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Journal articles on the topic 'CO2 capture and utilization'

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Author: Grafiati
Published: 14 March 2023

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1

Fernández, José R., Susana Garcia, and Eloy S. Sanz-Pérez. "CO2 Capture and Utilization Editorial." Industrial & Engineering Chemistry Research 59, no. 15 (April 15, 2020): 6767–72. http://dx.doi.org/10.1021/acs.iecr.0c01643.

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2

S. P. R. Arachchige, Udara, Dinesh Kawan, Lars André Tokheim, and Morten C. Melaaen. "Waste Heat Utilization for CO2 Capture in the Cement Industry." International Journal of Modeling and Optimization 4, no. 6 (December 2014): 438–42. http://dx.doi.org/10.7763/ijmo.2014.v4.414.

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3

Tian, Sicong, Feng Yan, Zuotai Zhang, and Jianguo Jiang. "Calcium-looping reforming of methane realizes in situ CO2 utilization with improved energy efficiency." Science Advances 5, no. 4 (April 2019): eaav5077. http://dx.doi.org/10.1126/sciadv.aav5077.

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Closing the anthropogenic carbon cycle is one important strategy to combat climate change, and requires the chemistry to effectively combine CO2 capture with its conversion. Here, we propose a novel in situ CO2 utilization concept, calcium-looping reforming of methane, to realize the capture and conversion of CO2 in one integrated chemical process. This process couples the calcium-looping CO2 capture and the CH4 dry reforming reactions in the CaO-Ni bifunctional sorbent-catalyst, where the CO2 captured by CaO is reduced in situ by CH4 to CO, a reaction catalyzed by catalyzed by the adjacent metallic Ni. The process coupling scheme exhibits excellent decarbonation kinetics by exploiting Le Chatelier’s principle to shift reaction equilibrium through continuous conversion of CO2, and results in an energy consumption 22% lower than that of conventional CH4 dry reforming for CO2 utilization. The proposed CO2 utilization concept offers a promising option to recycle carbon directly at large CO2 stationary sources in an energy-efficient manner.
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4

Orr, Franklin M. "Carbon Capture, Utilization, and Storage: An Update." SPE Journal 23, no. 06 (December 13, 2018): 2444–55. http://dx.doi.org/10.2118/194190-pa.

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Summary Recent progress in carbon capture, utilization, and storage (CCUS) is reviewed. Considerable research effort has gone into carbon dioxide (CO2) capture, with many promising separation processes in various stages of development, but only a few have been tested at commercial scale, and considerable additional development will be required to determine competitiveness of new technologies. Processes for direct capture of CO2 from the air are also under development and are starting to be tested at pilot scale. Transportation of CO2 to storage sites by pipeline is well-established, though substantially more pipeline capacity will be required if CCUS is to be undertaken at a large scale. Considerable experience has now been built up in enhanced-oil-recovery (EOR) operations, which have been under way since the 1970s. Storage in deep saline aquifers has also been achieved at scale. Recent large-scale projects that capture and store CO2 are described, as are current and potential future markets for CO2. Potential effects of changes in the US tax code Section 45Q on those markets are summarized. Future deployment of CCUS will depend more on cost reductions for CO2 separations, development of new markets for CO2, and the complexities of project finance than on technical issues associated with storage of CO2 in the subsurface.
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5

Shcherbyna, Yevhen, Oleksandr Novoseltsev, and Tatiana Evtukhova. "Overview of carbon capture, utilisation and storage technologies to ensure low-carbon development of energy systems." System Research in Energy 2022, no. 2 (December 27, 2022): 4–12. http://dx.doi.org/10.15407/srenergy2022.02.004.

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Carbon dioxide CO2 is a component of air that is responsible for the growing global warning and greenhouse gases emissions. The energy sector is one of the main sources of CO2 emissions in the world and especially in Ukraine. Carbon capture, utilization and storage (CCUS) is a group of technologies that play a significant role along with renewable energy sources, bioenergy and hydrogen to reduce CO2 emissions and to achieve international climate goals. Nowadays there are thirty-five commercial CCUS facilities under operation around the world with a CO2 capture capacity up to 45 million tons annually. Tougher climate targets and increased investment provide new incentives for CCUS technologies to be applied more widely. CCUS are applications in which CO2 is captured from anthropogenic sources (power generation and industrial processes) and stored in deep geological formations without entering atmosphere or used in various products using technologies without chemical modification or with conversion. The article discusses the use of various technologies of CO2 capture (post-combustion capture, pre-combustion capture and oxy-combustion capture), CO2 separation methods and their application in the global energy transition to reduce the carbon capacity of energy systems. Technical and economic indicators of CO2 capture at different efficiencies for coal and gas power plants are given. Technologies of transportation and storage of captured carbon dioxide and their economic indicators are considered. The directions for the alternative uses of captured CO2, among which the main ones are the production of synthetic fuels, various chemicals and building materials, are also presented and described in the paper. The possibility of utilization captured СО2 in the production of synthetic fuel in combination with Power-to-Gas technologies was studied. Keywords: greenhouse gases emissions, fossil fuels, СО2 capture technologies, capture efficiency, synthetic fuel
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6

Jiang, L., W. Liu, R. Q. Wang, A. Gonzalez-Diaz, M. F. Rojas-Michaga, S. Michailos, M. Pourkashanian, X. J. Zhang, and C. Font-Palma. "Sorption direct air capture with CO2 utilization." Progress in Energy and Combustion Science 95 (March 2023): 101069. http://dx.doi.org/10.1016/j.pecs.2022.101069.

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7

Podder, Jiban, Biswa R. Patra, Falguni Pattnaik, Sonil Nanda, and Ajay K. Dalai. "A Review of Carbon Capture and Valorization Technologies." Energies 16, no. 6 (March 9, 2023): 2589. http://dx.doi.org/10.3390/en16062589.

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Global fossil fuel consumption has induced emissions of anthropogenic carbon dioxide (CO2), which has emanated global warming. Significant levels of CO2 are released continually into the atmosphere from the extraction of fossil fuels to their processing and combustion for heat and power generation including the fugitive emissions from industries and unmanaged waste management practices such as open burning of solid wastes. With an increase in the global population and the subsequent rise in energy demands and waste generation, the rate of CO2 release is at a much faster rate than its recycling through photosynthesis or fixation, which increases its net accumulation in the atmosphere. A large amount of CO2 is emitted into the atmosphere from various sources such as the combustion of fossil fuels in power plants, vehicles and manufacturing industries. Thus, carbon capture plays a key role in the race to achieve net zero emissions, paving a path for a decarbonized economy. To reduce the carbon footprints from industrial practices and vehicular emissions and attempt to mitigate the effects of global warming, several CO2 capturing and valorization technologies have become increasingly important. Hence, this article gives a statistical and geographical overview of CO2 and other greenhouse gas emissions based on source and sector. The review also describes different mechanisms involved in the capture and utilization of CO2 such as pre-combustion, post-combustion, oxy-fuels technologies, direct air capture, chemical looping combustion and gasification, ionic liquids, biological CO2 fixation and geological CO2 capture. The article also discusses the utilization of captured CO2 for value-added products such as clean energy, chemicals and materials (carbonates and polycarbonates and supercritical fluids). This article also highlights certain global industries involved in progressing some promising CO2 capture and utilization techniques.
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8

Liu, Lei, Chang-Ce Ke, Tian-Yi Ma, and Yun-Pei Zhu. "When Carbon Meets CO2: Functional Carbon Nanostructures for CO2 Utilization." Journal of Nanoscience and Nanotechnology 19, no. 6 (June 1, 2019): 3148–61. http://dx.doi.org/10.1166/jnn.2019.16590.

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Major fossil fuel consumption associated with CO2 emission and socioeconomic instability has received much concern within the global community regarding the long-term sustainability and security of these commodities. The capture, sequestration, and conversion of CO2 emissions from flue gas are now becoming familiar worldwide. Nanostructured carbonaceous materials with designed functionality have been extensively used in some key CO2 exploitation processes and techniques, because of their excellent electrical conductivity, chemical/mechanical stability, adjustable chemical compositions, and abundant active sites. This review focuses on a variety of carbonaceous materials, like graphene, carbon nanotubes, amorphous porous carbons and carbon hybrid composites, which have been demonstrated promising in CO2 capture/separation and conversion (electrocatalysis and photocatalysis) to produce value-added chemicals and fuels. Along with the discussion and concerning synthesis strategies, characterization and conversion and capture/separation techniques employed, we further elaborate the structure-performance relationships in terms of elucidating active sites, reaction mechanisms and kinetics improvement. Finally, challenges and future perspectives of these carbon-based materials for CO2 applications using well-structured carbons are remarked in detail.
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9

Madejski, Paweł, Karolina Chmiel, Navaneethan Subramanian, and Tomasz Kuś. "Methods and Techniques for CO2 Capture: Review of Potential Solutions and Applications in Modern Energy Technologies." Energies 15, no. 3 (January 26, 2022): 887. http://dx.doi.org/10.3390/en15030887.

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The paper presents and discusses modern methods and technologies of CO2 capture (pre-combustion capture, post-combustion capture, and oxy-combustion capture) along with the principles of these methods and examples of existing and operating installations. The primary differences of the selected methods and technologies, with the possibility to apply them in new low-emission energy technologies, were presented. The following CO2 capture methods: pre-combustion, post-combustion based on chemical absorption, physical separation, membrane separation, chemical looping combustion, calcium looping process, and oxy-combustion are discussed in the paper. Large-scale carbon capture utilization and storage (CCUS) facilities operating and under development are summarized. In 2021, 27 commercial CCUS facilities are currently under operation with a capture capacity of up to 40 Mt of CO2 per year. If all projects are launched, the global CO2 capture potential can be more than ca. 130–150 Mt/year of captured CO2. The most popular and developed indicators for comparing and assessing CO2 emission, capture, avoiding, and cost connected with avoiding CO2 emissions are also presented and described in the paper.
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10

Lian, Xinbo, Leilei Xu, Mindong Chen, Cai-e. Wu, Wenjing Li, Bingbo Huang, and Yan Cui. "Carbon Dioxide Captured by Metal Organic Frameworks and Its Subsequent Resource Utilization Strategy: A Review and Prospect." Journal of Nanoscience and Nanotechnology 19, no. 6 (June 1, 2019): 3059–78. http://dx.doi.org/10.1166/jnn.2019.16647.

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The carbon dioxide (CO2) is notorious as the greenhouse gas, which could cause the global warming and climate change. Therefore, the reduction of the atmospheric CO2 emissions from power plants and other industrial facilities has become as an increasingly urgent concern. In the recent years, CO2 capture and storage technologies have received a worldwide attention. Adsorption is considered as one of the efficient options for CO2 capture because of its cost advantage, low energy requirement and extensive applicability over a relatively wide range of temperature and pressure. The metal organic frameworks (MOFs) show widely potential application prospects in CO2 capture and storage owing to their outstanding textural properties, such as the extraordinarily high specific surface area, tunable pore size, ultrahigh porosity (up to 90%), high crystallinity, adjustable internal surface properties, and controllable structure. Herein, the most important research progress of MOFs materials on the CO2 capture and storage in recent years has been comprehensively reviewed. The extraordinary characteristics and CO2 capture performance of Zeolitic Imidazolate Frameworks (ZIFs), Bio-metal organic frameworks (bio-MOFs), IL@MOFs and MOF-composite materials were highlighted. The promising strategies for improving the CO2 adsorption properties of MOFs materials, especially the low-pressure adsorption performance under actual flue gas conditions, are also carefully summarized. Besides, CO2 is considered as an abundant, nontoxic, nonflammable, and renewable C1 resource for the synthesis of useful chemicals and fuels. The potential routes for resource utilization of the captured CO2 are briefly proposed.
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11

Peres, Christiano B., Pedro M. R. Resende, Leonel J. R. Nunes, and Leandro C. de Morais. "Advances in Carbon Capture and Use (CCU) Technologies: A Comprehensive Review and CO2 Mitigation Potential Analysis." Clean Technologies 4, no. 4 (November 17, 2022): 1193–207. http://dx.doi.org/10.3390/cleantechnol4040073.

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One of society’s major current challenges is carbon dioxide emissions and their consequences. In this context, new technologies for carbon dioxide (CO2) capture have attracted much attention. One of these is carbon capture and utilization (CCU). This work focuses on the latest trends in a holistic approach to carbon dioxide capture and utilization. Absorption, adsorption, membranes, and chemical looping are considered for CO2 capture. Each CO2 capture technology is described, and its benefits and drawbacks are discussed. For the use of carbon dioxide, various possible applications of CCU are described, starting with the utilization of carbon dioxide in agriculture and proceeding to the conversion of CO2 into fuels (catalytic processes), chemicals (photocatalytic processes), polymers, and building supplies. For decades, carbon dioxide has been used in industrial processes, such as CO2-enhanced oil recovery, the food industry, organic compound production (such as urea), water treatment, and, therefore, the production of flame retardants and coolants. There also are several new CO2-utilization technologies at various stages of development and exploitation, such as electrochemical conversion to fuels, CO2-enhanced oil recovery, and supercritical CO2. At the end of this review, future opportunities are discussed regarding machine learning (ML) and life cycle assessment (LCA).
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12

Fu, Lipei, Zhangkun Ren, Wenzhe Si, Qianli Ma, Weiqiu Huang, Kaili Liao, Zhoulan Huang, Yu Wang, Junhua Li, and Peng Xu. "Research progress on CO2 capture and utilization technology." Journal of CO2 Utilization 66 (December 2022): 102260. http://dx.doi.org/10.1016/j.jcou.2022.102260.

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13

Talekar, Sachin, Byung Hoon Jo, Jonathan S. Dordick, and Jungbae Kim. "Carbonic anhydrase for CO2 capture, conversion and utilization." Current Opinion in Biotechnology 74 (April 2022): 230–40. http://dx.doi.org/10.1016/j.copbio.2021.12.003.

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14

Karimi, Iftekhar A., and Sibudjing Kawi. "Technoeconomic perspectives on sustainable CO2 capture and utilization." Environmental Science and Pollution Research 23, no. 22 (October 19, 2016): 22223–25. http://dx.doi.org/10.1007/s11356-016-7838-z.

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15

Yu, Kai Man Kerry, Igor Curcic, Joseph Gabriel, and S. C. E. Tsang. "Apology: Recent Advances in CO2 Capture and Utilization." ChemSusChem 3, no. 6 (June 11, 2010): 644. http://dx.doi.org/10.1002/cssc.201090023.

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16

Pires, José, and Ana Gonçalves. "Special Issue on Carbon Capture and Utilization." Applied Sciences 13, no. 2 (January 4, 2023): 725. http://dx.doi.org/10.3390/app13020725.

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Carbon dioxide (CO2) emissions to the atmosphere have drastically increased in recent decades, with the energy and transport sectors representing major fractions of total greenhouse gas (GHG) emissions [...]
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17

Meyer, Vincent, Nick de Cristofaro, Jason Bryant, and Sada Sahu. "Solidia Cement an Example of Carbon Capture and Utilization." Key Engineering Materials 761 (January 2018): 197–203. http://dx.doi.org/10.4028/www.scientific.net/kem.761.197.

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Solidia Cement is a non-hydraulic binder that is produced in existing cement kilns using the same raw material as Portland cement (PC). The key difference is that the Solidia binder is produced using less limestone and at lower kiln burning temperatures. This translates into reduced CO2 emissions during cement manufacturing (30% reduction). The Solidia concrete solution consists in a mix between the binder, aggregates, sand, water that is reacted with CO2 to form a durable matrix. The curing process captures up to 300 kg of CO2 per ton of cement used. Together, the Solidia cement and concrete reduce the CO2 footprint by down to 70% when compared to conventional cement and concrete products.The advantages to precasters are multiple also:- Full strength in concrete parts achieved within 24 hours thus allowing just-in-time manufacturing and a significant reduction in inventory cost.- Concrete waste from forming process is almost eliminated and equipment cleanup time is significantly reduced because the concrete does not harden until it is exposed to CO2.- The final precast products present better aesthetics than PC-based concretes (no efflorescence, better pigmentation, and better color grading).The first industrial demonstrations (cement production and precast applications) were achieved and confirm the CO2 and energy savings announced.
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18

Pieri, Tryfonas, and Athanasios Angelis-Dimakis. "Model Development for Carbon Capture Cost Estimation." Clean Technologies 3, no. 4 (October 20, 2021): 787–803. http://dx.doi.org/10.3390/cleantechnol3040046.

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Carbon capture is the most critical stage for the implementation of a technically viable and economically feasible carbon capture and storage or utilization scheme. For that reason, carbon capture has been widely studied, with many published results on the technical performance, modelling and, on a smaller scale, the costing of carbon capture technologies. Our objective is to review a large set of published studies, which quantified and reported the CO2 capture costs. The findings are grouped, homogenised and standardised, and statistical models are developed for each one of the categories. These models allow the estimation of the capture costs, based on the amount of CO2 captured and the type of source/separation principle of the capture technology used.
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19

Milman, O. O. "Power units with full CO2 utilization." Journal of Physics: Conference Series 2150, no. 1 (January 1, 2022): 012024. http://dx.doi.org/10.1088/1742-6596/2150/1/012024.

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Abstract The forecasts for the development of renewable energy and conventional energy with fossil fuels have significant discrepancies in quantitative indicators, but agree on the need to reduce CO2 emissions. In this direction, a great number of developments are associated with hydrogen energy. Alternative proposals are cycles on methane-oxygen fuel with CO2 capture from the concentrated stream at the outlet of the condenser-separator: high-temperature gas-steam turbine unit of CJSC SPC «Turbocon», Allam, and JIHT RAS cycle. A 100 kW gas-steam turbine with an initial mixture temperature of up to 800° C has been developed and tested. To develop a method for calculating steam condensers from a mixture with CO2 (common to all three schemes), tests were carried out on a special stand; the heat transfer coefficient experimental data have been used to design a highly efficient steam condenser from a mixture with a converging flow path to maintain its high speed, a heat transfer coefficient of 2700 W/m2K was achieved. It is planned to create a prototype installation containing a steam boiler, a gas-steam turbine and a steam condenser with CO2 capture from the concentrated stream at the compressor outlet.
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20

Xu, Shaomao, Shyamal K. Das, and Lynden A. Archer. "The Li–CO2 battery: a novel method for CO2 capture and utilization." RSC Advances 3, no. 18 (2013): 6656. http://dx.doi.org/10.1039/c3ra40394g.

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21

Senatore, Vincenzo, Antonio Buonerba, Tiziano Zarra, Giuseppina Oliva, Vincenzo Belgiorno, Joanna Boguniewicz-Zablocka, and Vincenzo Naddeo. "Innovative membrane photobioreactor for sustainable CO2 capture and utilization." Chemosphere 273 (June 2021): 129682. http://dx.doi.org/10.1016/j.chemosphere.2021.129682.

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22

de Kleijne, Kiane, Steef V. Hanssen, Lester van Dinteren, Mark A. J. Huijbregts, Rosalie van Zelm, and Heleen de Coninck. "Limits to Paris compatibility of CO2 capture and utilization." One Earth 5, no. 2 (February 2022): 168–85. http://dx.doi.org/10.1016/j.oneear.2022.01.006.

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23

Yamada, Hidetaka. "Amine-based capture of CO2 for utilization and storage." Polymer Journal 53, no. 1 (September 2, 2020): 93–102. http://dx.doi.org/10.1038/s41428-020-00400-y.

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24

Lin, Shiying. "Development of In-situ CO2 Capture Coal Utilization Technologies." Energy Procedia 37 (2013): 99–106. http://dx.doi.org/10.1016/j.egypro.2013.05.089.

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25

Marocco Stuardi, Francesca, Frances MacPherson, and Julien Leclaire. "Integrated CO2 capture and utilization: A priority research direction." Current Opinion in Green and Sustainable Chemistry 16 (April 2019): 71–76. http://dx.doi.org/10.1016/j.cogsc.2019.02.003.

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26

Nocito, Francesco, and Angela Dibenedetto. "Atmospheric CO2 mitigation technologies: carbon capture utilization and storage." Current Opinion in Green and Sustainable Chemistry 21 (February 2020): 34–43. http://dx.doi.org/10.1016/j.cogsc.2019.10.002.

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27

Theofanidis, Stavros A., Andy N. Antzaras, and Angeliki A. Lemonidou. "CO2 as a building block: from capture to utilization." Current Opinion in Chemical Engineering 39 (March 2023): 100902. http://dx.doi.org/10.1016/j.coche.2023.100902.

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28

Joshi, N., L. Sivachandiran, and A. A. Assadi. "Perspectives in advance technologies/strategies for combating rising CO2 levels in the atmosphere via CO2 utilisation: A review." IOP Conference Series: Earth and Environmental Science 1100, no. 1 (December 1, 2022): 012020. http://dx.doi.org/10.1088/1755-1315/1100/1/012020.

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Abstract This review provides exhaustive literature on carbon dioxide (CO2) capture, storage and utilization. CO2 is one of the greenhouse gas, emitted into the atmosphere and has reached an alarming level of well above 400 ppm. The consequences of rising CO2 levels and global warming are visual in day today life such as floods, wildfires, droughts and irregular precipitation cycles. Several reviews, focused on a particular topic, have been published since the 19th century and recently. However, in this review, we have attempted to cover all the CO2 mitigation techniques available for their advantages and disadvantages have been discussed. The blooming technology of carbon capture and storage (CCS) and the pros and cons of CO2 capture, transportation and storage techniques are showcased. Interestingly the transportation of captured CO2 to the potential storage sites requires more than 50% of the total energy budget, therefore, this review is dedicated to the onsite CO2 conversion into value-added chemicals. Various technological advancements for CO2 conversion into other products by the solar thermochemical, electrochemical and photochemical processes have been analysed. From the extensive literature, it’s demonstrated that NTP (Non-Thermal Plasma) is one of the emerging techniques for the direct conversion of CO2 into value-added products as it is energetically efficient. The mechanisms of CO2 activation by thermal and NTP-catalysis have been discussed. Moreover, the benefits of DBD to obtain oxygenates like methanol, aldehydes, acids, and hydrocarbons from direct one-pot synthesis are discussed. The production of such value-added chemicals from CO2 is of prime importance as it will be our step towards a carbon-neutral economy which is the need of the hour. This review has also attempted to compare the cost-effectiveness of current existing techniques for CO2 capture and utilized solar to fuel efficiency to compare distinct technologies available for the utilization of CO2 to value-added chemicals.
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29

Tcvetkov, Pavel, Alexey Cherepovitsyn, and Sergey Fedoseev. "The Changing Role of CO2 in the Transition to a Circular Economy: Review of Carbon Sequestration Projects." Sustainability 11, no. 20 (October 21, 2019): 5834. http://dx.doi.org/10.3390/su11205834.

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Despite the diversity of studies on global warming and climate change mitigation technologies, research on the changing role of CO2 in the industrial processes, which is connected with the introduction of circular economy principles, is still out of scope. The purpose of this review is to answer the following question: Is technogenic CO2 still an industrial waste or has it become a valuable resource? For this purpose, statistical information from the National Energy Technology Library and the Global CCS Institute databases were reviewed. All sequestration projects (199) were divided into three groups: carbon capture and storage (65); carbon capture, utilization, and storage (100); and carbon capture and utilization (34). It was found that: (1) total annual CO2 consumption of such projects was 50.1 Mtpa in 2018, with a possible increase to 326.7 Mtpa in the coming decade; (2) total amount of CO2 sequestered in such projects could be 2209 Mt in 2028; (3) the risk of such projects being cancelled or postponed is around 31.8%; (4) CO2 is a valuable and sought-after resource for various industries. It was concluded that further development of carbon capture and utilization technologies will invariably lead to a change in attitudes towards CO2, as well as the appearance of new CO2-based markets and industries.
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Zhang, Min, Xiaoqing Liang, Yaozheng Wang, Hongyu Yang, and Guangchao Liang. "Insights into the Capture of CO2 by Nickel Hydride Complexes." Catalysts 12, no. 7 (July 19, 2022): 790. http://dx.doi.org/10.3390/catal12070790.

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As a desired feedstock for sustainable energy source and for chemical synthesis, the capture and utilization of CO2 have attracted chemists’ continuous efforts. The homogeneous CO2 insertion into a nickel hydride complex to generate formate provides insight into the role of hydrogen as an active hydride form in the hydrogenation of CO2, which serves as a practicable approach for CO2 utilization. To parameterize the activities and to model the structure–activity relationship in the CO2 insertion into nickel hydride, the comprehensive mechanism of CO2 insertion into a series of square planar transition metal hydride (TM–H, TM = Ni, Pd, and Co) complexes was investigated using density functional theory (DFT) computations. The stepwise pathway with the TM-(H)-formate intermediate for the CO2 insertion into all seven square planar transition metal hydride (TM–H) complexes was observed. The overall rate-determining step (RDS) was the nucleophilic attraction of the terminal O atom on the Ni center in Ni-(H)-formate to form Ni-(O)-(exo)formate. The charge of the Ni atom in the axially vacant [Ni]+ complex was demonstrated as the dominant factor in CO2 insertion, which had an excellent linear correction (R2 = 0.967) with the Gibbs barrier (ΔG‡) of the RDS. The parameterized activities and modeled structure–activity relationship provided here light the way to the design of a more efficient Ni–H complex in the capture and utilization of CO2.
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31

Susanti, Indri. "Technologies and Materials for Carbon Dioxide Capture." Science Education and Application Journal 1, no. 2 (October 5, 2019): 84. http://dx.doi.org/10.30736/seaj.v1i2.147.

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This paper was aims to review the technologies and materials for CO2 capture. Carbon dioxide is one of the triggers for the greenhouse effect and global warming. Some methods to reduce CO2 are separation technologies include air capture, CO2 Capture Utilization and Storage (CCUS) and CO2 Capture and Storage (CCS) technology. CCS technology have several systems namely post-combution, pre-combustion and oxy-fuel combustion. Post-combution systems can be done in various systems including absorption, adsorption, membrane, and cryogenic. Adsorption proses for CO2 capture applied with porous material such us mesopore silica, zeolite, carbon, MOF dan COF. This review was described the advantages and disadvantages of each technology for CO2 capture. Materials for CO2 adsorption also descibed in this review.
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32

Wang, Dongliang, Jingwei Li, Wenliang Meng, Jian Wang, Ke Wang, Huairong Zhou, Yong Yang, Zongliang Fan, and Xueying Fan. "Integrated Process for Producing Glycolic Acid from Carbon Dioxide Capture Coupling Green Hydrogen." Processes 10, no. 8 (August 15, 2022): 1610. http://dx.doi.org/10.3390/pr10081610.

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A novel process path is proposed to produce glycolic acid (GA) from CO2 as the feedstock, including CO2 capture, power-to-hydrogen, CO2 hydrogenation to methanol, methanol oxidation to formaldehyde, and formaldehyde carbonylation units. The bottlenecks are discussed from the perspectives of carbon utilization, CO2 emissions, total site energy integration, and techno-economic analysis. The carbon utilization ratio of the process is 82.5%, and the CO2 capture unit has the largest percentage of discharge in carbon utilization. Among the indirect emissions of each unit, the CO2 hydrogenation to methanol has the largest proportion of indirect carbon emissions, followed by the formaldehyde carbonylation to glycolic acid and the CO2 capture. After total site energy integration, the utility consumption is 1102.89 MW for cold utility, 409.67 MW for heat utility, and 45.98 MW for power. The CO2 hydrogenation to methanol makes the largest contribution to utility consumption due to the multi-stage compression of raw hydrogen and the distillation of crude methanol. The unit production cost is 834.75 $/t-GA; CO2 hydrogenation to methanol accounts for the largest proportion, at 70.8% of the total production cost. The total production cost of the unit depends on the price of hydrogen due to the currently high renewable energy cost. This study focuses on the capture and conversion of CO2 emitted from coal-fired power plants, which provides a path to a feasible low-carbon and clean use of CO2 resources.
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Mikulčić, Hrvoje, Iva Ridjan Skov, Dominik Franjo Dominković, Sharifah Rafidah Wan Alwi, Zainuddin Abdul Manan, Raymond Tan, Neven Duić, Siti Nur Hidayah Mohamad, and Xuebin Wang. "Flexible Carbon Capture and Utilization technologies in future energy systems and the utilization pathways of captured CO2." Renewable and Sustainable Energy Reviews 114 (October 2019): 109338. http://dx.doi.org/10.1016/j.rser.2019.109338.

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Anvita Abhijit Bhate and Elizabeth Biju Joseph. "Decarbonizing the future: Understanding carbon capture, utilization, and storage methods." World Journal of Advanced Engineering Technology and Sciences 8, no. 1 (February 28, 2023): 247–50. http://dx.doi.org/10.30574/wjaets.2023.8.1.0020.

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Carbon capture refers to the removal of carbon dioxide from the atmosphere, or directly at the source of its emissions. The latter employs chemical engineering to design capture systems for industries. Aqueous amine scrubbing makes use of amine based solvents to capture carbon dioxide from flue gas streams. The carbon, once captured, is compressed and redirected for either reutilisation or storage. In enhanced oil recovery, the CO2 is injected into oil and gas reservoirs to increase their extraction. Carbon storage methods work to remove the carbon from the atmosphere, and aid mitigation against carbon emissions from industry, thereby reducing the contribution to global warming and ocean acidification. This paper aims to provide the readers with an understanding of the technologies involved in the above processes.
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Alabid, Maytham, and Cristian Dinca. "Parametrization Study for Optimal Pre-Combustion Integration of Membrane Processes in BIGCC." Sustainability 14, no. 24 (December 12, 2022): 16604. http://dx.doi.org/10.3390/su142416604.

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Presently, the utilization of biomass as an energy source has gained significant attention globally due to its capacity to provide constant feedstock. In 2020, biomass combustion generated 19 Mt of CO2, representing an increase of 16% from the previous year. The increase in CO2 emissions is fundamentally due to biomass gasification in power plants. Due to the growing demand to reduce greenhouse gas emissions, this paper aims to improve CO2 capture technologies to face this challenge. In this context, the utilization of three stages of the polymer membrane process, using different compressor pressure values, has been technically and economically analyzed. The proposed solution was combined pre-combustion in a BIGCC process equipped with a Siemens gas turbine with an installed power capacity of 50 MW. The article simulated energy operations by using membranes of polymer and CHEMCAD software improved in the CO2 integration research project. Consequently, polymeric membranes with CO2 permeability of 1000 GPU were examined while CO2 selectivity towards nitrogen was investigated to be 50. It was observed that by increasing the surface area of the polymer membrane (400,000–1,200,000 m2) an increase of 37% occurs in CO2 capture efficiency. On the other hand, LCOE increased from 97 to 141 EUR/MWh. The avoided cost of CO2 captured was 52.9 EUR/ton.
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Hatzell, Marta. "(Invited) Opportunities and Challenges for Biopolar Membrane-Based Electrosynthesis." ECS Meeting Abstracts MA2022-02, no. 49 (October 9, 2022): 1882. http://dx.doi.org/10.1149/ma2022-02491882mtgabs.

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Over the last 3 decades, research on CO2 abatement technologies centered solely on carbon capture and storage (CCS). Here, technology focus is in the design of separations technologies to capture CO2 from concentrated point (e.g. flue gas) or dilute distributed sources (e.g. atmosphere) using amine absorption, adsorption, and membranes. Most of these technologies involve adsorbing or absorbing CO2 gas, releasing this gas, and then pressurizing it for storage. Thus, a number of different subsystems and specialized new equipment are needed resulting in high capital and operating costs. As a result, CO2 capture for CCS is economically unfavorable in the absence of utilization routes for the captured CO2. Electrolysis of CO2 is a viable potential pathway toward attaining utilization; however, carbon loss in traditional electrolysis architectures is a large limitation. To overcome this challenge, movement toward bipolar-membrane (BPM) based electrolysis cells have been proposed as a viable option. BPMs contain an anion and a cation exchange layer. At the interface of these membranes, a junction potential forms when a electric field is applied across the membrane. Thus, within a BPM electrolysis cell, charge balancing occurs through water electro dissociating at the interface of the anion and cation membrane, thereby forming charge carriers in the form of OH- and H+. The production of acid and base in situ allows for a continuous process with low carbon losses. The primary aim of this talk is to discuss the challenges and opportunities that exist with the development of proper catalyst and membranes for these systems for carbon capture and electrofuel production.
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Facchino, Marco, Paulina Popielak, Marcin Panowski, Dariusz Wawrzyńczak, Izabela Majchrzak-Kucęba, and Marcello De Falco. "The Environmental Impacts of Carbon Capture Utilization and Storage on the Electricity Sector: A Life Cycle Assessment Comparison between Italy and Poland." Energies 15, no. 18 (September 18, 2022): 6809. http://dx.doi.org/10.3390/en15186809.

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Carbon Capture Utilization and Storage (CCUS) is a set of technologies aimed at capturing carbon dioxide (CO2) emissions from point-source emitters to either store permanently or use as a feedstock to produce chemicals and fuels. In this paper, the potential benefits of CCUS integration into the energy supply sector are evaluated from a Life Cycle Assessment (LCA) perspective by comparing two different routes for the CO2 captured from a natural gas combined cycle (NGCC). Both the complete storage of the captured CO2 and its partial utilization to produce dimethyl ether are investigated. Moreover, the assessment is performed considering the region-specific features of two of the largest CO2 emitters in Europe, namely Italy and Poland. Results shows that the complete storage of the captured CO2 reduces Global Warming Potential (GWP) by ~89% in Italy and ~97%, in Poland. On the other hand, the partial utilization of CO2 to produce dimethyl ether leads to a decrease of ~58% in Italy and ~68% in Poland with respect to a comparable reference entailing conventional dimethyl ether production. A series of environmental trade-offs was determined, with all the investigated categories apart from GWP showing an increase, mainly connected with the higher energy requirements of CCUS processes. These outcomes highlight the need for a holistic-oriented approach in the design of novel implemented configurations to avoid burden shifts throughout the value chain.
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Shreyash, Nehil, Muskan Sonker, Sushant Bajpai, Saurabh Kr Tiwary, Mohd Ashhar Khan, Subham Raj, Tushar Sharma, and Susham Biswas. "The Review of Carbon Capture-Storage Technologies and Developing Fuel Cells for Enhancing Utilization." Energies 14, no. 16 (August 13, 2021): 4978. http://dx.doi.org/10.3390/en14164978.

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The amount of CO2 released in the atmosphere has been at a continuous surge in the last decade, and in order to protect the environment from global warming, it is necessary to employ techniques like carbon capture. Developing technologies like Carbon Capture Utilization and Storage aims at mitigating the CO2 content from the air we breathe and has garnered immense research attention. In this review, the authors have aimed to discuss the various technologies that are being used to capture the CO2 from the atmosphere, store it and further utilize it. For utilization, researchers have developed alternatives to make profits from CO2 by converting it into an asset. The development of newer fuel cells that consume CO2 in exchange for electrical power to drive the industries and produce valuable hydrocarbons in the form of fuel has paved the path for more research in the field of carbon utilization. The primary focus on the article is to inspect the environmental and economic feasibility of novel technologies such as fuel cells, different electrochemical processes, and the integration of artificial intelligence and data science in them, which are designed for mitigating the percentage of CO2 in the air.
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Zhang, Tian, Wanchang Zhang, Ruizhao Yang, Dan Cao, Longfei Chen, Dewei Li, and Lingbin Meng. "CO2 Injection Deformation Monitoring Based on UAV and InSAR Technology: A Case Study of Shizhuang Town, Shanxi Province, China." Remote Sensing 14, no. 1 (January 5, 2022): 237. http://dx.doi.org/10.3390/rs14010237.

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Carbon Capture, Utilization and Storage, also referred to as Carbon Capture, Utilization and Sequestration (CCUS), is one of the novel climate mitigation technologies by which CO2 emissions are captured from sources, such as fossil power generation and industrial processes, and further either reused or stored with more attention being paid on the utilization of captured CO2. In the whole CCUS process, the dominant migration pathway of CO2 after being injected underground becomes very important information to judge the possible storage status as well as one of the essential references for evaluating possible environmental affects. Interferometric Synthetic Aperture Radar (InSAR) technology, with its advantages of extensive coverage in surface deformation monitoring and all-weather traceability of the injection processes, has become one of the promising technologies frequently adopted in worldwide CCUS projects. In this study, taking the CCUS sequestration area in Shizhuang Town, Shanxi Province, China, as an example, unmanned aerial vehicle (UAV) photography measurement technology with a 3D surface model at a resolution of 5.3 cm was applied to extract the high-resolution digital elevation model (DEM) of the study site in coordination with InSAR technology to more clearly display the results of surface deformation monitoring of the CO2 injection area. A 2 km surface heaving dynamic processes before and after injection from June 2020 to July 2021 was obtained, and a CO2 migration pathway northeastward was observed, which was rather consistent with the monitoring results by logging and micro-seismic studies. Additionally, an integrated monitoring scheme, which will be the trend of monitoring in the future, is proposed in the discussion.
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Sun, Shuzhuang, Hongman Sun, Paul T. Williams, and Chunfei Wu. "Recent advances in integrated CO2 capture and utilization: a review." Sustainable Energy & Fuels 5, no. 18 (2021): 4546–59. http://dx.doi.org/10.1039/d1se00797a.

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In this review, we summarize the recent progress of dual functional materials application in integrated CO2 capture and utilization and discuss the superiority of the integrated process from the perspective of industrial applications.
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41

Na, Choon-Ki, and Jee-June Song. "Applicability of Solvay Process as a CO2 Capture and Utilization." Journal of the Korean Society for Environmental Technology 20, no. 5 (October 30, 2019): 319–25. http://dx.doi.org/10.26511/jkset.20.5.5.

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Huang, Zhe, Lu Lu, and Zhiyong Jason Ren. "Can Wastewater Be Used for Direct CO2 Capture and Utilization?" Proceedings of the Water Environment Federation 2017, no. 5 (January 1, 2017): 5038–55. http://dx.doi.org/10.2175/193864717822156901.

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43

Desport, Lucas, and Sandrine Selosse. "An overview of CO2 capture and utilization in energy models." Resources, Conservation and Recycling 180 (May 2022): 106150. http://dx.doi.org/10.1016/j.resconrec.2021.106150.

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Nakano, Koji, Yu Hoshino, Keiji Numata, and Keiji Tanaka. "Special issue: CO2: capture of, utilization of, and degradation into." Polymer Journal 53, no. 1 (January 2021): 1–2. http://dx.doi.org/10.1038/s41428-020-00427-1.

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45

Dindi, Abdallah, Dang Viet Quang, Lourdes F. Vega, Enas Nashef, and Mohammad R. M. Abu-Zahra. "Applications of fly ash for CO2 capture, utilization, and storage." Journal of CO2 Utilization 29 (January 2019): 82–102. http://dx.doi.org/10.1016/j.jcou.2018.11.011.

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46

Li, Ying, and Fanxing Li. "Preface to Special Issue - CO2 Capture, Sequestration, Conversion and Utilization." Aerosol and Air Quality Research 14, no. 2 (2014): 451–52. http://dx.doi.org/10.4209/aaqr.2014.14.0001.

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47

Wei, Duo, Henrik Junge, and Matthias Beller. "An amino acid based system for CO2 capture and catalytic utilization to produce formates." Chemical Science 12, no. 17 (2021): 6020–24. http://dx.doi.org/10.1039/d1sc00467k.

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A novel amino acid based reaction system for CO2 capture and utilization (CCU) to produce formates is presented applying a ruthenium-based catalyst. Noteworthy, CO2 can be captured from ambient air and converted to formates in one-pot (TON > 50 000).
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48

Zieliński, Marcin, Marcin Dębowski, Joanna Kazimierowicz, and Izabela Świca. "Microalgal Carbon Dioxide (CO2) Capture and Utilization from the European Union Perspective." Energies 16, no. 3 (February 1, 2023): 1446. http://dx.doi.org/10.3390/en16031446.

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The increasing concentration of anthropogenic CO2 in the atmosphere is causing a global environmental crisis, forcing significant reductions in emissions. Among the existing CO2 capture technologies, microalgae-guided sequestration is seen as one of the more promising and sustainable solutions. The present review article compares CO2 emissions in the EU with other global economies, and outlines EU’s climate policy together with current and proposed EU climate regulations. Furthermore, it summarizes the current state of knowledge on controlled microalgal cultures, indicates the importance of CO2 phycoremediation methods, and assesses the importance of microalgae-based systems for long-term storage and utilization of CO2. It also outlines how far microalgae technologies within the EU have developed on the quantitative and technological levels, together with prospects for future development. The literature overview has shown that large-scale take-up of technological solutions for the production and use of microalgal biomass is hampered by economic, technological, and legal barriers. Unsuitable climate conditions are an additional impediment, forcing operators to implement technologies that maintain appropriate temperature and lighting conditions in photobioreactors, considerably driving up the associated investment and operational costs.
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Yang, Zhi Hao, Zhi Ping Li, Feng Peng Lai, and Jun Jie Yi. "The Capture, Utilization, Storage of CO2 in Methane Recovery." Advanced Materials Research 1092-1093 (March 2015): 1620–24. http://dx.doi.org/10.4028/www.scientific.net/amr.1092-1093.1620.

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According to the problems that the coalbed methane resource was rich in deep seam in China, but the economic and technology conditions were limited, it would be hard to mine with a conventional method. The CO2 capture, utilization and storage technology was provided (CO2-ECBM). The application of the technology would not only improve the methane recovery ratio from deep and unminable layer, but also put CO2 effectively in the deep layer for storage to reach a target of reducing emission. The study showed that a coal rank, coal seam pressure, coal seam permeability, injection time, injected gas types and others would affect to the recovery ratio of methane in a production mine. Therefore, before we use this technology, a rational evaluation should be conducted on the place location. So the capture and storage technology of CO2 has an important significance in protecting the natural environment.
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Tsiotsias, Anastasios I., Nikolaos D. Charisiou, Ioannis V. Yentekakis, and Maria A. Goula. "The Role of Alkali and Alkaline Earth Metals in the CO2 Methanation Reaction and the Combined Capture and Methanation of CO2." Catalysts 10, no. 7 (July 21, 2020): 812. http://dx.doi.org/10.3390/catal10070812.

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CO2 methanation has great potential for the better utilization of existing carbon resources via the transformation of spent carbon (CO2) to synthetic natural gas (CH4). Alkali and alkaline earth metals can serve both as promoters for methanation catalysts and as adsorbent phases upon the combined capture and methanation of CO2. Their promotion effect during methanation of carbon dioxide mainly relies on their ability to generate new basic sites on the surface of metal oxide supports that favour CO2 chemisorption and activation. However, suppression of methanation activity can also occur under certain conditions. Regarding the combined CO2 capture and methanation process, the development of novel dual-function materials (DFMs) that incorporate both adsorption and methanation functions has opened a new pathway towards the utilization of carbon dioxide emitted from point sources. The sorption and catalytically active phases on these types of materials are crucial parameters influencing their performance and stability and thus, great efforts have been undertaken for their optimization. In this review, we present some of the most recent works on the development of alkali and alkaline earth metal promoted CO2 methanation catalysts, as well as DFMs for the combined capture and methanation of CO2.
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