turton, R., Shaeiwitz, J.A., Bhattacharyya, D., Whiting, W.B., Analysis, synthesis, and design of chemical processes. 2018, Pearson Education, Inc.
Yang, Y., Chen, Y., Xu, Z., Wang, L., Zhang, P., A three-bed six-step TSA cycle with heat carrier gas recycling and its model-based performance assessment for gas drying. Sep Purif Technol, 237, 2020, 116335, 10.1016/J.SEPPUR.2019.116335.
EMBER, Wholesale electricity prices in Europe. https://ember-climate.org/data/data-tools/europe-power-prices/, 2023 (accessed July 17, 2023).
StatBel, Statistique quadri-annuelle sur le coût de la main-d'oeuvre. n.d https://statbel.fgov.be/fr/themes/emploi-formation/salaires-et-cout-de-la-main-doeuvre/cout-de-la-main-doeuvre#documents.
Chauvy, R., Dubois, L., Lybaert, P., Thomas, D., De Weireld, G., Production of synthetic natural gas from industrial carbon dioxide. Appl Energy, 260, 2020, 114249, 10.1016/J.APENERGY.2019.114249.
Goldberg, David E., Genetic algorithms in search, optimization, and machine learning. 1989, Addison-Wesley Professional.
Deb, K., Multi-objective optimization using evolutionary algorithms: An introduction. 2011.
Rubinstein, R.Y., Kroese, D.P., Simulation and the Monte Carlo method. 2007, John Wiley & Sons, Inc., Hoboken, NJ, USA, 10.1002/9780470230381.
Deng, Z., Hu, X., Lin, X., Che, Y., Xu, L., Guo, W., Data-driven state of charge estimation for lithium-ion battery packs based on Gaussian process regression. Energy, 205, 2020, 118000, 10.1016/J.ENERGY.2020.118000.
Richard, B., Cremona, C., Adelaide, L., A response surface method based on support vector machines trained with an adaptive experimental design. Struct Saf 39 (2012), 14–21, 10.1016/J.STRUSAFE.2012.05.001.
Coppitters, D., de Paepe, W., Contino, F., Robust design optimization of a photovoltaic-battery-heat pump system with thermal storage under aleatory and epistemic uncertainty. Energy, 229, 2021, 120692, 10.1016/j.energy.2021.120692.
Rixhon, X., Limpens, G., Coppitters, D., Jeanmart, H., Contino, F., The role of electrofuels under uncertainties for the belgian energy transition. Energies, 14, 2021, 4027, 10.3390/EN14134027.
Coppitters, D., Tsirikoglou, P., de Paepe, W., Kyprianidis, K., Kalfas, A., Contino, F., RHEIA: robust design optimization of renewable hydrogen and dErIved energy cArrier systems. J Open Source Softw, 2022, 7, 10.21105/joss.04370.
Sudret, B., Global sensitivity analysis using polynomial chaos expansions. Reliab Eng Syst Saf 93 (2008), 964–979, 10.1016/J.RESS.2007.04.002.
Coppitters, D., Verleysen, K., de Paepe, W., Contino, F., How can renewable hydrogen compete with diesel in public transport? Robust design optimization of a hydrogen refueling station under techno-economic and environmental uncertainty. Appl Energy, 2022, 312, 10.1016/J.APENERGY.2022.118694.
International Renewable Energy Agency, Renewable power generation costs in 2021. 2022.
