Topic Editors

Centro de Quimica Estrutural, Instituto Superior Técnico da Universidade de Lisboa, Lisboa, Portugal
Department of Mechanical Engineering, Escuela de Ingeniería y Arquitectura (EINA), Universidad de Zaragoza, 50018 Zaragoza, Spain
Centro de Química Estrutural, Instituto Superior Técnico, Universidade de Lisboa, Av Rovisco Pais, 1049-001 Lisboa, Portugal

Carbon Dioxide Capture or Removal and Valorisation: Advances in the Development of Materials and Technologies

Abstract submission deadline
closed (31 August 2024)
Manuscript submission deadline
30 November 2024
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8761

Topic Information

Dear Colleagues,

The energetic transition requires the replacement of fossil fuels with renewable energy sources, along with the development of innovative decarbonation technologies and the establishment of a circular economy model. Developing and deploying carbon capture (from fixed sources) or removal (from the atmosphere) technologies using innovative CO2 capture materials and CO2 valorization in short- or long-lived biofuels or green products are essential to reach carbon neutrality or negative emissions targets. This Special Topic, “Carbon Dioxide Capture or Removal and Valorisation: Advances in the Development of Materials and Technologies”, will address topics related, but not limited to:

  • Advances in CO2 sorbent properties for carbon removal (e.g., direct air capture, mineralization, biochar) and capture (e.g., post-combustion and pre-combustion conditions);
  • Enhancement of natural and synthetic sorbent materials properties for CO2 uptake;
  • Stability, activity, and regeneration of sorbents under different technological applications at low, medium, or high temperatures;
  • Dual-function materials for CO2 capture and conversion;
  • Development of catalysts for CO2 conversion to biofuels and green products;
  • Thermal-, photo-, electro-, bio- and plasma catalysis applications in CO2 conversion;
  • Carbon capture from power plants and industrial sectors and carbon removal from the air—novel technologies, integrated concepts, and methodologies;
  • Conversion of CO2 into fuels and chemicals through biological, thermal, electrochemical, and photochemical processes. In this topic, original papers or reviews are welcome.

Dr. Paula Teixeira
Dr. María Pilar Lisbona
Dr. Carmen Bacariza
Topic Editors

Keywords

  • CO2 capture
  • thermochemical energy storage 
  • power-to-X
  • bifunctional materials 
  • DAC
  • mineralization

Participating Journals

Journal Name Impact Factor CiteScore Launched Year First Decision (median) APC
Catalysts
catalysts
3.8 6.8 2011 12.9 Days CHF 2200 Submit
Clean Technologies
cleantechnol
4.0 6.1 2019 30 Days CHF 1600 Submit
Energies
energies
3.0 6.2 2008 17.5 Days CHF 2600 Submit
Gases
gases
- - 2021 23.4 Days CHF 1000 Submit
Sustainability
sustainability
3.3 6.8 2009 20 Days CHF 2400 Submit

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Published Papers (5 papers)

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18 pages, 5073 KiB  
Article
Metal Oxalates as a CO2 Solid State Reservoir: The Carbon Capture Reaction
by Linda Pastero, Vittorio Barella, Enrico Allais, Marco Pazzi, Fabrizio Sordello, Quentin Wehrung and Alessandro Pavese
Clean Technol. 2024, 6(4), 1389-1406; https://doi.org/10.3390/cleantechnol6040066 - 14 Oct 2024
Viewed by 750
Abstract
To maintain the carbon dioxide concentration below the no-return threshold for climate change, we must consider the reduction in anthropic emissions coupled to carbon capture methods applied in synergy. In our recent papers, we proposed a green and reliable method for carbon mineralization [...] Read more.
To maintain the carbon dioxide concentration below the no-return threshold for climate change, we must consider the reduction in anthropic emissions coupled to carbon capture methods applied in synergy. In our recent papers, we proposed a green and reliable method for carbon mineralization using ascorbic acid aqueous solution as the reducing agent for carbon (IV) to carbon (III), thus obtaining oxalic acid exploiting green reagents. Oxalic acid is made to mineralize as calcium (as the model cation) oxalate. Oxalates are solid-state reservoirs suitable for long-term carbon storage or carbon feedstock for manufacturing applications. The carbon mineralization reaction is a double-step process (carbon reduction and oxalate precipitation), and the carbon capture efficiency is invariably represented by a double-slope curve we formerly explained as a decrease in the reducing effectiveness of ascorbic acid during reaction. In the present paper, we demonstrated that the reaction proceeds via a “pure CO2-capture” stage in which ascorbic acid oxidizes into dehydroascorbic acid and carbon (IV) reduces to carbon (III) and a “mixed” stage in which the redox reaction competes with the degradation of ascorbic acid in producing oxalic acid. Despite the irreversibility of the reduction reaction, that was demonstrated in abiotic conditions, the analysis of costs according to the market price of the reagents endorses the application of the method. Full article
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21 pages, 550 KiB  
Review
Carbon Market for Climate Projects in Russia: An Overview of Nature-Based and Technological Carbon Offsets
by Tatiana Nevzorova
Gases 2024, 4(3), 153-173; https://doi.org/10.3390/gases4030009 - 8 Jul 2024
Viewed by 1453
Abstract
Climate projects can become one of the key tools for decarbonization in Russia. They have powerful potential in terms of solving the problems of reducing emissions and increasing the absorption of greenhouse gases, as well as monetization potential for businesses. Despite the geopolitical [...] Read more.
Climate projects can become one of the key tools for decarbonization in Russia. They have powerful potential in terms of solving the problems of reducing emissions and increasing the absorption of greenhouse gases, as well as monetization potential for businesses. Despite the geopolitical crisis and sanctions imposed on Russia, certain opportunities for implementing climate projects have remained accessible. This study aims to provide a comprehensive analysis of the current status, including the regulations and approved methodologies, prospects, and challenges for climate projects in the carbon market in Russia. It also offers an overview of international carbon market mechanisms and analyses the advantages and disadvantages of the nature-based and technological solutions of climate projects for carbon sequestration. This, in turn, can facilitate the realization of future strategies for realizing the bigger potential of Russian climate projects in the domestic and international carbon markets. This research also provides up-to-date data on the current situation of the carbon market in Russia. Full article
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16 pages, 7283 KiB  
Article
Investigation and Comparison of Catalytic Methods to Produce Green CO2-Containing Monomers for Polycarbonates
by Daniel Christian Brüggemann, Philipp Harry Isbrücker, Dzenna Zukova, Franz Robert Otto Heinrich Schröter, Yen Hoang Le and Reinhard Schomäcker
Catalysts 2024, 14(6), 362; https://doi.org/10.3390/catal14060362 - 1 Jun 2024
Viewed by 1172
Abstract
The preparation of CO2-containing polymers with improved degradation properties is still very challenging. An elegant method for preparing these polymers is to use CO2-containing monomers in ring-opening polymerizations (ROP) which are particularly gentle and energy-saving methods. However, cyclic carbonates [...] Read more.
The preparation of CO2-containing polymers with improved degradation properties is still very challenging. An elegant method for preparing these polymers is to use CO2-containing monomers in ring-opening polymerizations (ROP) which are particularly gentle and energy-saving methods. However, cyclic carbonates are required for this which are not readily available. This paper therefore aims to present the optimization and comparison of two synthesis methods to obtain cyclic carbonates for ROP. Within this work, cyclic styrene carbonate was synthesized from readily available raw materials by using a Jacobsen catalyst for the reaction of styrene oxide and carbon dioxide or an organocatalyst for the transesterification of methyl carbonate with 1-phenyl-1,2-ethanediol. The latter performed with 100% selectivity to the desired styrene carbonate, which was succesfully tested in ROP, producing an amorphous thermoplastic polymer with a TG of 185 °C. Full article
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16 pages, 3156 KiB  
Article
Carbon Dioxide Capture under Low-Pressure Low-Temperature Conditions Using Shaped Recycled Fly Ash Particles
by Sherif Fakher, Abdelaziz Khlaifat and Abdullah Hassanien
Gases 2024, 4(2), 117-132; https://doi.org/10.3390/gases4020007 - 23 May 2024
Cited by 3 | Viewed by 2014
Abstract
Carbon-capture technologies are extremely abundant, yet they have not been applied extensively worldwide due to their high cost and technological complexities. This research studies the ability of polymerized fly ash to capture carbon dioxide (CO2) under low-pressure and low-temperature conditions via [...] Read more.
Carbon-capture technologies are extremely abundant, yet they have not been applied extensively worldwide due to their high cost and technological complexities. This research studies the ability of polymerized fly ash to capture carbon dioxide (CO2) under low-pressure and low-temperature conditions via physical adsorption. The research also studies the ability to desorb CO2 due to the high demand for CO2 in different industries. The adsorption–desorption hysteresis was measured using infrared-sensor detection apparatus. The impact of the CO2 injection rate for adsorption, helium injection rate for desorption, temperature, and fly ash contact surface area on the adsorption–desorption hysteresis was investigated. The results showed that change in the CO2 injection rate had little impact on the variation in the adsorption capacity; for all CO2 rate experiments, the adsorption reached more than 90% of the total available adsorption sites. Increasing the temperature caused the polymerized fly ash to expand, thus increasing the available adsorption sites, thus increasing the overall adsorption volume. At low helium rates, desorption was extremely lengthy which resulted in a delayed hysteresis response. This is not favorable since it has a negative impact on the adsorption–desorption cyclic rate. Based on the results, the polymerized fly ash proved to have a high CO2 capture capability and thus can be applied for carbon-capture applications. Full article
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20 pages, 5875 KiB  
Article
Production of Sustainable Adsorbents for CO2 Capture Applications from Food Biowastes
by Fernando Rubiera, Carlos Córdoba, Tamara Pena and Marta G. Plaza
Energies 2024, 17(5), 1205; https://doi.org/10.3390/en17051205 - 3 Mar 2024
Viewed by 1536
Abstract
Traditional methods to develop biomass-based carbon adsorbents generally involve carbonization followed by chemical or physical activation. However, routes involving the hydrothermal treatment of biomass are receiving growing interest. In this work, two different strategies for the synthesis of sustainable CO2 adsorbents are [...] Read more.
Traditional methods to develop biomass-based carbon adsorbents generally involve carbonization followed by chemical or physical activation. However, routes involving the hydrothermal treatment of biomass are receiving growing interest. In this work, two different strategies for the synthesis of sustainable CO2 adsorbents are compared, i.e., in situ ionic activation and hydrothermal treatment followed by activation with CO2. The latter is a green and simple procedure that does not require the addition of chemicals or acid-washing stages, and which leads to carbon adsorbents with relatively high CO2 adsorption capacity at low pressures, up to 0.64 mmol g−1 at 15 kPa and 50 °C, conditions relevant for postcombustion CO2 capture applications. On the other hand, in situ ionic activation can lead to carbon adsorbents with superior CO2 adsorption capacity in the aforementioned conditions, 0.78 mmol g−1, and with reduced cost and environmental impact compared to conventional chemical activation. Full article
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