Chemical Looping Systems for Hydrogen Production and Their Implementation in Aspen Plus Software: A Review and Bibliometric Analysis

Vista sencilla de ítem
dc.contributor.affiliationVanegas E., Universidad de Medellín, Medellín, Colombia
dc.contributor.affiliationLuna-Delrisco M., Universidad de Medellín, Medellín, Colombia
dc.contributor.affiliationRocha-Meneses L., Estonian University of Life Sciences, Tartu, Estonia
dc.contributor.affiliationArrieta C.E., Universidad de Medellín, Medellín, Colombia
dc.contributor.affiliationSierra J., Instituto Tecnológico Metropolitano, Medellín, Colombia
dc.contributor.affiliationYepes H.A., Universidad Francisco de Paula Santander, Ocaña, Colombia
dc.contributor.authorVanegas E.
dc.contributor.authorLuna-Delrisco M.
dc.contributor.authorRocha-Meneses L.
dc.contributor.authorArrieta C.E.
dc.contributor.authorSierra J.
dc.contributor.authorYepes H.A.
dc.date.accessioned2025-09-08T14:23:47Z
dc.date.available2025-09-08T14:23:47Z
dc.date.issued2025
dc.descriptionHydrogen (H₂) production is a key strategy for reducing greenhouse gas emissions, providing a clean and efficient energy alternative. This review explores chemical looping combustion (CLC) for H₂ production, focusing on feedstocks, oxygen carriers (OCs), and process modeling in Aspen Plus®. A bibliometric analysis was conducted to support the review. Results indicate that methane (CH₄) outperforms biomass due to its higher efficiency and stable reaction behavior. Iron-and nickel-based oxides are the most effective OCs, with iron facilitating water splitting and nickel excelling in steam methane reforming (SMR) and chemical looping reforming (CLR). Enhancing OCs with support materials and sorbents improves system performance. Accurate simulations using Rgibbs and fluidized bed models are essential for optimizing the process. This study provides insights into improving H₂ production efficiency, contributing to advancements in clean energy technologies. © 2025 Tim Pengembang Jurnal UPI.
dc.identifier.doi10.17509/ijost.v10i2.82075
dc.identifier.instnameinstname:Universidad de Medellínspa
dc.identifier.issn25281410
dc.identifier.reponamereponame:Repositorio Institucional Universidad de Medellínspa
dc.identifier.repourlrepourl:https://repository.udem.edu.co/
dc.identifier.urihttp://hdl.handle.net/11407/9103
dc.language.isoeng
dc.publisher.facultyFacultad de Ingenieríasspa
dc.publisher.programIngeniería en Energíaspa
dc.relation.citationendpage284
dc.relation.citationissue2
dc.relation.citationstartpage249
dc.relation.citationvolume10
dc.relation.isversionofhttps://www.scopus.com/inward/record.uri?eid=2-s2.0-105005753070&doi=10.17509%2fijost.v10i2.82075&partnerID=40&md5=3086cf82769d7b9c99dbae6a434022f6
dc.relation.referencesCampbell B. M., Hansen J., Rioux J., Stirling C. M., Twomlow S., Urgent action to combat climate change and its impacts (SDG 13): Transforming agriculture and food systems, Current Opinion in Environmental Sustainability, 34, pp. 13-20, (2018)
dc.relation.referencesRamezani R., Di Felice L., Gallucci F., A review of chemical looping reforming technologies for hydrogen production: Recent advances and future challenges, Journal of Physics: Energy, 5, 2, (2023)
dc.relation.referencesLi J., Zhang H., Gao Z., Fu J., Ao W., Dai J., CO2 capture with chemical looping combustion of gaseous fuels: An overview, Energy and Fuels, 31, 4, pp. 3475-3524, (2017)
dc.relation.referencesJacobson T. A., Kler J. S., Hernke M. T., Braun R. K., Meyer K. C., Funk W. E., Direct human health risks of increased atmospheric carbon dioxide, Nature Sustainability, 2, 8, pp. 691-701, (2019)
dc.relation.referencesStoppacher B., Sterniczky T., Bock S., Hacker V., On-site production of high-purity hydrogen from raw biogas with fixed-bed chemical looping, Energy Conversion and Management, 268, (2022)
dc.relation.referencesLuo M., Yi Y., Wang S., Wang Z., Du M., Pan J., Wang Q., Review of hydrogen production using chemical-looping technology, Renewable and Sustainable Energy Reviews, 81, pp. 3186-3214, (2018)
dc.relation.referencesBanerjee S., Agarwal R., Transient reacting flow simulation of spouted fluidized bed for coal-direct chemical looping combustion with different Fe-based oxygen carriers, Applied Energy, 160, pp. 552-560, (2015)
dc.relation.referencesZhou L., Deshpande K., Zhang X., Agarwal R. K., Process simulation of chemical looping combustion using ASPEN plus for a mixture of biomass and coal with various oxygen carriers, Energy, 195, (2020)
dc.relation.referencesJasper M., Shahbazi A., Schimmel K., Li F., Wang L., Aspen Plus simulation of Chemical Looping Combustion of syngas and methane in fluidized beds, Discover Chemical Engineering, 3, 1, (2023)
dc.relation.referencesKappagantula R. V., Ingram G. D., Vuthaluru H. B., Application of aspen plus fluidized bed reactor model for chemical looping of synthesis gas, Fuel, 324, (2022)
dc.relation.referencesQi J., Liu J., Chen G., Yao J., Yan B., Yi W., Zao H., Xu S., Hydrogen production from municipal solid waste via chemical looping gasification using CuFe2O4 spinel as oxygen carrier: An Aspen Plus modeling, Energy Conversion and Management, 294, (2023)
dc.relation.referencesNandiyanto A. B. D., Ragadhita R., Fiandini M., Al Husaeni D. N., Aziz M., The role of iron oxide in hydrogen production: Theory and bibliometric analyses, Moroccan Journal of Chemistry, 11, pp. 897-916, (2023)
dc.relation.referencesRochman S., Rustaman N., Ramalis T. R., Amri K., Zukmadini A. Y., Ismail I., Putra A. H., How bibliometric analysis using VOSviewer is based on artificial intelligence data (using ResearchRabbit Data): Explore research trends in hydrology content, ASEAN Journal of Science and Engineering, 4, 2, pp. 251-294, (2024)
dc.relation.referencesAl Husaeni D. N., Al Husaeni D. F., How to calculate bibliometrics using vosviewer with publish or perish (using Scopus data): Science education keywords, Indonesian Journal of Educational Research and Technology, 2, 3, pp. 247-274, (2022)
dc.relation.referencesAl Husaeni D. F., Nandiyanto A. B. D., Bibliometric using Vosviewer with Publish or Perish (using Google Scholar data): From step-by-step processing for users to the practical examples in the analysis of digital learning articles in pre and post Covid-19 pandemic, ASEAN Journal of Science and Engineering, 2, 1, pp. 19-46, (2022)
dc.relation.referencesMarin-Rodriguez N. J., Vega J., Zanabria O. B., Gonzalez-Ruiz J. D., Botero S., Towards an understanding of landslide risk assessment and its economic losses: A scientometric analysis, Landslides, 21, 8, pp. 1865-1881, (2024)
dc.relation.referencesAugusto B., Rafael S., Coelho M. C., Ferreira J., Connecting the dots between urban morphology and the air quality of cities under a changing climate: A bibliometric analysis, Sustainability, 16, 1, (2024)
dc.relation.referencesLiu Y., Chen S., Yang B., Liu K., Zheng C., First and second thermodynamic-law comparison of biogas MILD oxy-fuel combustion moderated by CO2 or H2O, Energy Conversion and Management, 106, pp. 625-634, (2015)
dc.relation.referencesSurendra K. C., Takara D., Hashimoto A. G., Khanal S. K., Biogas as a sustainable energy source for developing countries: Opportunities and challenges, Renewable and Sustainable Energy Reviews, 31, pp. 846-859, (2014)
dc.relation.referencesKong F., Swift J., Zhang Q., Fan L. S., Tong A., Biogas to H2 conversion with CO2 capture using chemical looping technology: Process simulation and comparison to conventional reforming processes, Fuel, 279, (2020)
dc.relation.referencesRasi S., Veijanen A., Rintala J., Trace compounds of biogas from different biogas production plants, Energy, 32, 8, pp. 1375-1380, (2007)
dc.relation.referencesNahar G., Mote D., Dupont V., Hydrogen production from reforming of biogas: Review of technological advances and an Indian perspective, Renewable and Sustainable Energy Reviews, 76, pp. 1032-1052, (2017)
dc.relation.referencesZhao X., Joseph B., Kuhn J., Ozcan S., Biogas reforming to syngas: A review, IScience, 23, 5, pp. 1-46, (2020)
dc.relation.referencesMendiara T., Cabello A., Izquierdo M. T., Abad A., Mattisson T., Adanez J., Effect of the presence of siloxanes in biogas chemical looping combustion, Energy and Fuels, 35, 18, pp. 14984-14994, (2021)
dc.relation.referencesPandey B., Prajapati Y. K., Sheth P. N., Recent progress in thermochemical techniques to produce hydrogen gas from biomass: A state-of-the-art review, International Journal of Hydrogen Energy, 44, 47, pp. 25384-25415, (2019)
dc.relation.referencesZhao X., Zhou H., Sikarwar V. S., Zhao M., Park A. H. A., Fennell P. S., Shen L., Fan L. S., Biomass-based chemical looping technologies: The good, the bad and the future, Energy and Environmental Science, 10, 9, pp. 1885-1910, (2017)
dc.relation.referencesMarrugo G., Valdes C. F., Chejne F., Characterization of Colombian agroindustrial biomass residues as energy resources, Energy and Fuels, 30, 10, pp. 8386-8398, (2016)
dc.relation.referencesMercado J. P., Ubando A. T., Gonzaga J. A., Naqvi S. R., Life cycle assessment of a biomass based chemical looping combustion, Environmental Research, 217, (2023)
dc.relation.referencesAdanez-Rubio I., Abad A., Gayan P., De Diego L. F., Garcia-Labiano F., Adanez J., Biomass combustion with CO2 capture by chemical looping with oxygen uncoupling (CLOU), Fuel Processing Technology, 124, pp. 104-114, (2014)
dc.relation.referencesCoppola A., Scala F., Chemical looping for combustion of solid biomass: A review, Energy and Fuels, 35, 23, pp. 19248-19265, (2021)
dc.relation.referencesStenberg V., Ryden M., Mattisson T., Lyngfelt A., Exploring novel hydrogen production processes by integration of steam methane reforming with chemical-looping combustion (CLC-SMR) and oxygen carrier aided combustion (OCAC-SMR), International Journal of Greenhouse Gas Control, 74, pp. 28-39, (2018)
dc.relation.referencesMagdziarz A., Dalai A. K., Kozinski J. A., Chemical composition, character, and reactivity of renewable fuel ashes, Fuel, 176, pp. 135-145, (2016)
dc.relation.referencesAjorloo M., Ghodrat M., Scott J., Strezov V., Recent advances in thermodynamic analysis of biomass gasification: A review on numerical modelling and simulation, Journal of the Energy Institute, 102, pp. 395-419, (2022)
dc.relation.referencesPenthor S., Mayer K., Kern S., Kitzler H., Woss D., Proll T., Hofbauer H., Chemical-looping combustion of raw syngas from biomass steam gasification–Coupled operation of two dual fluidized bed pilot plants, Fuel, 127, pp. 178-185, (2014)
dc.relation.referencesSampron I., Cabello A., Garcia-Labiano F., Izquierdo M. T., de Diego L. F., An innovative Cu-Al oxygen carrier for the biomass chemical looping gasification process, Chemical Engineering Journal, 465, (2023)
dc.relation.referencesSalkuyeh Y. K., Saville B. A., MacLean H. L., Techno-economic analysis and life cycle assessment of hydrogen production from different biomass gasification processes, International Journal of Hydrogen Energy, 43, 20, pp. 9514-9528, (2018)
dc.relation.referencesGopaul S. G., Dutta A., Clemmer R., Chemical looping gasification for hydrogen production: A comparison of two unique processes simulated using ASPEN Plus, International Journal of Hydrogen Energy, 39, 11, pp. 5804-5817, (2014)
dc.relation.referencesNimmas T., Wongsakulphasatch S., Cheng C. K., Assabumrungrat S., Bi-metallic CuO-NiO based multifunctional material for hydrogen production from sorption-enhanced chemical looping autothermal reforming of ethanol, Chemical Engineering Journal, 398, (2020)
dc.relation.referencesGarcia-Diez E., Garcia-Labiano F., De Diego L. F., Abad A., Gayan P., Adanez J., Ruiz J. A. C., Optimization of hydrogen production with CO2 capture by autothermal chemical-looping reforming using different bioethanol purities, Applied Energy, 169, pp. 491-498, (2016)
dc.relation.referencesLi G., Zhang Z., You F., Pan Z., Zhang X., Dong J., Gao X., A novel strategy for hydrous-ethanol utilization: Demonstration of a spark-ignition engine fueled with hydrogen-rich fuel from an onboard ethanol/steam reformer, International journal of hydrogen energy, 38, 14, pp. 5936-5948, (2013)
dc.relation.referencesWang K., Dou B., Jiang B., Song Y., Zhang C., Zhang Q., Chen H., Xu Y., Renewable hydrogen production from chemical looping steam reforming of ethanol using xCeNi/SBA-15 oxygen carriers in a fixed-bed reactor, International Journal of Hydrogen Energy, 41, 30, pp. 12899-12909, (2016)
dc.relation.referencesAdanez-Rubio I., Ruiz J. A., Garcia-Labiano F., de Diego L. F., Adanez J., Use of bio-glycerol for the production of synthesis gas by chemical looping reforming, Fuel, 288, (2021)
dc.relation.referencesCharisiou N. D., Italiano C., Pino L., Sebastian V., Vita A., Goula M. A., Hydrogen production via steam reforming of glycerol over Rh/γ-Al2O3 catalysts modified with CeO2, MgO or La2O3, Renewable Energy, 162, pp. 908-925, (2020)
dc.relation.referencesJiang B., Dou B., Song Y., Zhang C., Du B., Chen H., Xu Y., Hydrogen production from chemical looping steam reforming of glycerol by Ni-based oxygen carrier in a fixed-bed reactor, Chemical Engineering Journal, 280, pp. 459-467, (2015)
dc.relation.referencesVoitic G., Hacker V., Recent advancements in chemical looping water splitting for the production of hydrogen, Rsc Advances, 6, 100, pp. 98267-98296, (2016)
dc.relation.referencesXu T., Jiang C., Wang X., Xiao B., Bio-oil chemical looping reforming coupled with water splitting for hydrogen and syngas coproduction: Effect of supports on the performance of Ni-Fe bimetallic oxygen carriers, Energy Conversion and Management, 244, (2021)
dc.relation.referencesKhan M. N., Shamim T., Investigation of hydrogen production using chemical looping reforming, Energy Procedia, 61, pp. 2034-2037, (2014)
dc.relation.referencesNadgouda S. G., Kathe M. V., Fan L. S., Cold gas efficiency enhancement in a chemical looping combustion system using staged H2 separation approach, International Journal of Hydrogen Energy, 42, 8, pp. 4751-4763, (2017)
dc.relation.referencesYang Q., Yan M., Zhang L., Xia X., Zhu Y., Zhang C., Zhao B., Xiaoxun M., Wang X., Thermodynamic analysis of chemical looping coupling process for coproducing syngas and hydrogen with in situ CO2 utilization, Energy Conversion and Management, 231, (2021)
dc.relation.referencesHe Y., Zhu L., Li L., Liu G., Hydrogen and power cogeneration based on chemical looping combustion: Is it capable of reducing carbon emissions and the cost of production?, Energy and Fuels, 34, 3, pp. 3501-3512, (2020)
dc.relation.referencesArgyris P. A., Wright A., Qazvini O. T., Spallina V., Dynamic behaviour of integrated chemical looping process with pressure swing adsorption in small scale on-site H2 and pure CO2 production, Chemical Engineering Journal, 428, (2022)
dc.relation.referencesAdanez-Rubio I., Garcia-Labiano F., Abad A., de Diego L. F., Adanez J., Synthesis gas and H2 production by chemical looping reforming using bio-oil from fast pyrolysis of wood as raw material, Chemical Engineering Journal, 431, (2022)
dc.relation.referencesYahom A., Powell J., Pavarajarn V., Onbhuddha P., Charojrochkul S., Assabumrungrat S., Simulation and thermodynamic analysis of chemical looping reforming and CO2 enhanced chemical looping reforming, Chemical Engineering Research and Design, 92, 11, pp. 2575-2583, (2014)
dc.relation.referencesLu C., Xu R., khan Muhammad I., Zhu X., Wei Y., Qi X., Li K., Thermodynamic evolution of magnetite oxygen carrier via chemical looping reforming of methane, Journal of Natural Gas Science and Engineering, 85, (2021)
dc.relation.referencesMiyahira K., Aziz M., Hydrogen and ammonia production from low-grade agricultural waste adopting chemical looping process, Journal of Cleaner Production, 372, (2022)
dc.relation.referencesAdanez J., Abad A., Garcia-Labiano F., Gayan P., De Diego L. F., Progress in chemical-looping combustion and reforming technologies, Progress in energy and combustion science, 38, 2, pp. 215-282, (2012)
dc.relation.referencesHu J., Zhang T., Zhang Q., Yan X., Zhao S., Dang J., Wang W., Application of calcium oxide/ferric oxide composite oxygen carrier for corn straw chemical looping gasification, Bioresource Technology, 330, (2021)
dc.relation.referencesLiu G., Lisak G., Cu-based oxygen carriers for chemical looping processes: Opportunities and challenges, Fuel, 342, (2023)
dc.relation.referencesde las Obras Loscertales M., Abad A., Garcia-Labiano F., Ruiz J. A., Adanez J., Reaction kinetics of a NiO-based oxygen carrier with ethanol to be applied in chemical looping processes, Fuel, 345, (2023)
dc.relation.referencesSun Z., Aziz M., Thermodynamic analysis of a tri-generation system driven by biomass direct chemical looping combustion process, Energy Conversion and Management, 244, (2021)
dc.relation.referencesYu Z., Yang Y., Yang S., Zhang Q., Zhao J., Fang Y., Xiaogang H., Guan G., Iron-based oxygen carriers in chemical looping conversions: A review, Carbon Resources Conversion, 2, 1, pp. 23-34, (2019)
dc.relation.referencesFang H., Haibin L., Zengli Z., Advancements in development of chemical-looping combustion: A review, International Journal of Chemical Engineering, 2009, 1, (2009)
dc.relation.referencesDi Z., Cao Y., Yang F., Zhang K., Cheng F., Thermodynamic analysis on the parametric optimization of a novel chemical looping methane reforming in the separated productions of H2 and CO, Energy Conversion and Management, 192, pp. 171-179, (2019)
dc.relation.referencesGao G., Lai Y., Wang S., Particle-resolved simulation of Fe-based oxygen carrier in chemical looping hydrogen generation, International Journal of Hydrogen Energy, 48, 89, pp. 34624-34633, (2023)
dc.relation.referencesRoslan N. A., Abidin S. Z., Ideris A., Vo D. V. N., A review on glycerol reforming processes over Ni-based catalyst for hydrogen and syngas productions, International Journal of Hydrogen Energy, 45, 36, pp. 18466-18489, (2020)
dc.relation.referencesZhu L., Xie N., Jiang P., Li L., Chen H., Double-stage chemical looping combustion combined with sorption enhanced natural gas steam reforming process for hydrogen and power cogeneration: Thermodynamic investigation, Chemical Engineering Research and Design, 114, pp. 247-257, (2016)
dc.relation.referencesStenberg V., Spallina V., Mattisson T., Ryden M., Techno-economic analysis of processes with integration of fluidized bed heat exchangers for H2 production–Part 2: Chemical-looping combustion, International Journal of Hydrogen Energy, 46, 50, pp. 25355-25375, (2021)
dc.relation.referencesDas S., Biswas A., Tiwary C. S., Paliwal M., Hydrogen production using chemical looping technology: A review with emphasis on H2 yield of various oxygen carriers, International Journal of Hydrogen Energy, 47, 66, pp. 28322-28352, (2022)
dc.relation.referencesChen X., Zou G., Yuan Y., Xu Z., Zhao H., Flame spray pyrolysis synthesized Ni-doped Fe/Ce oxygen carriers for chemical looping dry reforming of methane, Fuel, 343, (2023)
dc.relation.referencesHerrer M., Plou J., Duran P., Herguido J., Pena J. A., Hydrogen from synthetic biogas via SIP using NiAl2O4 catalyst: Reduction stage, International Journal of Hydrogen Energy, 40, 15, pp. 5244-5250, (2015)
dc.relation.referencesPlou J., Duran P., Herguido J., Pena J. A., Purified hydrogen from synthetic biogas by joint methane dry reforming and steam-iron process: Behaviour of metallic oxides and coke formation, Fuel, 118, pp. 100-106, (2014)
dc.relation.referencesLuo C., Dou B., Zhang H., Liu D., Zhao L., Chen H., Xu Y., Co-production of hydrogen and syngas from chemical looping water splitting coupled with decomposition of glycerol using Fe-Ce-Ni based oxygen carriers, Energy Conversion and Management, 238, (2021)
dc.relation.referencesHosseini S. Y., Khosravi-Nikou M. R., Shariati A., Production of hydrogen and syngas using chemical looping technology via cerium-iron mixed oxides, Chemical Engineering and Processing-Process Intensification, 139, pp. 23-33, (2019)
dc.relation.referencesWei G., Huang J., Fan Y., Huang Z., Zheng A., He F., Junguang M., Dongyan Z., Kun Z., Zenglin Z., Li H., Chemical looping reforming of biomass based pyrolysis gas coupling with chemical looping hydrogen by using Fe/Ni/Al oxygen carriers derived from LDH precursors, Energy Conversion and Management, 179, pp. 304-313, (2019)
dc.relation.referencesWang N., Guo X., Ma S., Feng Y., Understanding the synergistic effect of Ni/Al2O3 on CO2 adsorption and sintering properties of CaO in sorption-enhanced steam reforming process, Fuel, 341, (2023)
dc.relation.referencesNandy A., Loha C., Gu S., Sarkar P., Karmakar M. K., Chatterjee P. K., Present status and overview of chemical looping combustion technology, Renewable and Sustainable Energy Reviews, 59, pp. 597-619, (2016)
dc.relation.referencesAbbasi M., Farniaei M., Rahimpour M. R., Shariati A., Simultaneous syngas production with different H2/CO ratio in a multi-tubular methane steam and dry reformer by utilizing of CLC, Journal of Energy Chemistry, 24, 1, pp. 54-64, (2015)
dc.relation.referencesAlirezaei I., Hafizi A., Rahimpour M. R., Syngas production in chemical looping reforming process over ZrO2 promoted Mn-based catalyst, Journal of CO2 Utilization, 23, pp. 105-116, (2018)
dc.relation.referencesHossain M. M., de Lasa H. I., Chemical-looping combustion (CLC) for inherent CO2 separations—a review, Chemical Engineering Science, 63, 18, pp. 4433-4451, (2008)
dc.relation.referencesIdziak K., Czakiert T., Krzywanski J., Zylka A., Kozlowska M., Nowak W., Safety and environmental reasons for the use of Ni-, Co-, Cu-, Mn-and Fe-based oxygen carriers in CLC/CLOU applications: An overview, Fuel, 268, (2020)
dc.relation.referencesAbuelgasim S., Wang W., Abdalazeez A., A brief review for chemical looping combustion as a promising CO2 capture technology: Fundamentals and progress, Science of The Total Environment, 764, (2021)
dc.relation.referencesWang B., Li H., Wang W., Luo C., Mei D., Chemical looping combustion of lignite with the CaSO4–CoO mixed oxygen carrier, Journal of the Energy Institute, 93, 3, pp. 1229-1241, (2020)
dc.relation.referencesZheng M., Shen L., Feng X., In situ gasification chemical looping combustion of a coal using the binary oxygen carrier natural anhydrite ore and natural iron ore, Energy conversion and management, 83, pp. 270-283, (2014)
dc.relation.referencesWang B., Guo C., Xu B., Li X., Ma J., Ji J., Mei D., Zhao H., Synergistic reaction investigation of the NiO modified CaSO4 oxygen carrier with lignite for simultaneous CO2 capture and SO2 removal, Fuel Processing Technology, 220, (2021)
dc.relation.referencesSong T., Zheng M., Shen L., Zhang T., Niu X., Xiao J., Mechanism investigation of enhancing reaction performance with CaSO4/Fe2O3 oxygen carrier in chemical-looping combustion of coal, Industrial and Engineering Chemistry Research, 52, 11, pp. 4059-4071, (2013)
dc.relation.referencesDi Z., Yang F., Cao Y., Zhang K., Guo Y., Gao S., Cheng F., The transformation pathways on the catalytic and stability-promoted CaSO4 reduction in CLC process using Fe2O3 supported, Fuel, 253, pp. 327-338, (2019)
dc.relation.referencesHeidari M., Tahmasebpoor M., Antzaras A., Lemonidou A. A., CO2 capture and fluidity performance of CaO-based sorbents: Effect of Zr, Al and Ce additives in tri-, bi-and mono-metallic configurations, Process Safety and Environmental Protection, 144, pp. 349-365, (2020)
dc.relation.referencesZhu L., Li L., Fan J., A modified process for overcoming the drawbacks of conventional steam methane reforming for hydrogen production: Thermodynamic investigation, Chemical Engineering Research and Design, 104, pp. 792-806, (2015)
dc.relation.referencesGanesh I., A review on magnesium aluminate (MgAl2O4) spinel: Synthesis, processing and applications, International Materials Reviews, 58, 2, pp. 63-112, (2013)
dc.relation.referencesHafizi A., Rahimpour M. R., Inhibiting Fe–Al spinel formation on a narrowed mesopore-sized MgAl2O4 support as a novel catalyst for H2 production in chemical looping technology, Catalysts, 8, 1, (2018)
dc.relation.referencesNascimento R. A., Medeiros R. L., Costa T. R., Oliveira A. A., Macedo H. P., Melo M. A., Melo D. M., Mn/MgAl 2 O 4 oxygen carriers for chemical looping combustion using coal: Influence of the thermal treatment on the structure and reactivity, Journal of Thermal Analysis and Calorimetry, 140, pp. 2673-2685, (2020)
dc.relation.referencesCabello A., Dueso C., Garcia-Labiano F., Gayan P., Abad A., De Diego L. F., Adanez J., Performance of a highly reactive impregnated Fe2O3/Al2O3 oxygen carrier with CH4 and H2S in a 500 Wth CLC unit, Fuel, 121, pp. 117-125, (2014)
dc.relation.referencesHuang J., Liu W., Yang Y., Phase interactions in Mg-Ni-Al-O oxygen carriers for chemical looping applications, Chemical Engineering Journal, 326, pp. 470-476, (2017)
dc.relation.referencesLyngfelt A., Chemical looping combustion: Status and development challenges, Energy and Fuels, 34, 8, pp. 9077-9093, (2020)
dc.relation.referencesPorrazzo R., White G., Ocone R., Aspen Plus simulations of fluidised beds for chemical looping combustion, Fuel, 136, pp. 46-56, (2014)
dc.relation.referencesSinghal A., Cloete S., Quinta-Ferreira R., Amini S., Multiscale modeling of a packed bed chemical looping reforming (pbclr) reactor, Energies, 10, 12, (2017)
dc.relation.referencesBock S., Zacharias R., Hacker V., Co-production of pure hydrogen, carbon dioxide and nitrogen in a 10kW fixed-bed chemical looping system, Sustainable Energy and Fuels, 4, 3, pp. 1417-1426, (2020)
dc.relation.referencesLiu M., Li Y., Wang X., Gai Z., Rao Q., Yang T., Zhang J., Tang S., Pan Y., Jin H., Synergistic promotions between high purity H2 production and CO2 capture via sorption enhanced chemical looping reforming, Fuel Processing Technology, 254, (2024)
dc.relation.referencesWang I., Liu L., Yu S., Lai N. C., Gao Y., Li Z., Liu J., Wang W., Highly sintering-resistant iron oxide with a hetero-oxide shell for chemical looping water splitting, International Journal of Hydrogen Energy, 57, pp. 438-449, (2024)
dc.relation.referencesFarooqui A., Angal P., Shamim T., Santarelli M., Mahinpey N., Performance assessment of thermochemical CO2/H2O splitting in moving bed and fluidized bed reactors, International Journal of Hydrogen Energy, 46, 58, pp. 29774-29794, (2021)
dc.relation.referencesZhou Z., Han L., Bollas G. M., Overview of chemical-looping reduction in fixed bed and fluidized bed reactors focused on oxygen carrier utilization and reactor efficiency, Aerosol and Air Quality Research, 14, 2, pp. 559-571, (2014)
dc.relation.referencesHaider S. K., Duan L., Patchigolla K., Anthony E. J., A hydrodynamic study of a fast‐bed dual circulating fluidized bed for chemical looping combustion, Energy Technology, 4, 10, pp. 1254-1262, (2016)
dc.relation.referencesZhou K., Jia J., Li X., Pang X., Li C., Zhou J., Luo G., Wei F., Continuous vinyl chloride monomer production by acetylene hydrochlorination on Hg-free bismuth catalyst: From lab-scale catalyst characterization, catalytic evaluation to a pilot-scale trial by circulating regeneration in coupled fluidized beds, Fuel processing technology, 108, pp. 12-18, (2013)
dc.relation.referencesHsieh T. L., Xu D., Zhang Y., Nadgouda S., Wang D., Chung C., Pottimurthy Y., Guo M., Chen Y.-Y., Xu M., He P., Fan L.-S., Tong A., 250 kWth high pressure pilot demonstration of the syngas chemical looping system for high purity H2 production with CO2 capture, Applied Energy, 230, pp. 1660-1672, (2018)
dc.relation.referencesLan W., Chen G., Zhu X., Wang X., Liu C., Xu B., Biomass gasification-gas turbine combustion for power generation system model based on ASPEN PLUS, Science of the total environment, 628, pp. 1278-1286, (2018)
dc.relation.referencesDai X. P., Li R. J., Yu C. C., Hao Z. P., Unsteady-state direct partial oxidation of methane to synthesis gas in a fixed-bed reactor using AFeO3 (A= La, Nd, Eu) perovskite-type oxides as oxygen storage, The Journal of Physical Chemistry B, 110, 45, pp. 22525-22531, (2006)
dc.relation.referencesMoretti L., Arpino F., Cortellessa G., Di Fraia S., Di Palma M., Vanoli L., Reliability of equilibrium gasification models for selected biomass types and compositions: An overview, Energies, 15, 1, (2021)
dc.relation.referencesMutlu O. C., Zeng T., Challenges and opportunities of modeling biomass gasification in Aspen Plus: A review, Chemical Engineering and Technology, 43, 9, pp. 1674-1689, (2020)
dc.relation.referencesRyden M., Ramos P., H2 production with CO2 capture by sorption enhanced chemical-looping reforming using NiO as oxygen carrier and CaO as CO2 sorbent, Fuel Processing Technology, 96, pp. 27-36, (2012)
dc.relation.referencesMedrano J. A., Spallina V., van Sint Annaland M., Gallucci F., Thermodynamic analysis of a membrane-assisted chemical looping reforming reactor concept for combined H2 production and CO2 capture, International journal of hydrogen energy, 39, 9, pp. 4725-4738, (2014)
dc.relation.referencesRyden M., Lyngfelt A., Using steam reforming to produce hydrogen with carbon dioxide capture by chemical-looping combustion, International journal of hydrogen energy, 31, 10, pp. 1271-1283, (2006)
dc.relation.referencesKhan M. N., Shamim T., Investigation of hydrogen generation in a three-reactor chemical looping reforming process, Applied energy, 162, pp. 1186-1194, (2016)
dc.relation.referencesKathe M. V., Empfield A., Na J., Blair E., Fan L. S., Hydrogen production from natural gas using an iron-based chemical looping technology: Thermodynamic simulations and process system analysis, Applied Energy, 165, pp. 183-201, (2016)
dc.relation.referencesMeng W. X., Banerjee S., Zhang X., Agarwal R. K., Process simulation of multi-stage chemical-looping combustion using Aspen Plus, Energy, 90, pp. 1869-1877, (2015)
dc.relation.referencesAntzaras A. N., Heracleous E., Lemonidou A. A., Sorption enhanced– chemical looping steam methane reforming: Optimizing the thermal coupling of regeneration in a fixed bed reactor, Fuel Processing Technology, 208, (2020)
dc.relation.referencesFatigati F., Di Giuliano A., Carapellucci R., Gallucci K., Cipollone R., Experimental characterization and energy performance assessment of a sorption-enhanced steam–methane reforming system, Processes, 9, 8, (2021)
dc.relation.referencesWang W., Cao Y., A combined thermodynamic and experimental study on chemical‐looping ethanol reforming with carbon dioxide capture for hydrogen generation, International journal of energy research, 37, 1, pp. 25-34, (2013)
dc.relation.referencesAlam S., Sumana C., Thermodynamic analysis of plant-wide CLC-SESMR scheme for H2 production: Studying the effect of oxygen carrier supports, International Journal of Hydrogen Energy, 44, 5, pp. 3250-3263, (2019)
dc.relation.referencesHe Y., Zhu L., Li L., Sun L., Zero-energy penalty carbon capture and utilization for liquid fuel and power cogeneration with chemical looping combustion, Journal of Cleaner Production, 235, pp. 34-43, (2019)
dc.relation.referencesSurywanshi G. D., Patnaikuni V. S., Vooradi R., Anne S. B., 4-E and life cycle analyses of a supercritical coal direct chemical looping combustion power plant with hydrogen and power co-generation, Energy, 217, (2021)
dc.relation.referencesStenberg V., Spallina V., Mattisson T., Ryden M., Techno-economic analysis of H2 production processes using fluidized bed heat exchangers with steam reforming–Part 1: Oxygen carrier aided combustion, International Journal of Hydrogen Energy, 45, 11, pp. 6059-6081, (2020)
dc.relation.referencesSpallina V., Pandolfo D., Battistella A., Romano M. C., Annaland M. V. S., Gallucci F., Techno-economic assessment of membrane assisted fluidized bed reactors for pure H2 production with CO2 capture, Energy conversion and management, 120, pp. 257-273, (2016)
dc.relation.referencesMedrano J. A., Potdar I., Melendez J., Spallina V., Pacheco-Tanaka D. A., van Sint Annaland M., Gallucci F., The membrane-assisted chemical looping reforming concept for efficient H2 production with inherent CO2 capture: Experimental demonstration and model validation, Applied Energy, 215, pp. 75-86, (2018)
dc.relation.referencesGupta S. K., Mittal M., Analysis of cycle-to-cycle combustion variations in a spark-ignition engine operating under various biogas compositions, Energy and Fuels, 33, 12, pp. 12421-12430, (2019)
dc.relation.referencesPongboriboon N., Mariyappan V., Wu W., Chandra-Ambhorn W., Economic and environmental analyses for achieving net-zero CO2 emissions of a green diesel production process, Journal of the Taiwan Institute of Chemical Engineers, 165, (2024)
dc.relation.referencesBilal B., RaviKumar M., Workneh S., Study on simulation of biomass gasification for syngas production in a fixed bed reactor, International Journal of Scientific Research in Science and Technology, 4, 11, pp. 139-149, (2018)
dc.rights.accesoRestricted access
dc.rights.accessrightsinfo:eu-repo/semantics/restrictedAccess
dc.sourceIndonesian Journal of Science and Technology
dc.sourceIndones. J. Sci. Technol.
dc.sourceScopus
dc.subjectAspen plus
dc.subjectChemical looping
dc.subjectCO2 capture
dc.subjectFeedstock
dc.subjectHydrogen
dc.subjectOxygen carrier
dc.titleChemical Looping Systems for Hydrogen Production and Their Implementation in Aspen Plus Software: A Review and Bibliometric Analysis
dc.typeArticle
dc.type.localArtículospa
dc.type.versioninfo:eu-repo/semantics/publishedVersion

Archivos

Colecciones

Indexados Scopus