M. Dahl, K. McMahon, P. S. Lavery, S. H. Hamilton, C. E. Lovelock, and O. Serrano, “Ranking the Risk of CO₂ Emissions From Seagrass Soil Carbon Stocks Under Global Change Threats,” Global Environmental Change 78 (2023): 102632.

R. L. Wilby, M. Orr, D. Depledge, et al., “The Impacts of Sport Emissions on Climate: Measurement, Mitigation, and Making a Difference,” Annals of the New York Academy of Sciences 1519, no. 1 (2023): 20–33.

A. G. Olabi and M. A. Abdelkareem, “Renewable Energy and Climate Change,” Renewable and Sustainable Energy Reviews 158 (2022): 112111.

H. Ritchie and M. Roser, Climate Change and Flying: What Share of Global CO₂ Emissions Come From Aviation? (Our World in Data, 2023).

M. Amin, H. H. Shah, A. G. Fareed, et al., “Hydrogen Production Through Renewable and Non-Renewable Energy Processes and Their Impact on Climate Change,” International Journal of Hydrogen Energy 47, no. 77 (2022): 33112–33134.

S. Fujimori, W. Wu, J. Doelman, et al., “Land-Based Climate Change Mitigation Measures Can Affect Agricultural Markets and Food Security,” Nature Food 3, no. 2 (2022): 110–121.

J. Wang, R. Fu, S. Wen, et al., “Progress and Current Challenges for CO₂ Capture Materials From Ambient Air,” Advanced Composites and Hybrid Materials 5, no. 4 (2022): 2721–2759.

J. Murphy, Calculate Emissions by Country: View Carbon Footprint Data Around the World (2024), https://8billiontrees.com/carbon-offsets-credits/carbon-ecological-footprint-calculators/country/.

J. R. M. Poynting, Planet-Warming Gas Levels Rose More Than Ever in 2024 (BBC Climate & Science, 2025).

S. Chen, J. Liu, Q. Zhang, F. Teng, and B. C. McLellan, “A Critical Review on Deployment Planning and Risk Analysis of Carbon Capture, Utilization, and Storage (CCUS) Toward Carbon Neutrality,” Renewable and Sustainable Energy Reviews 167 (2022): 112537.

C. Zou, F. Ma, S. Pan, et al., “Earth Energy Evolution, Human Development and Carbon Neutral Strategy,” Petroleum Exploration and Development 49, no. 2 (2022): 468–488.

T. A. Saleh, “Nanomaterials and Hybrid Nanocomposites for CO₂ Capture and Utilization: Environmental and Energy Sustainability,” RSC Advances 12, no. 37 (2022): 23869–23888.

S. Bachleitner, Ö. Ata, and D. Mattanovich, “The Potential of CO₂-Based Production Cycles in Biotechnology to Fight the Climate Crisis,” Nature Communications 14, no. 1 (2023): 6978.

M. P. Jones, T. Krexner, and A. Bismarck, “Repurposing Fischer-Tropsch and Natural Gas as Bridging Technologies for the Energy Revolution,” Energy Conversion and Management 267 (2022): 115882.

N. Li, L. Mo, and C. Unluer, “Emerging CO₂ Utilization Technologies for Construction Materials: A Review,” Journal of CO₂ Utilization 65 (2022): 102237.

A. Sarwer, S. M. Hamed, A. I. Osman, et al., “Algal Biomass Valorization for Biofuel Production and Carbon Sequestration: A Review,” Environmental Chemistry Letters 20, no. 5 (2022): 2797–2851.

A. Saravanan, V. C. Deivayanai, P. Senthil Kumar, G. Rangasamy, and S. Varjani, “CO₂ Bio-Mitigation Using Genetically Modified Algae and Biofuel Production Towards a Carbon Net-Zero Society,” Bioresource Technology 363 (2022): 127982.

A. Raihan, R. A. Begum, M. N. M. Said, and J. J. Pereira, “Relationship Between Economic Growth, Renewable Energy Use, Technological Innovation, and Carbon Emission Toward Achieving Malaysia's Paris Agreement,” Environment Systems and Decisions 42, no. 4 (2022): 586–607.

K. R. Shivanna, “Climate Change and Its Impact on Biodiversity and Human Welfare,” Proceedings of the Indian National Science Academy 88, no. 2 (2022): 160–171.

D. Bhattacharyya, “Design and Optimization of Hybrid Membrane–Solvent-Processes for Post-Combustion CO₂ Capture,” Current Opinion in Chemical Engineering 36 (2022): 100768.

P. Muchan, C. Saiwan, and M. Nithitanakul, “Carbon Dioxide Adsorption/Desorption Performance of Single- and Blended-Amines-Impregnated MCM-41 Mesoporous Silica in Post-Combustion Carbon Capture,” Clean Energy 6, no. 3 (2022): 424–437.

V. Vatanpour, O. O. Teber, M. Mehrabi, and I. Koyuncu, “Polyvinyl Alcohol-Based Separation Membranes: A Comprehensive Review on Fabrication Techniques, Applications and Future Prospective,” Materials Today Chemistry 28 (2023): 101381.

Y. Ibrahim, M. M. Zagho, A. ElAlfy, A. Karim, and A. A. Elzatahry, “Recent Advances in Retention and Permeation of CO₂ Gas Using MXene Based Membranes,” Npj 2D Materials and Applications 9, no. 1 (2025): 12.

D. Wang, A. Joshi, and L.-S. Fan, “Chemical Looping Technology—A Manifestation of a Novel Fluidization and Fluid-Particle System for CO₂ Capture and Clean Energy Conversions,” Powder Technology 409 (2022): 117814.

B. Shindel, J. Hegarty, J. D. Estradioto, et al., “Platform Materials for Moisture-Swing Carbon Capture,” Environmental Science & Technology 59, no. 17 (2025): 8495–8505.

J. Ren, S. Zeng, D. Chen, M. Yang, P. Linga, and Z. Yin, “Roles of Montmorillonite Clay on the Kinetics and Morphology of CO₂ Hydrate in Hydrate-Based CO₂ Sequestration,” Applied Energy 340 (2023): 120997.

B. Lal and A. Manjusha, Gas Hydrate in Carbon Capture, Transportation and Storage: Technological, Economic, and Environmental Aspects (CRC Press, 2024).

E. Daneshvar, R. J. Wicker, P. L. Show, and A. Bhatnagar, “Biologically-Mediated Carbon Capture and Utilization by Microalgae Towards Sustainable CO₂ Biofixation and Biomass Valorization—A Review,” Chemical Engineering Journal 427 (2022): 130884.

D. Suri, S. Das, S. Choudhary, et al., “Enigma of Sustainable CO₂ Conversion to Renewable Fuels and Chemicals Through Photocatalysis, Electrocatalysis, and Photoelectrocatalysis: Design Strategies and Atomic Level Insights,” Small 21, no. 8 (2025): 2408981.

K. Zhong, P. Sun, and H. Xu, “Advances in Defect Engineering of Metal Oxides for Photocatalytic CO₂ Reduction,” Small 21, no. 28 (2024): 2310677.

B. B. Rath, S. Krause, and B. V. Lotsch, “Active Site Engineering in Reticular Covalent Organic Frameworks for Photocatalytic CO₂ Reduction,” Advanced Functional Materials 34, no. 43 (2024): 2309060.

F. J. Silerio-Vázquez, B. Kakavandi, M. Tayyab, O. Baigenzhenov, A. Hosseini-Bandegharaei, and J. B. Proal-Nájera, “Sustainability Insights Into Photocatalytic CO₂-to-CH₄ Conversion Utilizing g-C₃N₄-Based Photocatalysts: Flaws, Progress, and Prospectives,” Coordination Chemistry Reviews 542 (2025): 216901.

A. Nosrati, S. Javanshir, F. Feyzi, and S. Amirnejat, “Effective CO₂ Capture and Selective Photocatalytic Conversion Into CH₃OH by Hierarchical Nanostructured GO–TiO₂–Ag₂O and GO–TiO₂–Ag₂O–Arg,” ACS Omega 8, no. 4 (2023): 3981–3991.

C. Bizzarri and M. Tsotsalas, “Data-Driven Innovation in Metal-Organic Frameworks Photocatalysis: Bridging Gaps for CO₂ Capture and Conversion With FAIR Principles,” Advanced Energy and Sustainability Research 6, no. 5 (2025): 2400325.

A. Li, H. Qiu, Z. Wang, et al., “Electrocatalytic Conversion of Methane to Ethanol via Promoted •OH Generation in Aqueous Electrolyte,” ACS Sustainable Chemistry & Engineering 12, no. 25 (2024): 9558–9567.

S. Mumtaz, M. A. Nazir, S. S. A. Shah, et al., “Recent Progress in Chemically Functionalized Heterogeneous Catalysts for CO₂ Conversion by Electro and Photocatalysis: A Review,” Advanced Sustainable Systems 9, no. 5 (2025): 2400852.

F. Huang, H. Sun, S. He, et al., “Progress and Perspectives for Efficient Electrochemical Carbon Dioxide Reduction to Methane,” ChemSusChem 18, no. 12 (2025): e202402568.

W. Ma, X. He, W. Wang, S. Xie, Q. Zhang, and Y. Wang, “Electrocatalytic Reduction of CO₂ and CO to Multi-Carbon Compounds over Cu-Based Catalysts,” Chemical Society Reviews 50, no. 23 (2021): 12897–12914.

P. Chen, Y. Wu, T. E. Rufford, L. Wang, G. Wang, and Z. Wang, “Organic Molecules Involved in Cu-Based Electrocatalysts for Selective CO₂ Reduction to C₂₊ Products,” Materials Today Chemistry 27 (2023): 101328.

F. Mollaamin and M. Monajjemi, “Transition Metal (X = Mn, Fe, Co, Ni, Cu, Zn)-Doped Graphene as Gas Sensor for CO₂ and NO₂ Detection: A Molecular Modeling Framework by DFT Perspective,” Journal of Molecular Modeling 29, no. 4 (2023): 119.

J. Kundu, B. R. Anne, J. Cho, H. Huang, D. Cho, and S.-I. Choi, “Heterostructure Engineering in Metal Sulfides for Electrochemical CO₂ Reduction: Advancing Performance and Stability,” Small 21 (2025): e05185.

J. Li, W. Y. Zan, H. Kang, et al., “Graphitic-N Highly Doped Graphene-Like Carbon: A Superior Metal-Free Catalyst for Efficient Reduction of CO₂,” Applied Catalysis, B: Environmental 298 (2021): 120510.

V. Longo, G. Centi, S. Perathoner, and C. Genovese, “CO₂ Utilisation With Plasma Technologies,” Current Opinion in Green and Sustainable Chemistry 46 (2024): 100893.

J. Osorio-Tejada, M. Escriba-Gelonch, R. Vertongen, A. Bogaerts, and V. Hessel, “CO₂ Conversion to CO via Plasma and Electrolysis: A Techno-Economic and Energy Cost Analysis,” Energy & Environmental Science 17, no. 16 (2024): 5833–5853.

B. Wanten, Y. Gorbanev, and A. Bogaerts, “Plasma-Based Conversion of CO₂ and CH₄ Into Syngas: A Dive Into the Effect of Adding Water,” Fuel 374 (2024): 132355.

R. Snoeckx and A. Bogaerts, “Plasma Technology—A Novel Solution for CO₂ Conversion?,” Chemical Society Reviews 46, no. 19 (2017): 5805–5863.

S. Xu, Plasma-Assisted Conversion of CO₂ (University of Manchester, 2017).

M. U. Rao, D. Vidyasagar, C. Ghanty, et al., “Nonthermal Plasma-Assisted Enhanced CO₂ Conversion Over NiO_x/γ-Al₂O₃ Catalyst,” Industrial & Engineering Chemistry Research 63, no. 21 (2024): 9336–9346.

J. Ye, N. Dimitratos, L. M. Rossi, N. Thonemann, A. M. Beale, and R. Wojcieszak, “Hydrogenation of CO₂ for Sustainable Fuel and Chemical Production,” Science 387, no. 6737 (2025): eadn9388.

A. Mravak, S. Vajda, and V. Bonačić-Koutecký, “Mechanism of Catalytic CO₂ Hydrogenation to Methane and Methanol Using a Bimetallic Cu₃Pd Cluster at a Zirconia Support,” Journal of Physical Chemistry C 126, no. 43 (2022): 18306–18312.

L. Liu, F. Fan, Z. Jiang, X. Gao, J. Wei, and T. Fang, “Mechanistic Study of Pd–Cu Bimetallic Catalysts for Methanol Synthesis From CO₂ Hydrogenation,” Journal of Physical Chemistry C 121, no. 47 (2017): 26287–26299.

H. Qin, H. Zhang, K. Wu, X. Wang, and W. Fan, “A Systematic Theoretical Study of CO₂ Hydrogenation Towards Methanol on Cu-Based Bimetallic Catalysts: Role of the CHO&CH₃OH Descriptor in Thermodynamic Analysis,” Physical Chemistry Chemical Physics: PCCP 26, no. 28 (2024): 19088–19104.

H. Rashid and A. Rafey, “Solid Adsorbents for Carbon Dioxide Capture: A Review,” Chemistry and Ecology 39 (2023): 775–791.

A. Sanna, K. P. Reddy, C. Emehel, et al., “Integrated CO₂ Capture and Hydrogenation in Presence of Ru–Na₂ZrO₃: An In-Situ Study,” International Journal of Hydrogen Energy 121 (2025): 118–131.

Y.-F. Huang, P.-T. Chiueh, and S.-L. Lo, “Carbon Capture of Biochar Produced by Microwave Co-Pyrolysis: Adsorption Capacity, Kinetics, and Benefits,” Environmental Science and Pollution Research 30, no. 9 (2023): 22211–22221.

S. Davoodi, B. Biswas, and R. Naidu, “Carbon Capture Efficiency of Mechanically Activated Australian Halloysite-Rich Kaolin With Varying Iron Impurities and Its Potential Reuse for Removing Dyes From Water,” Minerals 15, no. 4 (2025): 399.

T. M. Gür, “Carbon Dioxide Emissions, Capture, Storage and Utilization: Review of Materials, Processes and Technologies,” Progress in Energy and Combustion Science 89 (2022): 100965.

G. K. Rath, G. Pandey, S. Singh, et al., “Carbon Dioxide Separation Technologies: Applicable to Net Zero,” Energies 16, no. 10 (2023): 4100.

B. Petrovic, M. Gorbounov, and S. M. Soltani, “Impact of Surface Functional Groups and Their Introduction Methods on the Mechanisms of CO₂ Adsorption on Porous Carbonaceous Adsorbents,” Carbon Capture Science & Technology 3 (2022): 100045.

O. Aschenbrenner and P. Styring, “Comparative Study of Solvent Properties for Carbon Dioxide Absorption,” Energy & Environmental Science 3, no. 8 (2010): 1106–1113.

W. M. Budzianowski, “Single Solvents, Solvent Blends, and Advanced Solvent Systems in CO₂ Capture by Absorption: A Review,” International Journal of Global Warming 7, no. 2 (2015): 184–225.

R. Maniarasu, S. K. Rathore, and S. Murugan, “A Review on Materials and Processes for Carbon Dioxide Separation and Capture,” Energy & Environment 34, no. 1 (2023): 3–57.

Z. Chen, B. Yuan, G. Zhan, et al., “Energy-Efficient Biphasic Solvents for Industrial Carbon Capture: Role of Physical Solvents on CO₂ Absorption and Phase Splitting,” Environmental Science & Technology 56, no. 18 (2022): 13305–13313.

M. Li, K. Huang, J. A. Schott, Z. Wu, and S. Dai, “Effect of Metal Oxides Modification on CO₂ Adsorption Performance Over Mesoporous Carbon,” Microporous and Mesoporous Materials 249 (2017): 34–41.

N. H. Khdary, A. S. Alayyar, L. M. Alsarhan, S. Alshihri, and M. Mokhtar, “Metal Oxides as Catalyst/Supporter for CO₂ Capture and Conversion, Review,” Catalysts 12, no. 3 (2022): 300.

H. Zeng, X. Qu, D. Xu, and Y. Luo, “Porous Adsorption Materials for Carbon Dioxide Capture in Industrial Flue Gas,” Frontiers in Chemistry 10 (2022): 939701.

C. Gunathilake, M. Gangoda, and M. Jaroniec, “Mesoporous Alumina With Amidoxime Groups for CO₂ Sorption at Ambient and Elevated Temperatures,” Industrial & Engineering Chemistry Research 55, no. 19 (2016): 5598–5607.

T. Harada and T. A. Hatton, “Colloidal Nanoclusters of MgO Coated With Alkali Metal Nitrates/Nitrites for Rapid, High Capacity CO₂ Capture at Moderate Temperature,” Chemistry of Materials 27, no. 23 (2015): 8153–8161.

Y. Qiao, J. Wang, Y. Zhang, et al., “Alkali Nitrates Molten Salt Modified Commercial MgO for Intermediate-Temperature CO₂ Capture: Optimization of the Li/Na/K Ratio,” Industrial & Engineering Chemistry Research 56, no. 6 (2017): 1509–1517.

Z. Chen, L. Xing, G. Zhan, et al., “Integration of Strong Oxide-Support Interaction and Mesoporous Confinement to Engineer Efficient and Durable Zr/Al₂O₃ for Catalytic Solvent Regeneration in CO₂ Capture,” Applied Catalysis B: Environment and Energy 351 (2024): 124000.

H. Zhang, T. Yan, Z. Liu, W. Xu, Y. Cheng, and P. Kang, “Alcoholamine-Grafted Zinc Oxide Enhances CO₂ Electroreduction at Elevated Temperatures,” ACS Sustainable Chemistry & Engineering 12 (2024): 2761–2770.

F. Fathalian, H. Moghadamzadeh, A. Hemmati, and A. Ghaemi, “Efficient CO₂ Adsorption Using Chitosan, Graphene Oxide, and Zinc Oxide Composite,” Scientific Reports 14, no. 1 (2024): 3186.

S. Wang, S. Yan, X. Maa, and J. Gong, “Recent Advances in Capture of Carbon Dioxide Using Alkali-Metal-Based Oxides,” Energy & Environmental Science 4, no. 10 (2011): 3805–3819.

J. Ding, Y. Li, X. Zhang, et al., “Study on the Homologous Effects on the Performance of Alkali Metal-Doping MgO-Based Adsorbents for CO₂ Capture,” Separation and Purification Technology 355 (2025): 129673.

S. N. Firmansyah, A. A. Dwiatmoko, and R. T. Yunarti, “Hydrothermal Synthesis of High Surface Area Magnesium Oxide (MgO) Using Ionic Surfactant and Their Capacity as CO₂ Adsorbent,” Vacuum 238 (2025): 114188.

J. K. Gbe, K. Ravi, E. K. Tillous, A. Arya, M. Grafouté, and A. V. Biradar, “Designing of 3D Architecture Flower-Like Mn-Promoted MgO and Its Application for CO₂ Adsorption and CO₂-Assisted Aerobic Oxidation of Alkylbenzenes,” ACS Applied Materials & Interfaces 15, no. 14 (2023): 17879–17892.

N. Noorani, B. Barzegar, A. Mehrdad, H. Aghdasinia, S. J. Peighambardoust, and H. Kazemian, “CO₂ Capture in Activated Pyrolytic Coke/Metal Oxide Nanoparticle Composites,” Colloids and Surfaces, A: Physicochemical and Engineering Aspects 679 (2023): 132554.

S. Kumar, S. K. Saxena, V. Drozd, and A. Durygin, “An Experimental Investigation of Mesoporous MgO as a Potential Pre-Combustion CO₂ Sorbent,” Materials for Renewable and Sustainable Energy 4 (2015): 8.

G.-B. Elvira, G. C. Francisco, S. M. Víctor, and M. L. R. Alberto, “MgO-Based Adsorbents for CO₂ Adsorption: Influence of Structural and Textural Properties on the CO₂ Adsorption Performance,” Journal of Environmental Sciences 57 (2017): 418–428.

W.-J. Liu, H. Jiang, K. Tian, Y. W. Ding, and H. Q. Yu, “Mesoporous Carbon Stabilized MgO Nanoparticles Synthesized by Pyrolysis of MgCl₂ Preloaded Waste Biomass for Highly Efficient CO₂ Capture,” Environmental Science & Technology 47, no. 16 (2013): 9397–9403.

Q. Pu, Y. Wang, X. Wang, et al., “Biomass-Derived carbon/MgO-Al₂O₃ Composite With Superior Dynamic CO₂ Uptake for Post Combustion Capture Application,” Journal of CO₂ Utilization 54 (2021): 101756.

Z. Xu, T. Jiang, H. Zhang, Y. Zhao, X. Ma, and S. Wang, “Efficient MgO-Doped CaO Sorbent Pellets for High Temperature CO₂ Capture,” Frontiers of Chemical Science and Engineering 15 (2021): 698–708.

H. Cui, Q. Zhang, Y. Hu, et al., “Ultrafast and Stable CO₂ Capture Using Alkali Metal Salt-Promoted MgO–CaCO₃ Sorbents,” ACS Applied Materials & Interfaces 10, no. 24 (2018): 20611–20620.

P. Kasikamphaiboon and U. Khunjan, “CO₂ Adsorption From Biogas Using Amine-Functionalized MgO,” International Journal of Chemical Engineering 2018 (2018): 1–8.

A. M. Alkadhem, M. A. A. Elgzoly, and S. A. Onaizi, “Novel Amine-Functionalized Magnesium Oxide Adsorbents for CO₂ Capture at Ambient Conditions,” Journal of Environmental Chemical Engineering 8, no. 4 (2020): 103968.

V. A. Tuan and C. H. Lee, “Preparation of Rod-Like MgO by Simple Precipitation Method for CO₂ Capture at Ambient Temperature,” Vietnam Journal of Chemistry 56, no. 2 (2018): 197–202.

K. Ho, S. Jin, M. Zhong, A. T. Vu, and C. H. Lee, “Sorption Capacity and Stability of Mesoporous Magnesium Oxide in Post-Combustion CO₂ Capture,” Materials Chemistry and Physics 198 (2017): 154–161.

M. Bhagiyalakshmi, J. Y. Lee, and H. T. Jang, “Synthesis of Mesoporous Magnesium Oxide: Its Application to CO₂ Chemisorption,” International Journal of Greenhouse Gas Control 4, no. 1 (2010): 51–56.

W. Gao, T. Zhou, and Q. Wang, “Controlled Synthesis of MgO With Diverse Basic Sites and Its CO₂ Capture Mechanism Under Different Adsorption Conditions,” Chemical Engineering Journal 336 (2018): 710–720.

Y. Guo, C. Tan, P. Wang, et al., “Structure-Performance Relationships of Magnesium-Based CO₂ Adsorbents Prepared With Different Methods,” Chemical Engineering Journal 379 (2020): 122277.

S. T. Bararpour, D. Karami, and N. Mahinpey, “Investigation of the Effect of Alumina-Aerogel Support on the CO₂ Capture Performance of K₂CO₃,” Fuel 242 (2019): 124–132.

S. T. Bararpour, D. Karami, and N. Mahinpey, “Post-Combustion CO₂ Capture Using Supported K₂CO₃: Comparing Physical Mixing and Incipient Wetness Impregnation Preparation Methods,” Chemical Engineering Research and Design 137 (2018): 319–328.

L. Valencia, W. Rosas, A. Aguilar-Sanchez, A. P. Mathew, and A. Palmqvist, “Bio-Based Micro-/Meso-/Macroporous Hybrid Foams With Ultrahigh Zeolite Loadings for Selective Capture of Carbon Dioxide,” ACS Applied Materials & Interfaces 11, no. 43 (2019): 40424–40431.

P. Wang, J. Sun, Y. Guo, et al., “Structurally Improved, Urea-Templated, K₂CO₃-Based Sorbent Pellets for CO₂ Capture,” Chemical Engineering Journal 374 (2019): 20–28.

G. L. Seah, L. Wang, L. F. Tan, et al., “Ordered Mesoporous Alumina With Tunable Morphologies and Pore Sizes for CO₂ Capture and Dye Separation,” ACS Applied Materials & Interfaces 13, no. 30 (2021): 36117–36129.

V. Hiremath, B. T. Shiferraw, and J. G. Seo, “MgO Insertion Endowed Strong Basicity in Mesoporous Alumina Framework and Improved CO₂ Sorption Capacity,” Journal of CO₂ Utilization 42 (2020): 101294.

X. Li, Z. Wang, R. Feng, J. Huang, and Y. Fang, “CO₂ Capture on Aminosilane Functionalized Alumina-Extracted Residue of Catalytic Gasification Coal Ash,” Energy 221 (2021): 119642.

N. K. Mohammad, A. Ghaemi, and K. Tahvildari, “Hydroxide Modified Activated Alumina as an Adsorbent for CO₂ Adsorption: Experimental and Modeling,” International Journal of Greenhouse Gas Control 88 (2019): 24–37.

F. N. Ridha, V. Manovic, A. Macchi, and E. J. Anthony, “CO₂ Capture at Ambient Temperature in a Fixed Bed With CaO-Based Sorbents,” Applied Energy 140 (2015): 297–303.

S.-L. Hsieh, F. Y. Li, P. Y. Lin, et al., “CaO Recovered From Eggshell Waste as a Potential Adsorbent for Greenhouse Gas CO₂,” Journal of Environmental Management 297 (2021): 113430.

P. Jamrunroj, S. Wongsakulphasatch, A. Maneedaeng, C. K. Cheng, and S. Assabumrungrat, “Surfactant Assisted CaO-Based Sorbent Synthesis and Their Application to High-Temperature CO₂ Capture,” Powder Technology 344 (2019): 208–221.

M. Zhang, Y. Peng, Y. Sun, P. Li, and J. Yu, “Preparation of CaO–Al₂O₃ Sorbent and CO₂ Capture Performance at High Temperature,” Fuel 111 (2013): 636–642.

S. S. Kazi, A. Aranda, J. Meyer, and J. Mastin, “High Performance CaO-Based Sorbents for Pre- and Post-Combustion CO₂ Capture at High Temperature,” Energy Procedia 63 (2014): 2207–2215.

H. Sun, J. Wang, J. Zhao, et al., “Dual Functional Catalytic Materials of Ni Over Ce-Modified CaO Sorbents for Integrated CO₂ Capture and Conversion,” Applied Catalysis, B: Environmental 244 (2019): 63–75.

A. Nawar, M. Ali, A. H. Khoja, A. Waqas, M. Anwar, and M. Mahmood, “Enhanced CO₂ Capture Using Organic Acid Structure Modified Waste Eggshell Derived CaO Sorbent,” Journal of Environmental Chemical Engineering 9, no. 1 (2021): 104871.

M. Venkata Ratnam, M. Vangalapati, K. Nagamalleswara Rao, and K. Ramesh Chandra, “Efficient Removal of Methyl Orange Using Magnesium Oxide Nanoparticles Loaded Onto Activated Carbon,” Bulletin of the Chemical Society of Ethiopia 36, no. 3 (2022): 531–544.

Y. Ye, Y. Qu, and J. Sun, “Functionalized Mesoporous SiO₂ Materials for CO₂ Capture and Catalytic Conversion to Cyclic Carbonates,” Catalysis Reviews 66 (2023): 1–56.

J. Wang, L. Huang, R. Yang, et al., “Recent Advances in Solid Sorbents for CO₂ Capture and New Development Trends,” Energy & Environmental Science 7, no. 11 (2014): 3478–3518.

H. M. Khan, T. Iqbal, S. Yasin, et al., “Application of Agricultural Waste as Heterogeneous Catalysts for Biodiesel Production,” Catalysts 11 (2021): 1215.

M. Oschatz and M. Antonietti, “A Search for Selectivity to Enable CO₂ Capture With Porous Adsorbents,” Energy & Environmental Science 11, no. 1 (2018): 57–70.

R. Hernández-Huesca, L. Dı́az, and G. Aguilar-Armenta, “Adsorption Equilibria and Kinetics of CO₂, CH₄ and N₂ in Natural Zeolites,” Separation and Purification Technology 15, no. 2 (1999): 163–173.

T. D. Pham, R. Xiong, S. I. Sandler, and R. F. Lobo, “Experimental and Computational Studies on the Adsorption of CO₂ and N₂ on Pure Silica Zeolites,” Microporous and Mesoporous Materials 185 (2014): 157–166.

P. Jadhav, R. V. Chatti, R. B. Biniwale, N. K. Labhsetwar, S. Devotta, and S. S. Rayalu, “Monoethanol Amine Modified Zeolite 13X for CO₂ Adsorption at Different Temperatures,” Energy & Fuels 21, no. 6 (2007): 3555–3559.

P. J. E. Harlick and F. H. Tezel, “Adsorption of Carbon Dioxide, Methane and Nitrogen: Pure and Binary Mixture Adsorption for ZSM-5 With SiO₂/Al₂O₃ Ratio of 280,” Separation and Purification Technology 33, no. 2 (2003): 199–210.

G. Calleja, A. Jimenez, J. Pau, L. Domínguez, and P. Pérez, “Multicomponent Adsorption Equilibrium of Ethylene, Propane, Propylene and CO₂ on 13X Zeolite,” Gas Separation & Purification 8, no. 4 (1994): 247–256.

J. A. Dunne, R. Mariwala, M. Rao, S. Sircar, R. J. Gorte, and A. L. Myers, “Calorimetric Heats of Adsorption and Adsorption Isotherms. 1. O₂, N₂, Ar, CO₂, CH₄, C₂H₆, and SF₆ on Silicalite,” Langmuir 12, no. 24 (1996): 5888–5895.

T. F. de Aquino, S. T. Estevam, V. O. Viola, et al., “CO₂ Adsorption Capacity of Zeolites Synthesized From Coal Fly Ashes,” Fuel 276 (2020): 118143.

E. Davarpanah, M. Armandi, S. Hernández, et al., “CO₂ Capture on Natural Zeolite Clinoptilolite: Effect of Temperature and Role of the Adsorption Sites,” Journal of Environmental Management 275 (2020): 111229.

D. Saha, Z. Bao, F. Jia, and S. Deng, “Adsorption of CO₂, CH₄, N₂O, and N₂ on MOF-5, MOF-177, and Zeolite 5A,” Environmental Science & Technology 44, no. 5 (2010): 1820–1826.

Z. Zhang, W. Zhang, X. Chen, Q. Xia, and Z. Li, “Adsorption of CO₂ on Zeolite 13X and Activated Carbon With Higher Surface Area,” Separation Science and Technology 45, no. 5 (2010): 710–719.

T.-H. Pham, B. K. Lee, J. Kim, and C. H. Lee, “Enhancement of CO₂ Capture by Using Synthesized Nano-Zeolite,” Journal of the Taiwan Institute of Chemical Engineers 64 (2016): 220–226.

M. Razavian, S. Fatemi, and M. Masoudi-Nejad, “A Comparative Study of CO₂ and CH₄ Adsorption on Silicalite-1 Fabricated by Sonication and Conventional Method,” Adsorption Science & Technology 32, no. 1 (2014): 73–87.

D. Panda, E. A. Kumar, and S. K. Singh, “Introducing Mesoporosity in Zeolite 4A Bodies for Rapid CO₂ Capture,” Journal of CO₂ Utilization 40 (2020): 101223.

A. A. Dabbawala, I. Ismail, B. V. Vaithilingam, et al., “Synthesis of Hierarchical Porous Zeolite-Y for Enhanced CO₂ Capture,” Microporous and Mesoporous Materials 303 (2020): 110261.

Q. Liu, P. He, X. Qian, et al., “Enhanced CO₂ Adsorption Performance on Hierarchical Porous ZSM-5 Zeolite,” Energy & Fuels 31, no. 12 (2017): 13933–13941.

T. H. Nguyen, S. Kim, M. Yoon, and T. H. Bae, “Hierarchical Zeolites With Amine-Functionalized Mesoporous Domains for Carbon Dioxide Capture,” ChemSusChem 9, no. 5 (2016): 455–461.

R. Kodasma, J. Fermoso, and A. Sanna, “Li-LSX-Zeolite Evaluation for Post-Combustion CO₂ Capture,” Chemical Engineering Journal 358 (2019): 1351–1362.

C. Chen, S. S. Kim, W. S. Cho, and W. S. Ahn, “Polyethylenimine-Incorporated Zeolite 13X With Mesoporosity for Post-Combustion CO₂ Capture,” Applied Surface Science 332 (2015): 167–171.

P. Murge, S. Dinda, and S. Roy, “Zeolite-Based Sorbent for CO₂ Capture: Preparation and Performance Evaluation,” Langmuir 35, no. 46 (2019): 14751–14760.

S. Boycheva, I. Marinov, and D. Zgureva-Filipova, “Studies on the CO₂ Capture by Coal Fly Ash Zeolites: Process Design and Simulation,” Energies 14, no. 24 (2021): 8279.

S. Kumar, R. Bera, N. Das, and J. Koh, “Chitosan-Based Zeolite-Y and ZSM-5 Porous Biocomposites for H₂ and CO₂ Storage,” Carbohydrate Polymers 232 (2020): 115808.

S. S. Fatima, A. Borhan, M. Ayoub, and N. Abd Ghani, “Development and Progress of Functionalized Silica-Based Adsorbents for CO₂ Capture,” Journal of Molecular Liquids 338 (2021): 116913.

R. Girimonte, F. Testa, M. Turano, G. Leone, M. Gallo, and G. Golemme, “Amine-Functionalized Mesoporous Silica Adsorbent for CO₂ Capture in Confined-Fluidized Bed: Study of the Breakthrough Adsorption Curves as a Function of Several Operating Variables,” Processes 10, no. 2 (2022): 422.

B. Dziejarski, J. Serafin, K. Andersson, and R. Krzyżyńska, “CO₂ Capture Materials: A Review of Current Trends and Future Challenges,” Materials Today Sustainability 24 (2023): 100483.

X. Li, R. Li, K. Peng, et al., “Interlayer Functionalization of Vermiculite Derived Silica With Hierarchical Layered Porous Structure for Stable CO₂ Adsorption,” Chemical Engineering Journal 435 (2022): 134875.

Y. Le, D. Guo, B. Cheng, and J. Yu, “Amine-Functionalized Monodispersed Porous Silica Microspheres With Enhanced CO₂ Adsorption Performance and Good Cyclic Stability,” Journal of Colloid and Interface Science 408 (2013): 173–180.

J. C. Hicks, J. H. Drese, D. J. Fauth, M. L. Gray, G. Qi, and C. W. Jones, “Designing Adsorbents for CO₂ Capture From Flue Gas-Hyperbranched Aminosilicas Capable of Capturing CO₂ Reversibly,” Journal of the American Chemical Society 130, no. 10 (2008): 2902–2903.

E. S. Sanz-Pérez, M. Olivares-Marín, A. Arencibia, R. Sanz, G. Calleja, and M. M. Maroto-Valer, “CO₂ Adsorption Performance of Amino-Functionalized SBA-15 Under Post-Combustion Conditions,” International Journal of Greenhouse Gas Control 17 (2013): 366–375.

N. H. Khdary, M. A. Ghanem, M. G. Merajuddine, and F. M. Bin Manie, “Incorporation of Cu, Fe, Ag, and Au Nanoparticles in Mercapto-Silica (MOS) and Their CO₂ Adsorption Capacities,” Journal of CO₂ Utilization 5 (2014): 17–23.

W. Henao, L. Y. Jaramillo, D. López, M. Romero-Sáez, and R. Buitrago-Sierra, “Insights Into the CO₂ Capture Over Amine-Functionalized Mesoporous Silica Adsorbents Derived From Rice Husk Ash,” Journal of Environmental Chemical Engineering 8, no. 5 (2020): 104362.

Z. Shen, Q. Cai, C. Yin, et al., “Facile Synthesis of Silica Nanosheets With Hierarchical Pore Structure and Their Amine-Functionalized Composite for Enhanced CO₂ Capture,” Chemical Engineering Science 217 (2020): 115528.

R. Sanz, G. Calleja, A. Arencibia, and E. S. Sanz-Pérez, “CO₂ Adsorption on Branched Polyethyleneimine-Impregnated Mesoporous Silica SBA-15,” Applied Surface Science 256, no. 17 (2010): 5323–5328.

S. Ahmed, A. Ramli, and S. Yusup, “Development of Polyethylenimine-Functionalized Mesoporous Si-MCM-41 for CO₂ Adsorption,” Fuel Processing Technology 167 (2017): 622–630.

H. Thakkar, S. Eastman, A. Al-Mamoori, A. Hajari, A. A. Rownaghi, and F. Rezaei, “Formulation of Aminosilica Adsorbents Into 3D-Printed Monoliths and Evaluation of Their CO₂ Capture Performance,” ACS Applied Materials & Interfaces 9, no. 8 (2017): 7489–7498.

H. Zhang, A. Goeppert, S. Kar, and G. K. S. Prakash, “Structural Parameters to Consider in Selecting Silica Supports for Polyethylenimine Based CO₂ Solid Adsorbents. Importance of Pore Size,” Journal of CO₂ Utilization 26 (2018): 246–253.

X. Jiang, Y. Kong, Z. Zhao, and X. Shen, “Spherical Amine Grafted Silica Aerogels for CO₂ Capture,” RSC Advances 10, no. 43 (2020): 25911–25917.

E. S. Sanz-Pérez, A. Fernández, A. Arencibia, G. Calleja, and R. Sanz, “Hybrid Amine-Silica Materials: Determination of N Content by 29Si NMR and Application to Direct CO₂ Capture From Air,” Chemical Engineering Journal 373 (2019): 1286–1294.

M. Garip and N. Gizli, “Ionic Liquid Containing Amine-Based Silica Aerogels for CO₂ Capture by Fixed Bed Adsorption,” Journal of Molecular Liquids 310 (2020): 113227.

W. Klinthong, C.-H. Huang, and C.-S. Tan, “One-Pot Synthesis and Pelletizing of Polyethylenimine-Containing Mesoporous Silica Powders for CO₂ Capture,” Industrial & Engineering Chemistry Research 55, no. 22 (2016): 6481–6491.

K. Min, W. Choi, and M. Choi, “Macroporous Silica With Thick Framework for Steam-Stable and High-Performance Poly (Ethyleneimine)/Silica CO₂ Adsorbent,” ChemSusChem 10, no. 11 (2017): 2518–2526.

L. Wang, M. Yao, X. Hu, et al., “Amine-Modified Ordered Mesoporous Silica: The Effect of Pore Size on CO₂ Capture Performance,” Applied Surface Science 324 (2015): 286–292.

M. Abdalqadir, S. R. Gomari, and D. Hughes, “Novel Synthesis and Application of Zeolite-Y From Waste Clay for Efficient CO₂ Capture and Water Purification,” Colloids and Surfaces, A: Physicochemical and Engineering Aspects 704 (2025): 135460.

A. Farinmade, O. Ajumobi, L. Yu, et al., “Tubular Clay Nano-Straws in Ordered Mesoporous Particles Create Hierarchical Porosities Leading to Improved CO₂ Uptake,” Industrial & Engineering Chemistry Research 61, no. 4 (2022): 1694–1703.

P. Mehrmohammadi, A. Ahmadvand, and A. Ghaemi, “CO₂ Adsorption on NaOH and Acid Modified Montmorillonite: Response Surface Methodology and Machine Learning Modeling,” Journal of CO₂ Utilization 96 (2025): 103099.

Y.-H. Chen and D.-L. Lu, “CO₂ Capture by Kaolinite and Its Adsorption Mechanism,” Applied Clay Science 104 (2015): 221–228.

Y.-H. Chen and D.-L. Lu, “Amine Modification on Kaolinites to Enhance CO₂ Adsorption,” Journal of Colloid and Interface Science 436 (2014): 47–51.

C. Chen, D.-W. Park, and W.-S. Ahn, “Surface Modification of a Low Cost Bentonite for Post-Combustion CO₂ Capture,” Applied Surface Science 283 (2013): 699–704.

E. Vilarrasa-García, J. A. Cecilia, D. C. S. Azevedo, C. L. Cavalcante, and E. Rodríguez-Castellón, “Evaluation of Porous Clay Heterostructures Modified With Amine Species as Adsorbent for the CO₂ Capture,” Microporous and Mesoporous Materials 249 (2017): 25–33.

G. Gómez-Pozuelo, E. S. Sanz-Pérez, A. Arencibia, P. Pizarro, R. Sanz, and D. P. Serrano, “CO₂ Adsorption on Amine-Functionalized Clays,” Microporous and Mesoporous Materials 282 (2019): 38–47.

A. E. I. Elkhalifah, M. A. Bustam, M. S. Azmi, and T. Murugesan, “Carbon Dioxide Retention on Bentonite Clay Adsorbents Modified by Mono-, Di- and Triethanolamine Compounds,” Advanced Materials Research 917 (2014): 115–122.

E. Vilarrasa-García, J. A. Cecilia, E. Rodríguez Aguado, et al., “Amino-Modified Pillared Adsorbent From Water-Treatment Solid Wastes Applied to CO₂/N₂ Separation,” Adsorption 23 (2017): 405–421.

L. Stevens, K. Williams, W. Y. Han, et al., “Preparation and CO₂ Adsorption of Diamine Modified Montmorillonite via Exfoliation Grafting Route,” Chemical Engineering Journal 215–216 (2013): 699–708.

J. A. Cecilia, E. Vilarrasa-García, C. L. Cavalcante, D. C. S. Azevedo, F. Franco, and E. Rodríguez-Castellón, “Evaluation of Two Fibrous Clay Minerals (Sepiolite and Palygorskite) for CO₂ Capture,” Journal of environmental chemical engineering 6, no. 4 (2018): 4573–4587.

J. Ouyang, C. Zheng, W. Gu, Y. Zhang, H. Yang, and S. L. Suib, “Textural Properties Determined CO₂ Capture of Tetraethylenepentamine Loaded SiO₂ Nanowires From α-Sepiolite,” Chemical Engineering Journal 337 (2018): 342–350.

X. Gao, S. Yang, L. Hu, S. Cai, L. Wu, and S. Kawi, “Carbonaceous Materials as Adsorbents for CO₂ Capture: Synthesis and Modification,” Carbon Capture Science & Technology 3 (2022): 100039.

S.-Y. Lee and S.-J. Park, “Carbon Dioxide Adsorption Performance of Ultramicroporous Carbon Derived From Poly (Vinylidene Fluoride),” Journal of Analytical and Applied Pyrolysis 106 (2014): 147–151.

J. Wang, I. Senkovska, M. Oschatz, et al., “Imine-Linked Polymer-Derived Nitrogen-Doped Microporous Carbons With Excellent CO₂ Capture Properties,” ACS Applied Materials & Interfaces 5, no. 8 (2013): 3160–3167.

L.-Y. Meng and S.-J. Park, “Effect of Exfoliation Temperature on Carbon Dioxide Capture of Graphene Nanoplates,” Journal of Colloid and Interface Science 386, no. 1 (2012): 285–290.

D.-I. Jang and S.-J. Park, “Influence of Nickel Oxide on Carbon Dioxide Adsorption Behaviors of Activated Carbons,” Fuel 102 (2012): 439–444.

S. Chowdhury, G. K. Parshetti, and R. Balasubramanian, “Post-Combustion CO₂ Capture Using Mesoporous TiO₂/Graphene Oxide Nanocomposites,” Chemical Engineering Journal 263 (2015): 374–384.

J. S. Lee, X. Wang, H. Luo, G. A. Baker, and S. Dai, “Facile Ionothermal Synthesis of Microporous and Mesoporous Carbons From Task Specific Ionic Liquids,” Journal of the American Chemical Society 131, no. 13 (2009): 4596–4597.

E. D. Bates, R. D. Mayton, I. Ntai, and J. H. Davis, “CO₂ Capture by a Task-Specific Ionic Liquid,” Journal of the American Chemical Society 124, no. 6 (2002): 926–927.

S.-Y. Lee and S.-J. Park, “Isothermal Exfoliation of Graphene Oxide by a New Carbon Dioxide Pressure Swing Method,” Carbon 68 (2014): 112–117.

N. P. Wickramaratne and M. Jaroniec, “Activated Carbon Spheres for CO₂ Adsorption,” ACS Applied Materials & Interfaces 5, no. 5 (2013): 1849–1855.

J. Serafin and O. F. Cruz, “Promising Activated Carbons Derived From Common Oak Leaves and Their Application in CO₂ Storage,” Journal of Environmental Chemical Engineering 10, no. 3 (2022): 107642.

L. Wang, F. Sun, F. Hao, et al., “A Green Trace K₂CO₃ Induced Catalytic Activation Strategy for Developing Coal-Converted Activated Carbon as Advanced Candidate for CO₂ Adsorption and Supercapacitors,” Chemical Engineering Journal 383 (2020): 123205.

N. A. Rashidi and S. Yusup, “Potential of Palm Kernel Shell as Activated Carbon Precursors Through Single Stage Activation Technique for Carbon Dioxide Adsorption,” Journal of Cleaner Production 168 (2017): 474–486.

M. Danish, V. Parthasarthy, and M. K. Al Mesfer, “CO₂ Capture by Low-Cost Date Pits-Based Activated Carbon and Silica Gel,” Materials 14, no. 14 (2021): 3885.

A. E. Ogungbenro, D. V. Quang, K. A. Al-Ali, L. F. Vega, and M. R. M. Abu-Zahra, “Physical Synthesis and Characterization of Activated Carbon From Date Seeds for CO₂ Capture,” Journal of Environmental Chemical Engineering 6, no. 4 (2018): 4245–4252.

A. S. González, M. G. Plaza, F. Rubiera, and C. Pevida, “Sustainable Biomass-Based Carbon Adsorbents for Post-Combustion CO₂ Capture,” Chemical Engineering Journal 230 (2013): 456–465.

A. S. Ello, L. K. C. de Souza, A. Trokourey, and M. Jaroniec, “Coconut Shell-Based Microporous Carbons for CO₂ Capture,” Microporous and Mesoporous Materials 180 (2013): 280–283.

M. G. Plaza, A. S. González, C. Pevida, J. J. Pis, and F. Rubiera, “Valorisation of Spent Coffee Grounds as CO₂ Adsorbents for Postcombustion Capture Applications,” Applied Energy 99 (2012): 272–279.

J. J. Manyà, B. González, M. Azuara, and G. Arner, “Ultra-Microporous Adsorbents Prepared From Vine Shoots-Derived Biochar With High CO₂ Uptake and CO₂/N₂ Selectivity,” Chemical Engineering Journal 345 (2018): 631–639.

J.-S. Bae and S. Su, “Macadamia Nut Shell-Derived Carbon Composites for Post Combustion CO₂ Capture,” International Journal of Greenhouse Gas Control 19 (2013): 174–182.

J. Serafin, M. Ouzzine, C. Xing, H. El Ouahabi, A. Kamińska, and J. Sreńscek-Nazzal, “Activated Carbons From the Amazonian Biomass Andiroba Shells Applied as a CO₂ Adsorbent and a Cheap Semiconductor Material,” Journal of CO₂ Utilization 62, no. 62 (2022): 102071.

M. G. Plaza, C. Pevida, B. Arias, et al., “Different Approaches for the Development of Low-Cost CO₂ Adsorbents,” Journal of Environmental Engineering 135, no. 6 (2009): 426–432.

M. S. Shafeeyan, W. M. A. W. Daud, A. Houshmand, and A. Arami-Niya, “Ammonia Modification of Activated Carbon to Enhance Carbon Dioxide Adsorption: Effect of Pre-Oxidation,” Applied Surface Science 257, no. 9 (2011): 3936–3942.

X. Liu, C. Sun, H. Liu, W. H. Tan, W. Wang, and C. Snape, “Developing Hierarchically Ultra-Micro/Mesoporous Biocarbons for Highly Selective Carbon Dioxide Adsorption,” Chemical Engineering Journal 361 (2019): 199–208.

E. Mehrvarz, A. A. Ghoreyshi, and M. Jahanshahi, “Surface Modification of Broom Sorghum-Based Activated Carbon via Functionalization With Triethylenetetramine and Urea for CO₂ Capture Enhancement,” Frontiers of Chemical Science and Engineering 11 (2017): 252–265.

A. Boonpoke, S. Chiarakorn, N. Laosiripojana, S. Towprayoon, and A. Chidthaisong, “Investigation of CO₂ Adsorption by Bagasse-Based Activated Carbon,” Korean Journal of Chemical Engineering 29 (2012): 89–94.

A. Kongnoo, P. Intharapat, P. Worathanakul, and C. Phalakornkule, “Diethanolamine Impregnated Palm Shell Activated Carbon for CO₂ Adsorption at Elevated Temperatures,” Journal of Environmental Chemical Engineering 4, no. 1 (2016): 73–81.

S. Shahkarami, A. K. Dalai, and J. Soltan, “Enhanced CO₂ Adsorption Using MgO-Impregnated Activated Carbon: Impact of Preparation Techniques,” Industrial & Engineering Chemistry Research 55, no. 20 (2016): 5955–5964.

Y. Guo, C. Zhao, C. Li, and S. Lu, “Application of PEI–K₂CO₃/AC for Capturing CO₂ From Flue Gas After Combustion,” Applied Energy 129 (2014): 17–24.

Y. Liu, P. Ghimire, and M. Jaroniec, “Copper Benzene-1, 3, 5-Tricarboxylate (Cu-BTC) Metal-Organic Framework (MOF) and Porous Carbon Composites as Efficient Carbon Dioxide Adsorbents,” Journal of Colloid and Interface Science 535 (2019): 122–132.

A. K. Adhikari and K.-S. Lin, “Improving CO₂ Adsorption Capacities and CO₂/N₂ Separation Efficiencies of MOF-74 (Ni, Co) by Doping Palladium-Containing Activated Carbon,” Chemical Engineering Journal 284 (2016): 1348–1360.

G.-J. Shin, K. Rhee, and S.-J. Park, “Improvement of CO₂ Capture by Graphite Oxide in Presence of Polyethylenimine,” International Journal of Hydrogen Energy 41, no. 32 (2016): 14351–14359.

H. Seok-Min, K. S. Hyun, and L. K. Bong, Adsorption of Carbon Dioxide on 3-Aminopropyl-Triethoxysilane Modified Graphite Oxide (2013).

A. K. Mishra and S. Ramaprabhu, Study of CO₂ Adsorption in Low Cost Graphite Nanoplatelets (2010).

M. Seredych, E. Rodríguez-Castellón, and T. J. Bandosz, “Alterations of S-Doped Porous Carbon-rGO Composites Surface Features Upon CO₂ Adsorption at Ambient Conditions,” Carbon 107 (2016): 501–509.

H. Yuan, L.-Y. Meng, and S.-J. Park, “KOH-Activated Graphite Nanofibers as CO₂ Adsorbents,” Carbon letters 19 (2016): 99–103.

L.-Y. Meng and S.-J. Park, “Effect of Heat Treatment on CO₂ Adsorption of KOH-Activated Graphite Nanofibers,” Journal of Colloid and Interface Science 352, no. 2 (2010): 498–503.

X. Ma, R. Chen, K. Zhou, et al., “Activated Porous Carbon With an Ultrahigh Surface Area Derived From Waste Biomass for Acetone Adsorption, CO₂ Capture, and Light Hydrocarbon Separation,” ACS Sustainable Chemistry & Engineering 8, no. 31 (2020): 11721–11728.

J. Serafin, U. Narkiewicz, A. W. Morawski, R. J. Wróbel, and B. Michalkiewicz, “Highly Microporous Activated Carbons From Biomass for CO₂ Capture and Effective Micropores at Different Conditions,” Journal of CO₂ Utilization 18 (2017): 73–79.

C. Zhang, W. Song, Q. Ma, L. Xie, X. Zhang, and H. Guo, “Enhancement of CO₂ Capture on Biomass-Based Carbon From Black Locust by KOH Activation and Ammonia Modification,” Energy & Fuels 30, no. 5 (2016): 4181–4190.

D. Li, T. Ma, R. Zhang, Y. Tian, and Y. Qiao, “Preparation of Porous Carbons With High Low-Pressure CO₂ Uptake by KOH Activation of Rice Husk Char,” Fuel 139 (2015): 68–70.

H. M. Coromina, D. A. Walsh, and R. Mokaya, “Biomass-Derived Activated Carbon With Simultaneously Enhanced CO₂ Uptake for Both Pre and Post Combustion Capture Applications,” Journal of Materials Chemistry A 4, no. 1 (2016): 280–289.

H. Wei, H. Chen, N. Fu, et al., “Excellent Electrochemical Properties and Large CO₂ Capture of Nitrogen-Doped Activated Porous Carbon Synthesised From Waste Longan Shells,” Electrochimica Acta 231 (2017): 403–411.

O. Boujibar, A. Souikny, F. Ghamouss, O. Achak, M. Dahbi, and T. Chafik, “CO₂ Capture Using N-Containing Nanoporous Activated Carbon Obtained From Argan Fruit Shells,” Journal of Environmental Chemical Engineering 6, no. 2 (2018): 1995–2002.

W. Travis, S. Gadipelli, and Z. Guo, “Superior CO₂ Adsorption From Waste Coffee Ground Derived Carbons,” RSC Advances 5, no. 37 (2015): 29558–29562.

F. Shen, Y. Wang, L. Li, K. Zhang, R. L. Smith, and X. Qi, “Porous Carbonaceous Materials From Hydrothermal Carbonization and KOH Activation of Corn Stover for Highly Efficient CO₂ Capture,” Chemical Engineering Communications 205, no. 4 (2018): 423–431.

T. Xu, Z. Wu, C. Lv, et al., “Chemiresistive NH Sensor of Cotton-Stalk-Based Carbon@ MoS Composites Promoted by Heterojunction,” IEEE Sensors Journal 22, no. 21 (2022): 20177–20185.

P. Lahijani, M. Mohammadi, and A. R. Mohamed, “Metal Incorporated Biochar as a Potential Adsorbent for High Capacity CO₂ Capture at Ambient Condition,” Journal of CO₂ Utilization 26 (2018): 281–293.

A. E. Creamer, B. Gao, and S. Wang, “Carbon Dioxide Capture Using Various Metal Oxyhydroxide–Biochar Composites,” Chemical Engineering Journal 283 (2016): 826–832.

N. A. Zubbri, A. R. Mohamed, N. Kamiuchi, and M. Mohammadi, “Enhancement of CO₂ Adsorption on Biochar Sorbent Modified by Metal Incorporation,” Environmental Science and Pollution Research 27 (2020): 11809–11829.

X. Zhang, J. Wu, H. Yang, et al., “Preparation of Nitrogen-Doped Microporous Modified Biochar by High Temperature CO₂–NH₃ Treatment for CO₂ Adsorption: Effects of Temperature,” RSC Advances 6, no. 100 (2016): 98157–98166.

P. D. Dissanayake, S. You, A. D. Igalavithana, et al., “Biochar-Based Adsorbents for Carbon Dioxide Capture: A Critical Review,” Renewable and Sustainable Energy Reviews 119 (2020): 109582.

K. Simeonidis, E. Kokkinos, E. Kaprara, and A. Zouboulis, “ Biomass-Derived Nanocomposites: A Critical Evaluation of Their Performance Toward the Capture of Inorganic Pollutants,” in Nano-Biosorbents for Decontamination of Water, Air, and Soil Pollution (Elsevier, 2022), 569–603.

A. C. Pierre, E. Elaloui, and G. M. Pajonk, “Comparison of the Structure and Porous Texture of Alumina Gels Synthesized by Different Methods,” Langmuir 14, no. 1 (1998): 66–73.

Y. Mizushima and M. Hori, “Properties of Alumina Aerogels Prepared Under Different Conditions,” Journal of Non-Crystalline Solids 167, no. 1–2 (1994): 1–8.

S. K. Sharma, B. K. Sanfui, A. Katare, and B. Mandal, “Fabrication and Performance Evaluation of Industrial Alumina Based Graded Ceramic Substrate for CO₂ Selective Amino Silicate Membrane,” ACS Applied Materials & Interfaces 12, no. 36 (2020): 40269–40284.

Y. Shen, W. Shi, D. Zhang, P. Na, and B. Fu, “The Removal and Capture of CO₂ From Biogas by Vacuum Pressure Swing Process Using Silica Gel,” Journal of CO₂ Utilization 27 (2018): 259–271.

K. Wang, H. Shang, L. Li, et al., “Efficient CO₂ Capture on Low-Cost Silica Gel Modified by Polyethyleneimine,” Journal of Natural Gas Chemistry 21, no. 3 (2012): 319–323.

J.-T. Anyanwu, Y. Wang, and R. T. Yang, “Amine-Grafted Silica Gels for CO₂ Capture Including Direct Air Capture,” Industrial & Engineering Chemistry Research 59, no. 15 (2019): 7072–7079.

S. R. Caskey, A. G. Wong-Foy, and A. J. Matzger, “Dramatic Tuning of Carbon Dioxide Uptake via Metal Substitution in a Coordination Polymer With Cylindrical Pores,” Journal of the American Chemical Society 130, no. 33 (2008): 10870–10871.

P. D. C. Dietzel, R. E. Johnsen, H. Fjellvåg, et al., “Adsorption Properties and Structure of CO₂ Adsorbed on Open Coordination Sites of Metal–Organic Framework Ni₂ (dhtp) From Gas Adsorption, IR Spectroscopy and X-Ray Diffraction,” Chemical Communications no. 41 (2008): 5125–5127.

A. R. Millward and O. M. Yaghi, “Metal−Organic Frameworks With Exceptionally High Capacity for Storage of Carbon Dioxide at Room Temperature,” Journal of the American Chemical Society 127, no. 51 (2005): 17998–17999.

L. Lei, Y. Cheng, C. Chen, M. Kosari, Z. Jiang, and C. He, “Taming Structure and Modulating Carbon Dioxide (CO₂) Adsorption Isosteric Heat of Nickel-Based Metal Organic Framework (MOF-74 (Ni)) for Remarkable CO₂ Capture,” Journal of Colloid and Interface Science 612 (2022): 132–145.

X. He, D.-R. Chen, and W.-N. Wang, “Bimetallic Metal-Organic Frameworks (MOFs) Synthesized Using the Spray Method for Tunable CO₂ Adsorption,” Chemical Engineering Journal 382 (2020): 122825.

Q. Yan, Y. Lin, P. Wu, et al., “Designed Synthesis of Functionalized Two-Dimensional Metal–Organic Frameworks With Preferential CO₂ Capture,” ChemPlusChem 78, no. 1 (2013): 86–91.

H.-M. Wen, C. Liao, L. Li, et al., “A Metal–Organic Framework With Suitable Pore Size and Dual Functionalities for Highly Efficient Post-Combustion CO₂ Capture,” Journal of Materials Chemistry A 7, no. 7 (2019): 3128–3134.

Y. Cao, Y. Zhao, F. Song, and Q. Zhong, “Alkali Metal Cation Doping of Metal-Organic Framework for Enhancing Carbon Dioxide Adsorption Capacity,” Journal of Energy Chemistry 23, no. 4 (2014): 468–474.

C. R. Wade and M. Dincă, “Investigation of the Synthesis, Activation, and Isosteric Heats of CO₂ Adsorption of the Isostructural Series of Metal–Organic Frameworks M₃(BTC)₂ (M = Cr, Fe, Ni, Cu, Mo, Ru),” Dalton Transactions 41, no. 26 (2012): 7931–7938.

T. K. Prasad and M. P. Suh, “Control of Interpenetration and Gas-Sorption Properties of Metal–Organic Frameworks by a Simple Change in Ligand Design,” Chemistry–A European Journal 18, no. 28 (2012): 8673–8680.

H. Furukawa, N. Ko, Y. B. Go, et al., “Ultrahigh Porosity in Metal-Organic Frameworks,” Science 329, no. 5990 (2010): 424–428.

B. Soleimani, M. Niknam Shahrak, and K. S. Walton, “The Influence of Different Functional Groups on Enhancing CO₂ Capture in Metal-Organic Framework Adsorbents,” Journal of the Taiwan Institute of Chemical Engineers 163 (2024): 105638.

P. Liu, K. Cai, D. J. Tao, and T. Zhao, “The Mega-Merger Strategy: M@ COF Core-Shell Hybrid Materials for Facilitating CO₂ Capture and Conversion to Monocyclic and Polycyclic Carbonates,” Applied Catalysis, B: Environmental 341 (2024): 123317.

Y. Zeng, R. Zou, and Y. Zhao, “Covalent Organic Frameworks for CO₂ Capture,” Advanced Materials 28, no. 15 (2016): 2855–2873.

L. Ge, H. Song, J. Zhu, Y. Zhang, Z. Zhou, and B. Van der Bruggen, “Metal/Covalent–Organic Framework Based Thin Film Nanocomposite Membranes for Advanced Separations,” Journal of Materials Chemistry A 12, no. 14 (2024): 7975–8013.

Y. Tian, S. Q. Xu, C. Qian, Z. F. Pang, G. F. Jiang, and X. Zhao, “Two-Dimensional Dual-Pore Covalent Organic Frameworks Obtained From the Combination of Two D_2h Symmetrical Building Blocks,” Chemical Communications 52, no. 78 (2016): 11704–11707.

Q. Gao, X. Li, G. H. Ning, et al., “Covalent Organic Framework With Frustrated Bonding Network for Enhanced Carbon Dioxide Storage,” Chemistry of Materials 30, no. 5 (2018): 1762–1768.

B. Dong, L. Wang, S. Zhao, et al., “Immobilization of Ionic Liquids to Covalent Organic Frameworks for Catalyzing the Formylation of Amines With CO₂ and Phenylsilane,” Chemical Communications 52, no. 44 (2016): 7082–7085.

Z. Kahveci, T. Islamoglu, G. A. Shar, R. Ding, and H. M. El-Kaderi, “Targeted Synthesis of a Mesoporous Triptycene-Derived Covalent Organic Framework,” CrystEngComm 15, no. 8 (2013): 1524–1527.

O. Buyukcakir, S. H. Je, S. N. Talapaneni, D. Kim, and A. Coskun, “Charged Covalent Triazine Frameworks for CO₂ Capture and Conversion,” ACS Applied Materials & Interfaces 9 (2017): 7209–7216.

N. Huang, X. Chen, R. Krishna, and D. Jiang, “Two-Dimensional Covalent Organic Frameworks for Carbon Dioxide Capture Through Channel-Wall Functionalization,” Angewandte Chemie International Edition 54, no. 10 (2015): 2986–2990.

X. Li, Q. Su, K. Luo, H. Li, G. Li, and Q. Wu, “Construction of a Highly Heteroatom-Functionalized Covalent Organic Framework and Its CO₂ Capture Capacity and CO₂/N₂ Selectivity,” Materials Letters 282 (2021): 128704.

H. Furukawa and O. M. Yaghi, “Storage of Hydrogen, Methane, and Carbon Dioxide in Highly Porous Covalent Organic Frameworks for Clean Energy Applications,” Journal of the American Chemical Society 131, no. 25 (2009): 8875–8883.

H. Zhu, S. Li, J. Zhang, L. Zhao, and Y. Huang, “A Highly Effective and Low-Cost Sepiolite-Based Solid Amine Adsorbent for CO₂ Capture in Post-Combustion,” Separation and Purification Technology 306 (2023): 122627.

C. Zhou, S. Yu, K. Ma, et al., “Amine-Functionalized Mesoporous Monolithic Adsorbents for Post-Combustion Carbon Dioxide Capture,” Chemical Engineering Journal 413 (2021): 127675.

C. Xu, Y. Zhang, T. Yang, et al., “Adsorption Mechanisms and Regeneration Heat Analysis of a Solid Amine Sorbent During CO₂ Capture in Wet Flue Gas,” Energy 284 (2023): 129379.

K. J. Chao, W. Klinthong, and C. S. Tan, “CO₂ Adsorption Ability and Thermal Stability of Amines Supported on Mesoporous Silica SBA-15 and Fumed Silica,” Journal of the Chinese Chemical Society 60, no. 7 (2013): 735–744.

B. Boukoussa, A. Hakiki, N. Bouazizi, et al., “Mesoporous Silica Supported Amine and Amine-Copper Complex for CO₂ Adsorption: Detailed Reaction Mechanism of Hydrophilic Character and CO₂ Retention,” Journal of Molecular Structure 1191 (2019): 175–182.

L. Guo, X. Hu, G. Hu, et al., “Tetraethylenepentamine Modified Protonated Titanate Nanotubes for CO₂ Capture,” Fuel Processing Technology 138 (2015): 663–669.

J. C. Fisher, J. Tanthana, and S. S. Chuang, “Oxide-Supported Tetraethylenepentamine for CO₂ Capture,” Environmental Progress & Sustainable Energy 28, no. 4 (2009): 589–598.

D. V. Quang, A. Dindi, K. Al-Ali, and M. R. M. Abu-Zahra, “Template-Free Amine-Bridged Silsesquioxane With Dangling Amino Groups and Its CO₂ Adsorption Performance,” Journal of Materials Chemistry A 6, no. 46 (2018): 23690–23702.

R. Stanton and D. J. Trivedi, “Investigating the Increased CO₂ Capture Performance of Amino Acid Functionalized Nanoporous Materials From First-Principles and Grand Canonical Monte Carlo Simulations,” Journal of Physical Chemistry Letters 14 (2023): 5069–5076.

Z. Huang, M. Mohamedali, D. Karami, and N. Mahinpey, “Evaluation of Supported Multi-Functionalized Amino Acid Ionic Liquid-Based Sorbents for Low Temperature CO₂ Capture,” Fuel 310 (2022): 122284.

X. Li, K. Peng, X. Zhao, et al., “Amine-Functionalized Mesoporous Silica Derived From Natural Phyllosilicate for Efficient CO₂ Adsorption,” Applied Clay Science 256 (2024): 107433.

E. Y. Safronova, D. Y. Voropaeva, A. A. Lysova, O. V. Korchagin, V. A. Bogdanovskaya, and A. B. Yaroslavtsev, “On the Properties of Nafion Membranes Recast From Dispersion in N-Methyl-2-Pyrrolidone,” Polymers 14, no. 23 (2022): 5275.

N. Noorani, A. Mehrdad, and I. Ahadzadeh, “CO₂ Absorption in Amino Acid-Based Ionic Liquids: Experimental and Theoretical Studies,” Fluid Phase Equilibria 547 (2021): 113185.

X. Wang, N. G. Akhmedov, Y. Duan, D. Luebke, D. Hopkinson, and B. Li, “Amino Acid-Functionalized Ionic Liquid Solid Sorbents for Post-Combustion Carbon Capture,” ACS Applied Materials & Interfaces 5, no. 17 (2013): 8670–8677.

J. Ren, Z. Li, Y. Chen, Z. Yang, and X. Lu, “Supported Ionic Liquid Sorbents for CO₂ Capture From Simulated Flue-Gas,” Chinese Journal of Chemical Engineering 26, no. 11 (2018): 2377–2384.

V. Hiremath, A. H. Jadhav, H. Lee, S. Kwon, and J. G. Seo, “Highly Reversible CO₂ Capture Using Amino Acid Functionalized Ionic Liquids Immobilized on Mesoporous Silica,” Chemical Engineering Journal 287 (2016): 602–617.

Y. Uehara, D. Karami, and N. Mahinpey, “Amino Acid Ionic Liquid-Modified Mesoporous Silica Sorbents With Remaining Surfactant for CO₂ Capture,” Adsorption 25 (2019): 703–716.

Y. Zhao, H. Ge, Y. Miao, J. Chen, and W. Cai, “CO₂ Capture Ability of Cu-Based Metal-Organic Frameworks Synergized With Amino Acid-Functionalized Layered Materials,” Catalysis Today 356 (2020): 604–612.

W.-L. Xu, J. Y. Zhang, N. N. Cheng, et al., “Facilely Synthesized Mesoporous Polymer for Dispersion of Amino Acid Ionic Liquid and Effective Capture of Carbon Dioxide From Anthropogenic Source,” Journal of the Taiwan Institute of Chemical Engineers 125 (2021): 115–121.

X. Wang, W. Zeng, H. Zhang, et al., “The Dynamic CO₂ Adsorption of Polyethylene Polyamine-Loaded MCM-41 Before and After Methoxypolyethylene Glycol Codispersion,” RSC Advances 9, no. 46 (2019): 27050–27059.

A. C. Dassanayake and M. Jaroniec, “Activated Polypyrrole-Derived Carbon Spheres for Superior CO₂ Uptake at Ambient Conditions,” Colloids and Surfaces, A: Physicochemical and Engineering Aspects 549 (2018): 147–154.

Y. Chen, M. He, J. Zhang, et al., “Design of Ultrathin Cross-Linked Poly (Ethylene Oxide) Selective Layer for High-Performance CO₂ Capture,” Chemical Engineering Journal 478 (2023): 147530.

Z. Huang, Study on Supported Triamino-functionalized Ionic Liquids for Carbon Dioxide Capture (Schulich School of Engineering, 2021).

C. Guo, N. Li, L. Ji, et al., “N- and O-Doped Carbonaceous Nanotubes From Polypyrrole for Potential Application in High-Performance Capacitance,” Journal of Power Sources 247 (2014): 660–666.

K. Gokkus, “New Hyper-Crosslinked Polymers for Enhanced CO₂ Adsorption: Synthesis and Characterization,” Sustainable Chemistry and Pharmacy 45 (2025): 102015.

D. Jiang, S. M. Mahurin, and S. Dai, Materials for Carbon Capture (John Wiley & Sons, 2020).

A. Sattari, A. Ramazani, H. Aghahosseini, and M. K. Aroua, “The Application of Polymer Containing Materials in CO₂ Capturing via Absorption and Adsorption Methods,” Journal of CO₂ Utilization 48 (2021): 101526.

B. Zhang, J. Yan, G. Li, and Z. Wang, “Carboxyl-, Hydroxyl-, and Nitro-Functionalized Porous Polyaminals for Highly Selective CO₂ Capture,” ACS Applied Polymer Materials 1, no. 6 (2019): 1524–1531.

Y. J. Heintz, L. Sehabiague, B. I. Morsi, K. L. Jones, and H. W. Pennline, “Novel Physical Solvents for Selective CO₂ Capture From Fuel Gas Streams at Elevated Pressures and Temperatures,” Energy & Fuels 22, no. 6 (2008): 3824–3837.

X. Shen, H. Du, R. H. Mullins, and R. R. Kommalapati, “Polyethylenimine Applications in Carbon Dioxide Capture and Separation: From Theoretical Study to Experimental Work,” Energy Technology 5, no. 6 (2017): 822–833.

J. Rolker, M. Seiler, L. Mokrushina, and W. Arlt, “Potential of Branched Polymers in the Field of Gas Absorption: Experimental Gas Solubilities and Modeling,” Industrial & Engineering Chemistry Research 46, no. 20 (2007): 6572–6583.

R. Enick, P. Koronaios, C. Stevenson, et al., “Hydrophobic Polymeric Solvents for the Selective Absorption of CO₂ From Warm Gas Streams That Also Contain H₂ and H₂O,” Energy & Fuels 27, no. 11 (2013): 6913–6920.

J. Wang, D. Long, H. Zhou, Q. Chen, X. Liu, and L. Ling, “Surfactant Promoted Solid Amine Sorbents for CO₂ Capture,” Energy & Environmental Science 5, no. 2 (2012): 5742–5749.

A. Dave, M. Dave, Y. Huang, S. Rezvani, and N. Hewitt, “Process Design for H₂S Enrichment in Physical Solvent DMEPEG,” International Journal of Greenhouse Gas Control 50 (2016): 261–270.

S. M. Khan, H. Kitayama, Y. Yamada, et al., “High CO₂ Sensitivity and Reversibility on Nitrogen-Containing Polymer by Remarkable CO₂ Adsorption on Nitrogen Sites,” Journal of Physical Chemistry C 122, no. 42 (2018): 24143–24149.

C. Xu, Y. Zhu, C. Yao, et al., “Facile Synthesis of Tetraphenylethene-Based Conjugated Microporous Polymers as Adsorbents for CO₂ and Organic Vapor Uptake,” New Journal of Chemistry 44, no. 2 (2020): 317–321.

L. Wang, W. Xie, G. Xu, S. Zhang, C. Yao, and Y. Xu, “Synthesis of Thiophene-Based Conjugated Microporous Polymers for High Iodine and Carbon Dioxide Capture,” Polymers for Advanced Technologies 33, no. 2 (2022): 584–590.

Y. Liu, S. Wang, X. Meng, Y. Ye, X. Song, and Z. Liang, “Increasing the Surface Area and CO₂ Uptake of Conjugated Microporous Polymers via a Post-Knitting Method,” Materials Chemistry Frontiers 5, no. 14 (2021): 5319–5327.

Y. Hosseini, M. Najafi, S. Khalili, M. Jahanshahi, and M. Peyravi, “Assembly of Amine-Functionalized Graphene Oxide for Efficient and Selective Adsorption of CO₂,” Materials Chemistry and Physics 270 (2021): 124788.

L. An, S. Liu, L. Wang, et al., “Novel Nitrogen-Doped Porous Carbons Derived From Graphene for Effective CO₂ Capture,” Industrial & Engineering Chemistry Research 58, no. 8 (2019): 3349–3358.

K. Xia, R. Xiong, Y. Chen, et al., “Tuning the Pore Structure and Surface Chemistry of Porous Graphene for CO₂ Capture and H₂ Storage,” Colloids and Surfaces, A: Physicochemical and Engineering Aspects 622 (2021): 126640.

B. Szczęśniak and J. Choma, “Graphene-Containing Microporous Composites for Selective CO₂ Adsorption,” Microporous and Mesoporous Materials 292 (2020): 109761.

N. Politakos, I. Barbarin, T. Cordero-Lanzac, A. Gonzalez, R. Zangi, and R. Tomovska, “Reduced Graphene Oxide/Polymer Monolithic Materials for Selective CO₂ Capture,” Polymers 12, no. 4 (2020): 936.

S. Wang, L. Shao, Y. Sang, and J. Huang, “Hollow Hyper-Cross-Linked Polymer Microspheres for Efficient Rhodamine B Adsorption and CO₂ Capture,” Journal of Chemical & Engineering Data 64, no. 4 (2019): 1662–1670.

X. Jiang, Y. Liu, J. Liu, X. Fu, Y. Luo, and Y. Lyu, “Hypercrosslinked Conjugated Microporous Polymers for Carbon Capture and Energy Storage,” New Journal of Chemistry 41, no. 10 (2017): 3915–3919.

D. Chang, M. Yu, C. Zhang, et al., “Indolo [3, 2-b] Carbazole-Containing Hypercrosslinked Microporous Polymer Networks for Gas Storage and Separation,” Microporous and Mesoporous Materials 228 (2016): 231–236.

K. A. Fayemiwo, N. Chiarasumran, S. A. Nabavi, et al., “Eco-Friendly Fabrication of a Highly Selective Amide-Based Polymer for CO₂ Capture,” Industrial & Engineering Chemistry Research 58, no. 39 (2019): 18160–18167.

L. Shao, S. Wang, M. Liu, J. Huang, and Y. N. Liu, “Triazine-Based Hyper-Cross-Linked Polymers Derived Porous Carbons for CO₂ Capture,” Chemical Engineering Journal 339 (2018): 509–518.

Y. Wen, J. Yuan, X. Ma, S. Wang, and Y. Liu, “Polymeric Nanocomposite Membranes for Water Treatment: A Review,” Environmental Chemistry Letters 17, no. 4 (2019): 1539–1551.

W. R. Alesi, and J. R. Kitchin, “Evaluation of a Primary Amine-Functionalized Ion-Exchange Resin for CO₂ Capture,” Industrial & Engineering Chemistry Research 51, no. 19 (2012): 6907–6915.

X. Wang, J. Song, Y. Chen, et al., “CO₂ Absorption Over Ion Exchange Resins: The Effect of Amine Functional Groups and Microporous Structures,” Industrial & Engineering Chemistry Research 59, no. 38 (2020): 16507–16515.

M. Parvazinia, S. Garcia, and M. Maroto-Valer, “CO₂ Capture by Ion Exchange Resins as Amine Functionalised Adsorbents,” Chemical Engineering Journal 331 (2018): 335–342.

M. Alvarez-Guerra, J. Albo, E. Alvarez-Guerra, and A. Irabien, “Ionic Liquids in the Electrochemical Valorisation of CO₂,” Energy & Environmental Science 8, no. 9 (2015): 2574–2599.

L. Zhao, Z. Bacsik, N. Hedin, et al., “Carbon Dioxide Capture on Amine-Rich Carbonaceous Materials Derived From Glucose,” ChemSusChem 3, no. 7 (2010): 840–845.

C. Pevida, T. C. Drage, and C. E. Snape, “Silica-Templated Melamine–Formaldehyde Resin Derived Adsorbents for CO₂ Capture,” Carbon 46, no. 11 (2008): 1464–1474.

S. G. Kazarian, B. J. Briscoe, and T. Welton, “Combining Ionic Liquids and Supercritical Fluids: In Situ ATR-IR Study of CO₂ Dissolved in Two Ionic Liquids at High Pressures,” Chemical Communications no. 20 (2000): 2047–2048, http://www.rsc.org/suppdata/cc/b0/b005514j.0.

C. Wang, H. Luo, D. Jiang, H. Li, and S. Dai, “Carbon Dioxide Capture by Superbase-Derived Protic Ionic Liquids,” Angewandte Chemie 122, no. 34 (2010): 6114–6117.

E. R. Van Selow, P. D. Cobden, R. W. van den Brink, J. R. Hufton, and A. Wright, “Performance of Sorption-Enhanced Water-Gas Shift as a Pre-Combustion CO₂ Capture Technology,” Energy Procedia 1, no. 1 (2009): 689–696.

S. Z. Zarghami, CO₂ Capture and Hydrogen Production in Sorbent Enhanced Water-Gas Shift (SEWGS) Process With Regenerable Solid Sorbent (Illinois Institute of Technology, 2015).

R. J. Allam, R. Chiang, J. R. Hufton, P. Middleton, E. Weist, and V. White, “Development of the Sorption Enhanced Water Gas Shift Process,” Carbon Dioxide Capture for Storage in Deep Geologic Formations 1 (2005): 227–256.

W. Gao, T. Zhou, Y. Gao, and Q. Wang, “Enhanced Water Gas Shift Processes for Carbon Dioxide Capture and Hydrogen Production,” Applied Energy 254 (2019): 113700.

M. Nisar, F. L. Bernard, E. Duarte, V. V. Chaban, and S. Einloft, “New Polysulfone Microcapsules Containing Metal Oxides and ([BMIM][NTf2]) Ionic Liquid for CO₂ Capture,” Journal of Environmental Chemical Engineering 9, no. 1 (2021): 104781.

J. You, M. Xiao, Z. Wang, and L. Wang, “Non-Noble Metal-Based Cocatalysts for Photocatalytic CO₂ Reduction,” Journal of CO₂ Utilization 55 (2022): 101817.

H. R. Radfarnia and M. C. Iliuta, “Metal Oxide-Stabilized Calcium Oxide CO₂ Sorbent for Multicycle Operation,” Chemical Engineering Journal 232 (2013): 280–289.

E. P. Reddy and P. G. Smirniotis, “High-Temperature Sorbents for CO₂ Made of Alkali Metals Doped on CaO Supports,” Journal of Physical Chemistry B 108, no. 23 (2004): 7794–7800.

L. Bénariac-Doumal, I. Deroche, H. Nouali, et al., “A Comparative Study of CO₂ Adsorption in a Series of Zeolites,” Physical Chemistry Chemical Physics 27, no. 20 (2025): 10621–10634.

N. Czuma, I. Casanova, P. Baran, J. Szczurowski, and K. Zarębska, “CO₂ Sorption and Regeneration Properties of Fly Ash Zeolites Synthesized With the Use of Differentiated Methods,” Scientific Reports 10, no. 1 (2020): 1825.

O. Tumurbaatar, M. Popova, V. Mitova, P. Shestakova, and N. Koseva, “Engineering of Silica Mesoporous Materials for CO₂ Adsorption,” Materials 16, no. 11 (2023): 4179.

A. N. Arias, A. L. Páez Jerez, Á. Y. Tesio, M. R. Serrano, N. A. Bonini, and M. L. Parentis, “Optimization of Surface Silanol Groups in Mesoporous SBA-15 and KIT-6 Materials: Effects on APTES Functionalization and CO₂ Adsorption,” Microporous and Mesoporous Materials 382 (2025): 113394.

P. Muchan, C. Saiwan, and M. Nithitanakul, “Investigation of Adsorption/Desorption Performance by Aminopropyltriethoxysilane Grafted Onto Different Mesoporous Silica for Post-Combustion CO₂ Capture,” Clean Energy 4, no. 2 (2020): 120–131.

T. A. Ho, Y. Wang, S. B. Rempe, et al., “Control of the Structural Charge Distribution and Hydration State Upon Intercalation of CO₂ Into Expansive Clay Interlayers,” Journal of Physical Chemistry Letters 14, no. 11 (2023): 2901–2909.

L. P. Cavalcanti, G. N. Kalantzopoulos, J. Eckert, K. D. Knudsen, and J. O. Fossum, “A Nano-Silicate Material With Exceptional Capacity for CO₂ Capture and Storage at Room Temperature,” Scientific Reports 8, no. 1 (2018): 11827.

K. W. Bø Hunvik, P. Loch, D. Wallacher, et al., “CO₂ Adsorption Enhanced by Tuning the Layer Charge in a Clay Mineral,” Langmuir 37, no. 49 (2021): 14491–14499.

X. Hu, H. Deng, C. Lu, Y. Tian, and Z. Jin, “Characterization of CO₂/CH₄ Competitive Adsorption in Various Clay Minerals in Relation to Shale Gas Recovery From Molecular Simulation,” Energy & Fuels 33, no. 9 (2019): 8202–8214.

H. Öztan and D. Uysal, “Determination of Adsorption Capacities of N₂ and CO₂ on Commercial Activated Carbon and Adsorption Isotherm Models,” E3S Web of Conferences 433 (2023): 01004.

H. Jedli, M. Almonnef, R. Rabhi, M. Mbarek, J. Abdessalem, and K. Slimi, “Activated Carbon as an Adsorbent for CO₂ Capture: Adsorption, Kinetics, and RSM Modeling,” ACS Omega 9, no. 2 (2023): 2080–2087.

S. O. Akpasi and Y. M. Isa, “Effect of Operating Variables on CO₂ Adsorption Capacity of Activated Carbon, Kaolinite, and Activated Carbon–Kaolinite Composite Adsorbent,” Water-Energy Nexus 5 (2022): 21–28.

C. Zhang, Y. Ji, C. Li, et al., “The Application of Biochar for CO₂ Capture: Influence of Biochar Preparation and CO₂ Capture Reactors,” Industrial & Engineering Chemistry Research 62, no. 42 (2023): 17168–17181.

P. D. Dissanayake, S. W. Choi, A. D. Igalavithana, et al., “Sustainable Gasification Biochar as a High Efficiency Adsorbent for CO₂ Capture: A Facile Method to Designer Biochar Fabrication,” Renewable and Sustainable Energy Reviews 124 (2020): 109785.

C. Zhang, S. Sun, S. Xu, and C. Wu, “CO₂ Capture Over Steam and KOH Activated Biochar: Effect of Relative Humidity,” Biomass and bioenergy 166 (2022): 106608.

S. Jung, Y.-K. Park, and E. E. Kwon, “Strategic Use of Biochar for CO₂ Capture and Sequestration,” Journal of CO₂ Utilization 32 (2019): 128–139.

G. Lee, I. Ahmed, and S. H. Jhung, “CO₂ Adsorption Using Functionalized Metal–Organic Frameworks Under Low Pressure: Contribution of Functional Groups, Excluding Amines, to Adsorption,” Chemical Engineering Journal 481 (2024): 148440.

N. A. A. Qasem, R. Ben-Mansour, and M. A. Habib, “An Efficient CO₂ Adsorptive Storage Using MOF-5 and MOF-177,” Applied Energy 210 (2018): 317–326.

H.-Y. Cho, D. A. Yang, J. Kim, S. Y. Jeong, and W. S. Ahn, “CO₂ Adsorption and Catalytic Application of Co-MOF-74 Synthesized by Microwave Heating,” Catalysis Today 185, no. 1 (2012): 35–40.

A. Kazemi, M. A. Pordsari, M. Tamtaji, et al., “Environmentally Friendly Synthesis and Morphology Engineering of Mixed-Metal MOF for Outstanding CO₂ Capture Efficiency,” Chemical Engineering Journal 505 (2025): 158951.

H. Chang, I. Khan, A. Yuan, et al., “Polyarylimide-Based COF/MOF Nanoparticle Hybrids for CO₂ Conversion, Hydrogen Generation, and Organic Pollutant Degradation,” ACS Applied Nano Materials 7, no. 9 (2024): 10451–10465.

S. Gu, L. Feng, G. Dai, et al., “Building Ternary Mixed Matrix Membranes With Ionic Liquid-Functional COF Fillers for Efficient CO₂ Separation,” Journal of Membrane Science 716 (2025): 123506.

J. S. De Vos, S. Ravichandran, S. Borgmans, et al., “High-Throughput Screening of Covalent Organic Frameworks for Carbon Capture Using Machine Learning,” Chemistry of Materials 36, no. 9 (2024): 4315–4330.

A. Sharma, A. Malani, N. V. Medhekar, and R. Babarao, “CO₂ Adsorption and Separation in Covalent Organic Frameworks With Interlayer Slipping,” CrystEngComm 19, no. 46 (2017): 6950–6963.

X. Wang, H. Liu, J. Zhang, and S. Chen, “Covalent Organic Frameworks (COFs): A Promising CO₂ Capture Candidate Material,” Polymer Chemistry 14, no. 12 (2023): 1293–1317.

X. Lu, H. Zhang, S. Liu, et al., “Efficient CO₂ Capture and Separation in TpPa COFs: Synergies From Functional Groups and Metal Li,” Separation and Purification Technology 342 (2024): 127036.

X. Sun, X. Shen, H. Wang, et al., “Atom-Level Interaction Design Between Amines and Support for Achieving Efficient and Stable CO₂ Capture,” Nature Communications 15, no. 1 (2024): 5068.

X. Duan, G. Song, G. Lu, et al., “Chemisorption and Regeneration of Amine-Based CO₂ Sorbents in Direct Air Capture,” Materials Today Sustainability 23 (2023): 100453.

J. Hack, N. Maeda, and D. M. Meier, “Review on CO₂ Capture Using Amine-Functionalized Materials,” ACS Omega 7, no. 44 (2022): 39520–39530.

M. A. Hussain, Y. Soujanya, and G. N. Sastry, “Evaluating the Efficacy of Amino Acids as CO₂ Capturing Agents: A First Principles Investigation,” Environmental Science & Technology 45, no. 19 (2011): 8582–8588.

G. Gao, B. Xu, X. Gao, et al., “New Insights Into the Structure-Activity Relationship for CO₂ Capture by Tertiary Amines From the Experimental and Quantum Chemical Calculation Perspectives,” Chemical Engineering Journal 473 (2023): 145277.

W. Xu, W. Wang, X. Zhang, et al., “Study on the Adsorption Rate of Anion Exchange Absorbents for Capturing Carbon Dioxide in Ambient Air,” Chemical Engineering Research and Design 201 (2024): 503–509.

K. Vinayakumar, A. Palliyarayil, N. S. Kumar, and S. Sil, “Processing of Aerogels and Their Applications Toward CO₂ Adsorption and Electrochemical Reduction: A Review,” Environmental Science and Pollution Research 29, no. 32 (2022): 47942–47968.

S. Yan, S. A. Mahyoub, Y. Cui, Q. Wang, and Z. Li, “Aerogels for Sustainable CO₂ Electroreduction to Value-Added Chemicals,” Materials Today Sustainability 28 (2024): 101038.

A. Sao and M. S. Gaikwad, “Recent Progress and Future Outlook on Hybrid Aerogel Materials for Sustainable CO₂ Capture: A Mini Review,” Materials Letters 355 (2024): 135423.

W.-H. Chen and C.-Y. Chen, “Water Gas Shift Reaction for Hydrogen Production and Carbon Dioxide Capture: A Review,” Applied Energy 258 (2020): 114078.

M. G. Darmayanti, K. L. Tuck, and S. H. Thang, “Carbon Dioxide Capture by Emerging Innovative Polymers: Status and Perspectives,” Advanced Materials 36, no. 30 (2024): 2403324.

A. Mollahosseini, M. N. Dafchahi, S. K. Salestan, et al., “Polymeric Membranes in Carbon Capture, Utilization, and Storage: Current Trends and Future Directions in Decarbonization of Industrial Flue Gas and Climate Change Mitigation,” Energy & Environmental Science 18, no. 11 (2025): 5025–5092.

S. Zulfiqar, M. I. Sarwar, and D. Mecerreyes, “Polymeric Ionic Liquids for CO₂ Capture and Separation: Potential, Progress and Challenges,” Polymer Chemistry 6, no. 36 (2015): 6435–6451.

Q. Li, R. Zhang, D. Wu, et al., “Cell-Nanoparticle Assembly Fabricated for CO₂ Capture and In Situ Carbon Conversion,” Journal of CO₂ Utilization 13 (2016): 17–23.

M. Younas, M. Sohail, L. K. Leong, M. J. Bashir, and S. Sumathi, “Feasibility of CO₂ Adsorption by Solid Adsorbents: A Review on Low-Temperature Systems,” International Journal of Environmental Science and Technology 13 (2016): 1839–1860.

A. Sharma, J. Jindal, A. Mittal, K. Kumari, S. Maken, and N. Kumar, “Carbon Materials as CO₂ Adsorbents: A Review,” Environmental Chemistry Letters 19 (2021): 875–910.

C. W. W. Ng, Y. C. Wang, J. J. Ni, and K. W. K. Tsim, “Coupled Effects of CO₂ and Biochar Amendment on the Yield and Quality of Pseudostellaria heterophylla,” Industrial Crops and Products 188 (2022): 115599.