Abstract
Carbon capture, utilization and storage (CCUS) technologies play an essential role in achieving Net Zero Emissions targets. Considering the lack of timely reviews on the recent advancements in promising CCUS technologies, it is crucial to provide a prompt review of the CCUS advances to understand the current research gaps pertained to its industrial application. To that end, this review first summarized the developmental history of CCUS technologies and the current large-scale demonstrations. Then, based on a visually bibliometric analysis, the carbon capture remains a hotspot in the CCUS development. Noting that the materials applied in the carbon capture process determines its performance. As a result, the state-of-the-art carbon capture materials and emerging capture technologies were comprehensively summarized and discussed. Gaps between state-of-art carbon capture process and its ideal counterpart are analyzed, and insights into the research needs such as material design, process optimization, environmental impact, and technical and economic assessments are provided.
Article PDF
Similar content being viewed by others
Avoid common mistakes on your manuscript.
Abbreviations
- AEM:
-
Anion exchange membranes
- AMP:
-
Amphetamine
- BPMED:
-
Bipolar membrane electrodialysis
- CCUS:
-
Carbon capture, utilisation and storage
- CCS:
-
Carbon capture and storage
- CLC:
-
Chemical looping combustion
- CMS:
-
Carbon molecular sieves
- DAC:
-
Direct air capture
- DEEA:
-
Diethylethanolamine
- DEA:
-
Ethylene glycol amine
- EOR:
-
Enhance oil recovery
- GO:
-
Graphene oxide
- IPCC:
-
The Intergovernmental Panel on Climate Change
- IL:
-
Ionic liquid
- MEA:
-
monoethanolamine
- MDEA:
-
Methyldiethanolamine
- MMEA:
-
Methylethanolamin
- MMM:
-
Mixed matrix membrane
- ML:
-
Mechanical learning
- MOF:
-
Metal-organic framework
- NOx :
-
Nitrogen oxide
- OC:
-
Oxygen carrier
- OER:
-
Oxygen evolution reaction
- OTC:
-
Oxygen transport capacity
- ORR:
-
Oxygen reduction reaction
- PA:
-
Polyamide
- PEI:
-
Polyvinylamine
- PI:
-
Polyimide
- PSE:
-
Porous Solid Electrolyte
- PCET:
-
Proton-coupled electron transfer
- PZ:
-
Piperazine
- TETA:
-
Triethylenetetramine
- TEPA:
-
Tetraethylenepentamine
- WMO:
-
The World Meteorological Organization
- WoS:
-
Web of Science
References
Abd A A, Naji S Z, Hashim A S, Othman M R (2020). Carbon dioxide removal through physical adsorption using carbonaceous and non-carbonaceous sorbents: a review. Journal of Environmental Chemical Engineering, 8(5): 104142
Adánez J, Gayán P, Celaya J, De Diego L F, García-Labiano F, Abad A (2006). Chemical looping combustion in a 10 kWth prototype using a CuO/Al2O3 oxygen carrier: effect of operating conditions on methane combustion. Industrial & Engineering Chemistry Research, 45(17): 6075–6080
Aghaie M, Rezaei N, Zendehboudi S (2018). A systematic review on CO2 capture with ionic liquids: current status and future prospects. Renewable & Sustainable Energy Reviews, 96: 502–525
Ahmed R, Liu G J, Yousaf B, Abbas Q, Ullah H, Ali M U (2020). Recent advances in carbon-based renewable adsorbent for selective carbon dioxide capture and separation: a review. Journal of Cleaner Production, 242: 118409
Al-Absi A A, Mohamedali M, Domin A, Benneker A M, Mahinpey N (2022). Development of in situ polymerized amines into mesoporous silica for direct air CO2 capture. Chemical Engineering Journal, 447: 137465
Andrus H E, Chiu J H, Thibeault P R, Miller C (2010). Alstom’s Chemical Looping Combustion Coal Power Technology Development Prototype. Morgantown: National Energy Technology Laboratory (NETL)
Antzaras A N, Papalas T, Heracleous E, Kouris C (2023). Technoeconomic and environmental assessment of CO2 capture technologies in the cement industry. Journal of Cleaner Production, 428: 139330
Azis M M, Jerndal E, Leion H, Mattisson T, Lyngfelt A (2010). On the evaluation of synthetic and natural ilmenite using syngas as fuel in chemical-looping combustion (CLC). Chemical Engineering Research & Design, 88(11): 1505–1514
Ban Y J, Li Z J, Li Y S, Peng Y, Jin H, Jiao W M, Guo A, Wang P, Yang Q Y, Zhong C L, et al. (2015). Confinement of ionic liquids in nanocages: tailoring the molecular sieving properties of ZIF-8 for membrane-based CO2 capture. Angewandte Chemie International Edition, 54(51): 15483–15487
Barbarossa V, Barzagli F, Mani F, Lai S, Stoppioni P, Vanga G (2013). Efficient CO2 capture by non-aqueous 2-amino-2-methyl-1-propanol (AMP) and low temperature solvent regeneration. RSC Advances, 3(30): 12349–12355
Bates E D, Mayton R D, Ntai I, Davis J H (2002). CO2 capture by a task-specific ionic liquid. Journal of the American Chemical Society, 124(6): 926–927
Baylin-Stern A, Berghout N (2021). Is carbon capture too expensive? Paris: IEA
Bera N, Sardar P, Samanta A N, Sarkar N (2024). Arginine-based ionic liquid in a water–DMSO binary mixture for highly efficient CO2 capture from open air. Energy & Fuels, 38(2): 1281–1287
Berguerand N, Lyngfelt A (2009). Chemical-looping combustion of petroleum coke using ilmenite in a 10 kWh unit-high-temperature operation. Energy & Fuels, 23(10): 5257–5268
Berguerand N, Lyngfelt A (2008). The use of petroleum coke as fuel in a 10 kWth chemical-looping combustor. International Journal of Greenhouse Gas Control, 2(2): 169–179
Bistline J E T, Blanford G J (2021). Impact of carbon dioxide removal technologies on deep decarbonization of the electric power sector. Nature Communications, 12(1): 3732
Blanchard L A, Hancu D, Beckman E J, Brennecke J F (1999). Green processing using ionic liquids and CO2. Nature, 399(6731): 28–29
Bose S, Sengupta D, Malliakas C D, Idrees K B, Xie H M, Wang X L, Barsoum M L, Barker N M, Dravid V P, Islamoglu T, et al. (2023). Suitability of a diamine functionalized metal-organic framework for direct air capture. Chemical Science, 14(35): 9380–9388
Bougie F, Fan X F (2018). Microwave regeneration of monoethanolamine aqueous solutions used for CO2 capture. International Journal of Greenhouse Gas Control, 79: 165–172
Boyd P G, Chidambaram A, García-Díez E, Ireland C P, Daff T D, Bounds R, Gladysiak A, Schouwink P, Moosavi S M, Maroto-Valer M M, et al. (2019). Data-driven design of metal-organic frameworks for wet flue gas CO2 capture. Nature, 576(7786): 253–256
Brethomé F M, Williams N J, Seipp C A, Kidder M K, Custelcean R (2018). Direct air capture of CO2 via aqueous-phase absorption and crystalline-phase release using concentrated solar power. Nature Energy, 3(7): 553–559
Brúder P, Grimstvedt A, Mejdell T, Svendsen H F (2011). CO2 capture into aqueous solutions of piperazine activated 2-amino-2-methyl-1-propanol. Chemical Engineering Science, 66(23): 6193–6198
Cai T, Chen X, Tang H, Zhou W, Wu Y, Zhao C (2021). Unraveling the disparity of CO2 sorption on alkali carbonates under high humidity. Journal of CO2 Utilization, 53: 101737
Cai T Y, Chen X P, Zhong J, Wu Y, Ma J L, Liu D Y, Liang C (2020). Understanding the morphology of supported Na2CO3/γ-AlOOH solid sorbent and its CO2 sorption performance. Chemical Engineering Journal, 395: 124139
Chakraborty A K, Astarita G, Bischoff K B (1986). CO2 absorption in aqueous solutions of hindered amines. Chemical Engineering Science, 41(4): 997–1003
Chatterjee S, Huang K W (2020). Unrealistic energy and materials requirement for direct air capture in deep mitigation pathways. Nature Communications, 11(1): 3287
Chen C M, Yu J X, Song G S, Che K (2023a). Desorption performance of commercial zeolites for temperature-swing CO2 capture. Journal of Environmental Chemical Engineering, 11(3): 110253
Chen H H, Zheng Y Z, Li J L, Li L Y, Wang X A (2023b). AI for nanomaterials development in clean energy and carbon capture, utilization and storage (CCUS). ACS Nano, 17(11): 9763–9792
Chen L Y, Bao J H, Kong L, Combs M, Nikolic H S, Fan Z, Liu K L (2017). Activation of ilmenite as an oxygen carrier for solid-fueled chemical looping combustion. Applied Energy, 197: 40–51
Chen X X, Xiong Z, Qin Y D, Gong B G, Tian C, Zhao Y C, Zhang J Y, Zheng C G (2016). High-temperature CO2 sorption by Ca-doped Li4SiO4 sorbents. International Journal of Hydrogen Energy, 41(30): 13077–13085
Cheng L H, Fu Y J, Liao K S, Chen J T, Hu C C, Hung W S, Lee K R, Lai J Y (2014). A high-permeance supported carbon molecular sieve membrane fabricated by plasma-enhanced chemical vapor deposition followed by carbonization for CO2 capture. Journal of Membrane Science, 460: 1–8
Cruz T T, Perrella Balestieri J A, de Toledo Silva J M, Vilanova M R N, Oliveira O J, Ávila I (2021). Life cycle assessment of carbon capture and storage/utilization: from current state to future research directions and opportunities. International Journal of Greenhouse Gas Control, 108: 103309
Custelcean R, Williams N J, Garrabrant K A, Agullo P, Brethome F M, Martin H J, Kidder M K (2019). Direct air capture of CO2 with aqueous amino acids and solid bis-iminoguanidines (BIGs). Industrial & Engineering Chemistry Research, 58(51): 23338–23346
Dasgupta S, Rajasekaran M, Roy P K, Thakkar F M, Pathak A D, Ayappa K G, Maiti P K (2022). Influence of chain length on structural properties of carbon molecular sieving membranes and their effects on CO2, CH4 and N2 adsorption: a molecular simulation study. Journal of Membrane Science, 664: 121044
Datta S, Henry M P, Lin Y J, Fracaro A T, Millard C S, Snyder S W, Stiles R L, Shah J, Yuan J W, Wesoloski L, et al. (2013). Electrochemical CO2 capture using resin-wafer electrodeionization. Industrial & Engineering Chemistry Research, 52(43): 15177–15186
de Diego L F, García-Labiano F, Gayán P, Celaya J, Palacios J M, Adánez J (2007). Operation of a 10 kWth chemical-looping combustor during 200h with a CuO-Al2O3 oxygen carrier. Fuel, 86(7–8): 1036–1045
de Lannoy C F, Eisaman M D, Jose A, Karnitz S D, Devaul R W, Hannun K, Rivest J L B (2018). Indirect ocean capture of atmospheric CO2: Part I. Prototype of a negative emissions technology. International Journal of Greenhouse Gas Control, 70: 243–253
Dimascio F, Willauer H D, Hardy D R, Lewis M K, Williams F W (2010). Extraction of Carbon Dioxide from Seawater by an Electrochemical Acidification Cell. Part 1. Initial Feasibility Studies. Washington, DC: Naval Research Laboratory
Ding J, Yu C, Lu J F, Wei X L, Wang W L, Pan G C Q (2020). Enhanced CO2 adsorption of MgO with alkali metal nitrates and carbonates. Applied Energy, 263: 114681
Dong H, Li L H, Feng Z, Wang Q N, Luan P, Li J, Li C (2023). Amine-functionalized quasi-MOF for direct air capture of CO2. ACS Materials Letters, 5(10): 2656–2664
Dubey A, Arora A (2022). Advancements in carbon capture technologies: a review. Journal of Cleaner Production, 373: 133932
Eisaman M D, Alvarado L, Larner D, Wang P, Garg B, Littau K A (2011a). CO2 separation using bipolar membrane electrodialysis. Energy & Environmental Science, 4(4): 1319–1328
Eisaman M D, Alvarado L, Larner D, Wang P, Littau K A (2011b). CO2 desorption using high-pressure bipolar membrane electrodialysis. Energy & Environmental Science, 4(10): 4031–4037
Eisaman M D, Parajuly K, Tuganov A, Eldershaw C, Chang N, Littau K A (2012). CO2 extraction from seawater using bipolar membrane electrodialysis. Energy & Environmental Science, 5(6): 7346–7352
Eisaman M D, Schwartz D E, Amic S, Larner D, Zesch J, Torres F, Littau K (2009). Energy-efficient electrochemical CO2 capture from the atmosphere. In: Technical proceedings of the clean technology conference and trade show. Houston: CRC Press–Taylor & Francis Group, 175–178
Fan L S, Li F X (2010). Chemical looping technology and its fossil energy conversion applications. Industrial & Engineering Chemistry Research, 49(21): 10200–10211
Fan W Q, Zhang T Y, Musyoka N M, Huang L, Li H L, Wang L D, Wang Q (2023). Fabrication of structurally improved KNaTiO3 pellets derived from cheap rutile sand for high-temperature CO2 capture. Fuel, 354(15): 129322
Fateminia Z, Chiniforoshan H, Ghafarinia V (2023). Novel core/Shell nylon 6,6/La-TMA MOF electrospun nanocomposite membrane and CO2 capture assessments of the membrane and pure La-TMA MOF. ACS Omega, 8(25): 22742–22751
Fatima S S, Borhan A, Ayoub M, Abd Ghani N (2021). Development and progress of functionalized silica-based sorbents for CO2 capture. Journal of Molecular Liquids, 338(15): 116913
Feng L L, Yin X C, Tan S Y, Li C, Gong X Y, Fang X, Pan Y J (2021). Ammonium bicarbonate significantly accelerates the microdroplet reactions of amines with carbon dioxide. Analytical Chemistry, 93(47): 15775–15784
Fernández J R (2023). An overview of advances in CO2 capture technologies. Energies, 16(3): 1413
Flyvbjerg B (2014). What you should know about megaprojects and why: an overview. Project Management Journal, 45(2): 6–19
Fu H M, Shen Y B, Li Z H, Zhang H, Chen H P, Gao D (2023a). CO2 capture using superhydrophobic ceramic membrane: Preparation and performance analysis. Energy, 282(1): 128873
Fu H M, Xue K L, Yang J H, Li Z H, Zhang H, Gao D, Chen H P (2023b). CO2 capture based on Al2O3 ceramic membrane with hydrophobic modification. Journal of the European Ceramic Society, 43(8): 3427–3436
Galán-Martín A, Vázquez D, Cobo S, Mac Dowell N, Caballero J A, Guillén-Gosálbez G (2021). Delaying carbon dioxide removal in the European Union puts climate targets at risk. Nature Communications, 12(1): 6490
Gao W L, Vasiliades M A, Damaskinos C M, Zhao M, Fan W Q, Wang Q, Reina T R, Efstathiou A M (2021). Molten salt-promoted MgO sorbents for CO2 capture: transient kinetic studies. Environmental Science & Technology, 55(8): 4513–4521
Gao W, Liang S, Wang R, Jiang Q, Zhang Y, Zheng Q, Xie B, Toe C Y, Zhu X, Wang J, et al. (2020). Industrial carbon dioxide capture and utilization: state of the art and future challenges. Chemical Society Reviews, 49(23): 8584–8686
Gardas R L, Coutinho J A P (2008). A group contribution method for viscosity estimation of ionic liquids. Fluid Phase Equilibria, 266(1–2): 195–201
Ghaffari S, Gutierrez M F, Seidel-Morgenstern A, Lorenz H, Schulze P (2023). Sodium hydroxide-based CO2 direct air capture for soda ash production—fundamentals for process engineering. Industrial & Engineering Chemistry Research, 62(19): 7566–7579
Global CCS Institute (2020). Global Status of CCS 2020. Washington, DC: The Global CCS Institute
Global CCS Institute (2022). Global Status of CCS 2022. Washington, DC: The global CCS Institute
Gelles T, Lawson S, Rownaghi A A, Rezaei F (2020). Recent advances in development of amine functionalized sorbents for CO2 capture. Adsorption, 26(1): 5–50
Geng Y, Guo Y, Fan B, Cheng F, Cheng H (2021). Research progress of calcium-based sorbents for CO2 capture and anti-sintering modification. Journal of Fuel Chemistry & Technology, 49(7): 998–1013
Ghaedi H, Kalhor P, Zhao M, Clough P T, Anthony E J, Fennell P S (2022). Potassium carbonate-based ternary transition temperature mixture (deep eutectic analogues) for CO2 absorption: characterizations and DFT analysis. Frontiers of Environmental Science & Engineering, 16(7): 92
Gkotsis P, Peleka E, Zouboulis A (2023). Membrane-based technologies for post-combustion CO2 capture from flue gases: Recent progress in commonly employed membrane materials. Membranes, 13(12): 898
Gregg S J, Ramsay J D (1970). Adsorption of carbon dioxide by magnesia studied by use of infrared and isotherm measurements. Journal of the Chemical Society A: Inorganic, Physical, Theoretical, 17:2784–2787
Gu H M, Shen L H, Xiao J, Zhang S W, Song T (2011). Chemical looping combustion of biomass/coal with natural Iron ore as oxygen carrier in a continuous reactor. Energy & Fuels, 25(1): 446–455
Hallett J P, Welton T (2011). Room-temperature ionic liquids: Solvents for synthesis and catalysis. 2. Chemical Reviews, 111(5): 3508–3576
Harada T, Simeon F, Hamad E Z, Hatton T A (2015). Alkali metal nitrate-promoted high-capacity MgO adsorbents for regenerable CO2 capture at moderate temperatures. Chemistry of Materials, 27(6): 1943–1949
Hernández-Palomares A, Alcántar-Vázquez B, Ramírez-Zamora R M, Coutino-Gonzalez E, Espejel-Ayala F (2023). CO2 capture using lithium-based sorbents prepared with construction and demolition wastes as raw materials. Materials Today Sustainability, 24: 100491
Holmes H E, Ghosh S, Li C Y, Kalyanaraman J, Realff M J, Weston S C, Lively R P (2023). Optimum relative humidity enhances CO2 uptake in diamine-appended M2(dobpdc). Chemical Engineering Journal, 477(1): 147119
Hospital-Benito D, Moya C, Gazzani M, Palomar J (2023). Direct air capture based on ionic liquids: From molecular design to process assessment. Chemical Engineering Journal, 468: 143630
Hu L, Wu W, Jiang L, Hu M, Zhu H, Gong L, Yang J, Lin D, Yang K (2023). Methyl-functionalized Al-based MOF ZJU-620 (Al): A potential physisorbent for carbon dioxide capture. ACS Applied Materials & Interfaces, 15(37): 43925–43932
Huang C L, Liu C J, Wu K J, Yue H R, Tang S Y, Lu H F, Liang B (2019). CO2 capture from flue gas using an electrochemically reversible hydroquinone/quinone solution. Energy & Fuels, 33(4): 3380–3389
IEA (2013). Technology roadmap: carbon capture and storage 2013 edition. Paris: International Energy Agency (IEA)
IEA (2021). Net Zero by 2050: A Roadmap for the Global Energy Sector. Paris, France: International Energy Agency (IEA)
IEA (2022). Global Energy Review: CO2 Emissions in 2021, Global emission rebound sharply to higheat ever level. Paris, France: International Energy Agency (IEA)
Iizuka A, Hashimoto K, Nagasawa H, Kumagai K, Yanagisawa Y, Yamasaki A (2012). Carbon dioxide recovery from carbonate solutions using bipolar membrane electrodialysis. Separation and Purification Technology, 101: 49–59
IPCC (2001). Climatic Change 2001: Synthesis Report. Cambridge, United Kingdom: Cambridge University Press
IPCC (2014). Climatic Change 2014: Synthesis Report. Geneva, Switzerland: Intergovernmental Panel on Climate Change (IPCC)
IPCC (2018). Global Warming of 1.5 °C. Geneva, Switzerland: Intergovernmental Panel on Climate Change (IPCC)
IPCC (2023). Climate Change 2023: Synthesis Report. Geneva, Switzerland: Intergovernmental Panel on Climate Change(IPCC)
Jahandar Lashaki M, Ziaei-Azad H, Sayari A (2022). Unprecedented improvement of the hydrothermal stability of amine-grafted MCM-41 silica for CO2 capture via aluminum incorporation. Chemical Engineering Journal, 450(4): 138393
Jiang K, Ashworth P (2021). The development of carbon capture utilization and storage (CCUS) research in China: A bibliometric perspective. Renewable & Sustainable Energy Reviews, 138: 110521
Jing G H, Qian Y H, Zhou X B, Lv B H, Zhou Z M (2018). Designing and screening of multi-amino-functionalized ionic liquid solution for CO2 capture by quantum chemical simulation. ACS Sustainable Chemistry & Engineering, 6(1): 1182–1191
Kang M K, Jeon S B, Cho J H, Kim J S, Oh K J (2017). Characterization and comparison of the CO2 absorption performance into aqueous, quasi-aqueous and non-aqueous MEA solutions. International Journal of Greenhouse Gas Control, 63: 281–288
Keller M, Oka H, Otomo J (2019). Reactivity improvement of ilmenite by calcium nitrate melt infiltration for chemical looping combustion of biomass. Carbon Resources Conversion, 2(1): 51–58
Khakpoor N, Mostafavi E, Mahinpey N, De la Hoz Siegler H (2019). Oxygen transport capacity and kinetic study of ilmenite ores for methane chemical-looping combustion. Energy, 169: 329–337
Kikkawa S, Amamoto K, Fujiki Y, Hirayama J, Kato G, Miura H, Shishido T, Yamazoe S (2022). Direct air capture of CO2 using a liquid amine-solid carbamic acid phase-separation system using diamines bearing an aminocyclohexyl group. ACS Environmental Au, 2(4): 354–362
Kim S, Jeon S G, Lee K B (2016). High-temperature CO2 sorption on hydrotalcite having a high Mg/Al molar ratio. ACS applied materials & interfaces, 8(9): 5763–5767
Kim S, Lee K B (2019). Impregnation of hydrotalcite with NaNO3 for enhanced high-temperature CO2 sorption uptake. Chemical Engineering Journal, 356: 964–972
Kim S, Yoon H J, Lee C H, Lee K B (2023). Effects of alkali-metal nitrate salts on hydrotalcite-based sorbents for enhanced cyclic CO2 capture at high temperatures. Journal of CO2 Utilization, 77: 102610
Knuutila H K, Nannestad Å (2017). Effect of the concentration of MAPA on the heat of absorption of CO2 and on the cyclic capacity in DEEA-MAPA blends. International Journal of Greenhouse Gas Control, 61: 94–103
Kolbitsch P, Bolhàr-Nordenkampf J, Pröll T, Hofbauer H (2009). Comparison of two Ni-based oxygen carriers for chemical looping combustion of natural gas in 140 kW continuous looping operation. Industrial & Engineering Chemistry Research, 48(11): 5542–5547
Kolbitsch P, Bolhàr-Nordenkampf J, Pröll T, Hofbauer H (2010). Operating experience with chemical looping combustion in a 120 kW dual circulating fluidized bed (DCFB) unit. Energy Procedia, 1(1): 1465–1472
Kortunov P V, Siskin M, Baugh L S, Calabro D C (2015). In situ nuclear magnetic resonance mechanistic studies of carbon dioxide reactions with liquid amines in aqueous systems: new insights on carbon capture reaction pathways. Energy & Fuels, 29(9): 5919–5939
Krödel M, Landuyt A, Abdala P M, Müller C R (2020). Mechanistic understanding of CaO-based sorbents for high-temperature CO2 capture: Advanced characterization and prospects. ChemSusChem, 13(23): 6259–6272
Ku H C, Miao Y H, Wang Y Z, Chen X, Zhu X C, Lu H L, Li J, Yu L J (2023). Frontier science and challenges on offshore carbon storage. Frontiers of Environmental Science & Engineering, 17(7): 80
Kumar D R, Rosu C, Sujan A R, Sakwa-Novak M A, Ping E W, Jones C W (2020). Alkyl-aryl amine-rich molecules for CO2 removal via direct air capture. ACS Sustainable Chemistry & Engineering, 8(29): 10971–10982
Kumar R, Bandyopadhyay M, Pandey M, Tsunoji N (2022). Amine-impregnated nanoarchitectonics of mesoporous silica for capturing dry and humid 400 ppm carbon dioxide: A comparative study. Microporous and Mesoporous Materials, 338: 111956
Kumar R, Ohtani S, Tsunoji N (2023). Direct air capture on amine-impregnated FAU zeolites: Exploring for high adsorption capacity and low-temperature regeneration. Microporous and Mesoporous Materials, 360: 112714
Lai Q H, Toan S, Assiri M A, Cheng H G, Russell A G, Adidharma H, Radosz M, Fan M H (2018). Catalyst-TiO(OH)2 could drastically reduce the energy consumption of CO2 capture. Nature Communications, 9(1): 2672
Lawal O, Bello A, Idem R (2005). The role of methyl diethanolamine (MDEA) in preventing the oxidative degradation of CO2 loaded and concentrated aqueous monoethanolamine (MEA)-MDEA blends during CO2 absorption from flue gases. Industrial & Engineering Chemistry Research, 44(6): 1874–1896
Le Quéré C, Peters G P, Friedlingstein P, Andrew R M, Canadell J G, Davis S J, Jackson R B, Jones M W (2021). Fossil CO2 emissions in the post-COVID-19 era. Nature Climate Change, 11(3): 197–199
Lee W H, Zhang X, Banerjee S, Jones C W, Realff M J, Lively R P (2023). Sorbent-coated carbon fibers for direct air capture using electrically driven temperature swing adsorption. Joule, 7(6): 1241–1259
Legrand L, Shu Q, Tedesco M, Dykstra J E, Hamelers H V M (2020). Role of ion exchange membranes and capacitive electrodes in membrane capacitive deionization (MCDI) for CO2 capture. Journal of Colloid and Interface Science, 564: 478–490
Lei L, Cheng Y, Chen C W, Kosari M, Jiang Z Y, He C (2022). 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: 132–145
Leion H, Mattisson T, Lyngfelt A (2009). Use of ores and industrial products As oxygen carriers in chemical-looping combustion. Energy & Fuels, 23(4): 2307–2315
Li J X, Li Y, Li C, Tu R, Xie P F, He Y, Shi Y (2022a). CO2 absorption and microwave regeneration with high-concentration TETA nonaqueous absorbents. Greenhouse Gases: Science and Technology, 12(3): 362–375
Li Q, Liu G, Li X, Chen Z A (2022b). Intergenerational evolution and presupposition of CCUS technology from a multidimensional perspective. Advanced Engineering Sciences, 54(1): 157–166
Li W, Goh K L, Chuah C Y, Bae T H (2019). Mixed-matrix carbon molecular sieve membranes using hierarchical zeolite: A simple approach towards high CO2 permeability enhancements. Journal of Membrane Science, 588: 117220
Li X L, Zhou X B, Wei J W, Fan Y M, Liao L, Wang H Q (2021). Reducing the energy penalty and corrosion of carbon dioxide capture using a novel nonaqueous monoethanolamine-based biphasic solvent. Separation and Purification Technology, 265: 118481
Li X, Jiao C, Zhang X, Li X, Song X, Zhao Y, Jiang H (2023). Dual-modulated polyamide membranes based on vapor-liquid interfacial polymerization for CO2 separation. Chemistry of Materials, 36(1): 461–470
Li X, Zhao X H, Liu Y Y, Hatton T A, Liu Y Y (2022c). Redox-tunable Lewis bases for electrochemical carbon dioxide capture. Nature Energy, 7(11): 1065–1075
Li Y, Gao J Z, Li J X, Li Y N, Bernards M T, Tao M N, He Y, Shi Y (2020). Screening and performance evaluation of triethylenetetramine nonaqueous solutions for CO2 capture with microwave regeneration. Energy & Fuels, 34(9): 11270–11281
Liao X, Wang B, Yin R Q, Ren W G, Li J, Gan H T, Lv P, Bao W R, Wang J C, Chang L P, et al. (2023). Manipulation of the crystallization of SSZ-13 transformed from coal fly ash-derived analcime. Journal of Solid State Chemistry, 323: 124024
Lin J B, Nguyen T T T, Vaidhyanathan R, Burner J, Taylor J M, Durekova H, Akhtar F, Mah R K, Ghaffari-Nik O, Marx S, et al. (2021). A scalable metal-organic framework as a durable physisorbent for carbon dioxide capture. Science, 374(6574): 1464–1469
Lin L, Meng Y, Ju T Y, Han S Y, Meng F Z, Li J L, Du Y F, Song M Z, Lan T, Jiang J G (2023). Characteristics, application and modeling of solid amine sorbents for CO2 capture: a review. Journal of Environmental Management, 325(A): 116438
Linderholm C, Abad A, Mattisson T, Lyngfelt A (2008). 160 h of chemical-looping combustion in a 10 kW reactor system with a NiO-based oxygen carrier. International Journal of Greenhouse Gas Control, 2(4): 520–530
Linderholm C, Mattisson T, Lyngfelt A (2009). Long-term integrity testing of spray-dried particles in a 10-kW chemical-looping combustor using natural gas as fuel. Fuel, 88(11): 2083–2096
Liu A H, Li J J, Ren B H, Lu X B (2019). Development of high-capacity and water-lean CO2 absorbents by a concise molecular design strategy through viscosity control. ChemSusChem, 12(23): 5164–5171
Liu F, Jing G H, Zhou X B, Lv B H, Zhou Z M (2018). Performance and mechanisms of triethylene tetramine (TETA) and 2-amino-2-methyl-1-propanol (AMP) in aqueous and nonaqueous solutions for CO2 capture. ACS Sustainable Chemistry & Engineering, 6(1): 1352–1361
Liu G, Cai B, Li Q, Zhang X, Ouyang T (2022a). China’s pathways of CO2 capture, utilization and storage under carbon neutrality vision 2060. Carbon Management, 13(1): 435–449
Liu K, Zhao B S, Wu Y, Li F, Li Q, Zhang J B (2020a). Bubbling synthesis and high-temperature CO2 adsorption performance of CaO-based sorbents from carbide slag. Fuel, 269: 117481
Liu L, Li Z S, Wang L J, Zhao Z H, Li Y, Cai N S (2020b). MgO-kaolin-supported manganese ores as oxygen carriers for chemical looping combustion. Industrial & Engineering Chemistry Research, 59(15): 7238–7246
Liu Y H, Guan Y, Lin X L, Wang B, Lyu Q (2022b). Research progress and perspectives of solid fuels chemical looping reaction with Fe-based oxygen carriers. Energy & Fuels, 36(23): 13956–13984
Liu Y Y, Ye H Z, Diederichsen K M, Van Voorhis T, Hatton T A (2020c). Electrochemically mediated carbon dioxide separation with quinone chemistry in salt-concentrated aqueous media. Nature Communications, 11(1): 2278
Liu Z X, Lu Y L, Wang C F, Zhang Y, Jin X D, Wu J W, Wang Y H, Zeng J B, Yan Z F, Sun H M, et al. (2023). MOF-derived nano CaO for highly efficient CO2 fast adsorption. Fuel, 340: 127476
Lu P, Yan X, Ye L, Chen D, Chen D, Huang J, Cen C (2024). Performance and mechanism of CO2 absorption during the simultaneous removal of SO2 and NOx by wet scrubbing process. Journal of Environmental Sciences (China), 135: 534–545
Lv B H, Yang K X, Zhou X B, Zhou Z M, Jing G H (2020). 2-Amino-2-methyl-1-propanol based non-aqueous absorbent for energy-efficient and non-corrosive carbon dioxide capture. Applied Energy, 264: 114703
Lyngfelt A (2011). Oxygen carriers for chemical looping combustion-4000 h of operational experience. Oil & Gas Science and Technology-Revue D IFP Energies Nouvelles, 66(2): 161–172
McQueen N, Kelemen P, Dipple G, Renforth P, Wilcox J (2020). Ambient weathering of magnesium oxide for CO2 removal from air. Nature Communications, 11(1): 3299
Meckling J, Biber E (2021). A policy roadmap for negative emissions using direct air capture. Nature Communications, 12(1): 2051
Milad B, Moghanloo R G, Hayman N W (2024). Assessing CO2 geological storage in arbuckle group in northeast oklahoma. Fuel, 356: 129323
Morita M, Horiuchi Y, Matsuoka M, Ogawa M (2022). Preparation of titanium-containing layered alkali silicates. Crystal Growth & Design, 22(3): 1638–1644
Muldoon M J, Aki S, Anderson J L, Dixon J K, Brennecke J F (2007). Improving carbon dioxide solubility in ionic liquids. Journal of Physical Chemistry B, 111(30): 9001–9009
Müller L J, Kätelhön A, Bringezu S, Mccoy S, Suh S, Edwards R, Sick V, Kaiser S, Cuéllar-Franca R, El Khamlichi A, et al. (2020). The carbon footprint of the carbon feedstock CO2. Energy & Environmental Science, 13(9): 2979–2992
NEA (2023). China Carbon Capture, Utilization and Storage (CCUS) Annual Report (2023). Beijing: National Energy Administration (in Chinese)
Nik O G, Chen X Y, Kaliaguine S (2012). Functionalized metal organic framework-polyimide mixed matrix membranes for CO2/CH4 separation. Journal of Membrane Science, 413–414: 48–61
Noorani N, Mehrdad A (2020). CO2 solubility in some amino acid-based ionic liquids: Measurement, correlation and DFT studies. Fluid Phase Equilibria, 517: 112591
Noorani N, Mehrdad A (2022). Cholinium-amino acid ionic liquids as biocompatible agents for carbon dioxide absorption. Journal of Molecular Liquids, 357: 119078
Noorani N, Mehrdad A, Ahadzadeh I (2021). CO2 absorption in amino acid-based ionic liquids: Experimental and theoretical studies. Fluid Phase Equilibria, 547: 113185
Orujov A, Coddington K, Aryana S A (2023). A review of CCUS in the context of foams, regulatory frameworks and monitoring. Energies, 16(7): 3284
Park H B, Kamcev J, Robeson L M, Elimelech M, Freeman B D (2017). Maximizing the right stuff: the trade-off between membrane permeability and selectivity. Science, 356(6343): eaab0530
Pröll T, Kolbitsch P, Bolhàr-Nordenkampf J, Hofbauer H (2009a). A novel dual circulating fluidized bed system for chemical looping processes. AIChE Journal. American Institute of Chemical Engineers, 55(12): 3255–3266
Pröll T, Mayer K, Bolhàr-Nordenkampf J, Kolbitsch P, Mattisson T, Lyngfelt A, Hofbauer H (2009b). Natural minerals as oxygen carriers for chemical looping combustion in a dual circulating fluidized bed system. Energy Procedia, 1(1): 27–34
Qi G, Wang S (2017). Thermodynamic modeling of NH3-CO2-SO2-K2SO4-H2O system for combined CO2 and SO2 capture using aqueous NH3. Applied Energy, 191(1): 549–558
Qiu L, Peng L, Moitra D, Liu H, Fu Y, Dong Z, Hu W, Lei M, Jiang D E, Lin H, et al. (2023). Harnessing the hybridization of a metal-organic framework and superbase-derived ionic liquid for highperformance direct air capture of CO2. Small, 19(41): 2302708
Qiu Y, Lamers P, Daioglou V, McQueen N, de Boer H S, Harmsen M, Wilcox J, Bardow A, Suh S (2022). Environmental trade-offs of direct air capture technologies in climate change mitigation toward 2100. Nature Communications, 13(1): 3635
Rajendran A, Subraveti S G, Pai K N, Prasad V, Li Z (2023). How can (or why should) process engineering aid the screening and discovery of solid sorbents for CO2 capture? Accounts of Chemical Research, 56(17): 2354–2365
Rau G H (2008). Electrochemical splitting of calcium carbonate to increase solution alkalinity: implications for mitigation of carbon dioxide and ocean acidity. Environmental Science & Technology, 42(23): 8935–8940
Realmonte G, Drouet L, Gambhir A, Glynn J, Hawkes A, Köberle A C, Tavoni M (2019). An inter-model assessment of the role of direct air capture in deep mitigation pathways. Nature Communications, 10(1): 3277
Rochelle G T (2024). Air pollution impacts of amine scrubbing for CO2 capture. Carbon Capture Science & Technology, 11: 100192
Sanyal O, Hays S S, León N E, Guta Y A, Itta A K, Lively R P, Koros W J (2020). A self-consistent model for sorption and transport in polyimide-derived carbon molecular sieve gas separation membranes. Angewandte Chemie International Edition, 59(46): 20343–20347
Schmitz M, Linderholm C, Hallberg P, Sundqvist S, Lyngfelt A (2016). Chemical-looping combustion of solid fuels using manganese ores as oxygen carriers. Energy & Fuels, 30(2): 1204–1216
Sedighi M, Talaie M R, Sabzyan H, Aghamiri S F (2023). A computational investigation on the roles of binding affinity and pore size on CO2/N2 overall adsorption process performance of MOFs through modifying MIL-101 structure. Sustainable Materials and Technologies, 38: e00701
Sekizkardes A K, Kusuma V A, Culp J T, Muldoon P, Hoffman J, Steckel J A, Hopkinson D (2023). Single polymer sorbent fibers for high performance and rapid direct air capture. Journal of Materials Chemistry. A, Materials for Energy and Sustainability, 11(22): 11670–11674
Shan K Y, Lin Y L, Chu P S, Yu X P, Song F F (2023). Seasonal advance of intense tropical cyclones in a warming climate. Nature, 623(7985): 83–89
Shen L H, Wu J H, Gao Z P, Xiao J (2009a). Reactivity deterioration of NiO/Al2O3 oxygen carrier for chemical looping combustion of coal in a 10 kWth reactor. Combustion and Flame, 156(7): 1377–1385
Shen L H, Wu J H, Xiao J, Song Q L, Xiao R (2009b). Chemical-looping combustion of biomass in a 10 kWth reactor with iron oxide As an oxygen carrier. Energy & Fuels, 23(5): 2498–2505
Shen Q, Song X H, Mao F, Sun N N, Wen X, Wei W (2020). Carbon reduction potential and cost evaluation of different mitigation approaches in China’s coal to olefin Industry. Journal of Environmental Sciences, 90: 352–363
Shen Y, Liu F, Wang X Y, Shao P J, He Z, Zhang S H, Chen L, Li S J, Li W, Wang L D, et al. (2022). A pore matching amine-functionalized strategy for efficient CO2 physisorption with low energy penalty. Chemical Engineering Journal, 432: 134403
Shi J S, Cui H M, Xu J G, Yan N F, You S Y (2022). Synthesis of N-doped hierarchically ordered micro-mesoporous carbons for CO2 adsorption. Journal of CO2 Utilization, 62: 102081
Siegelman R L, Kim E J, Long J R (2021). Porous materials for carbon dioxide separations. Nature Materials, 20(8): 1060–1072
Song C F, Fan Z C, Li R, Liu Q L, Sun Y W, Kitamura Y (2018). Intensification of CO2 separation performance via cryogenic and membrane hybrid process—comparison of polyimide and polysulfone hollow fiber membrane. Chemical Engineering and Processing - Process Intensification, 133: 83–89
Sridhar D, Tong A, Kim H, Zeng L, Li F, Fan L S (2012). Syngas chemical looping process: design and construction of a 25 kWh subpilot unit. Energy & Fuels, 26(4): 2292–2302
Stefanelli E, Vitolo S, Puccini M (2022). Single-step fabrication of templated Li4SiO4-based pellets for CO2 capture at high temperature. Journal of Environmental Chemical Engineering, 10(5): 108389
Storrs K, Lyhne I, Drustrup R (2023). A comprehensive framework for feasibility of CCUS deployment: a meta-review of literature on factors impacting CCUS deployment. International Journal of Greenhouse Gas Control, 125: 103878
Stucki S, Schuler A, Constantinescu M (1995). Coupled CO2 recovery from the atmosphere and water electrolysis: feasibility of a new process for hydrogen storage. International Journal of Hydrogen Energy, 20(8): 653–663
Sun Z Y, Shao B, Zhang Y, Gao Z H, Wang M H, Liu H L, Hu J (2023). Integrated CO2 capture and methanation from the intermediate-temperature flue gas on dual functional hybrids of AMS/CaMgO. NixCoy. Separation and Purification Technology, 307:122680
Sundqvist S, Arjmand M, Mattisson T, Rydén M, Lyngfelt A (2015). Screening of different manganese ores for chemical-looping combustion (CLC) and chemical-looping with oxygen uncoupling (CLOU). International Journal of Greenhouse Gas Control, 43: 179–188
Szcześniak B, Choma J (2020). Graphene-containing microporous composites for selective CO2 adsorption. Microporous and Mesoporous Materials, 292: 109761
Tao M N, Gao J Z, Zhang W, Li Y, He Y, Shi Y (2018). A novel phase-changing nonaqueous solution for CO2 capture with high capacity, thermostability, and regeneration efficiency. Industrial & Engineering Chemistry Research, 57(28): 9305–9312
Tian H J, Siriwardane R, Simonyi T, Poston J (2013). Natural ores as oxygen carriers in chemical looping combustion. Energy & Fuels, 27(8): 4108–4118
Tian W, Ma K, Ji J Y, Tang S Y, Zhong S, Liu C J, Yue H R, Liang B (2021). Nonaqueous MEA/PEG200 absorbent with high efficiency and low energy consumption for CO2 capture. Industrial & Engineering Chemistry Research, 60(10): 3871–3880
Tian X, Zhao H B, Wang K, Ma J C, Zheng C G (2015). Performance of cement decorated copper ore as oxygen carrier in chemical-looping with oxygen uncoupling. International Journal of Greenhouse Gas Control, 41: 210–218
Tong D, Zhang Q, Zheng Y X, Caldeira K, Shearer C, Hong C P, Qin Y, Davis S J (2019). Committed emissions from existing energy infrastructure jeopardize 1.5 °C climate target. Nature, 572(7769): 373
Wang H, Yang Z Y, Zhou Y Q, Cui H J, Cheng Z M, Zhou Z M (2023a). Direct air capture of CO2 with metal nitrate-doped, tetraethylenepentamine-functionalized SBA-15 sorbents. Industrial & Engineering Chemistry Research, 62(41): 16579–16588
Wang L D, Zhang Y F, Wang R J, Li Q W, Zhang S H, Li M, Liu J, Chen B (2018). Advanced monoethanolamine absorption using sulfolane as a phase splitter for CO2 capture. Environmental Science & Technology, 52(24): 14556–14563
Wang L, Lin C, Boldog I, Yang J, Janiak C, Li J (2023b). Inverse adsorption separation of N2O/CO2 in AgZK-5 zeolite. Angewandte Chemie International Edition, 63(4): e202317435
Wang R (2024). Status and perspectives on CCUS clusters and hubs. Unconventional Resources, 4: 100065
Wang R J, Jiang L, Li Q W, Gao G, Zhang S H, Wang L D (2020). Energy-saving CO2 capture using sulfolane-regulated biphasic solvent. Energy, 211: 118667
Wang Y H, Wang K X, Zhang X R, Li J P (2023c). Co@NC@ZIF-8-hybridized carbon molecular sieve membranes for highly efficient gas separation. Journal of Membrane Science, 682: 121781
Wang Y Y, Tang X D, XinWei, Gao S J, Jiang L, Yi Y (2024). Study of CO2 adsorption on carbon aerogel fibers prepared by electrospinning. Journal of Environmental Management, 349: 119432
Waqas Anjum M, de Clippel F, Didden J, Laeeq Khan A, Couck S, Baron G V, Denayer J F M, Sels B F, Vankelecom I F J (2015). Polyimide mixed matrix membranes for CO2 separations using carbon-silica nanocomposite fillers. Journal of Membrane Science, 495: 121–129
Wen Y Y, Li Z S, Xu L, Cai N S (2012). Experimental study of natural Cu ore particles as oxygen carriers in chemical looping with oxygen uncoupling (CLOU). Energy & Fuels, 26(6): 3919–3927
Wijesiri R P, Knowles G P, Yeasmin H, Hoadley A F A, Chaffee A L (2019). CO2 capture from air using pelletized polyethylenimine impregnated MCF silica. Industrial & Engineering Chemistry Research, 58(8): 3293–3303
Willauer H D, Dimascio F, Hardy D R (2017). Extraction of carbon dioxide and hydrogen from seawater by an electrolytic cation exchange module (E-CEM) part 5: E-CEM effluent discharge composition as a function of electrode water composition. Washington DC: Naval research laboratory
Willauer H D, Dimascio F, Hardy D R, Lewis M K, Williams F W (2011). Development of an electrochemical acidification cell for the recovery of CO2 and H2 from seawater. Industrial & Engineering Chemistry Research, 50(17): 9876–9882
Willauer H D, Dimascio F, Hardy D R, Williams F W (2014). Feasibility of CO2 extraction from seawater and simultaneous hydrogen gas generation using a novel and robust electrolytic cation exchange module based on continuous electrodeionization technology. Industrial & Engineering Chemistry Research, 53(31): 12192–12200
WMO (2023). Provisional state of the global climate 2023. Geneva, Switzerland: World Meteorological Organization
Wu B Z, Liu F Q, Luo S W, Zhang L Q, Zou F X (2021). Carbonaceous materials-supported polyethylenimine with high thermal conductivity: A promising adsorbent for CO2 capture. Composites Science and Technology, 208: 108781
Wu K, Peng S, Ye G, Chen Z, Wu D (2023). Self-Assembled core-shell structure MgO@ TiO2 as a K2CO3 support with superior performance for direct air capture CO2. ACS Applied Materials & Interfaces, 15(51): 59561–59572
Xia C, Xia Y, Zhu P, Fan L, Wang H T (2019). Direct electrosynthesis of pure aqueous H2O2 solutions up to 20% by weight using a solid electrolyte. Science, 366(6462): 226–231
Xiao M, Liu H L, Gao H X, Olson W, Liang Z W (2019). CO2 capture with hybrid absorbents of low viscosity imidazolium-based ionic liquids and amine. Applied Energy, 235: 311–319
Xiao R, Song Q L, Zhang S A, Zheng W G, Yang Y C (2010). Pressurized chemical-looping combustion of chinese bituminous coal: cyclic performance and characterization of iron ore-based oxygen carrier. Energy & Fuels, 24(2): 1449–1463
Xie H, Jiang W, Liu T, Wu Y, Wang Y, Chen B, Niu D, Liang B (2020). Low-energy electrochemical carbon dioxide capture based on a biological redox proton carrier. Cell Reports. Physical Science, 1(5): 100046
Xie Y, Zhong H, Weng Z X, Guo X B, Kim S E, Wu S W (2023). PM2.5 concentration declining saves health expenditure in China. Frontiers of Environmental Science & Engineering, 17(7): 90
Xie W, Jiao Y, Cai Z L, Liu H Y, Gong L L, Lai W, Shan L L, Luo S J (2022). Highly selective benzimidazole-based polyimide/ionic polyimide membranes for pure- and mixed-gas CO2/CH4 separation. Separation and Purification Technology, 282(B): 120091
Xu L, Sun H M, Li Z S, Cai N S (2016). Experimental study of copper modified manganese ores as oxygen carriers in a dual fluidized bed reactor. Applied Energy, 162: 940–947
Yan H Y, Zhang G J, Xu Y, Zhang Q Q, Liu J, Li G Q, Zhao Y Q, Wang Y, Zhang Y F (2022). High CO2 adsorption on amine-functionalized improved macro-/mesoporous multimodal pore silica. Fuel, 315: 123195
Yan Y L, Borhani T N, Subraveti S G, Pai K N, Prasad V, Rajendran A, Nkulikiyinka P, Asibor J O, Zhang Z E, Shao D, et al. (2021). Harnessing the power of machine learning for carbon capture, utilisation, and storage (CCUS): a state-of-the-art review. Energy & Environmental Science, 14(12): 6122–6157
Yang H, Huang X J, Hu J L, Thompson J R, Flower R J (2022). Achievements, challenges and global implications of China’s carbon neutral pledge. Frontiers of Environmental Science & Engineering, 16(8): 111
Yang Z Y, Soriano A N, Caparanga A R, Li M H (2010). Equilibrium solubility of carbon dioxide in (2-amino-2-methyl-1-propanol+piperazine+water). Journal of Chemical Thermodynamics, 42(5): 659–665
Yang Z, Chen B, Chen H, Li H (2023). A critical review on machine-learning-assisted screening and design of effective sorbents for carbon dioxide (CO2) capture. Frontiers in Energy Research, 10: 1043064
Yao B, Wang Y Q, Fang Z, Hu Y, Ye Z Z, Peng X S (2023a). Electrodepositing MOFs into laminated graphene oxide membrane for CO2 capture. Microporous and Mesoporous Materials, 361: 112758
Yao J, Han H, Yang Y, Song Y, Li G (2023b). A review of recent progress of carbon capture, utilization, and storage (CCUS) in China. Applied Sciences, 13(2): 1169
Youn M H, Park K T, Lee Y H, Kang S P, Lee S M, Kim S S, Kim Y E, Ko Y N, Jeong S K, Lee W (2019). Carbon dioxide sequestration process for the cement industry. Journal of CO2 Utilization, 34: 325–334
Younas M, Rezakazemi M, Daud M, Wazir M B, Ahmad S, Ullah N, Inamuddin, Ramakrishna S (2020). Recent progress and remaining challenges in post-combustion CO2 capture using metal-organic frameworks (MOFs). Progress in Energy and Combustion Science, 80:100849
Yu Y, Mao J F, Wullschleger S D, Chen A P, Shi X Y, Wang Y P, Hoffman F M, Zhang Y L, Pierce E (2022). Machine learning-based observation-constrained projections reveal elevated global socioeconomic risks from wildfire. Nature Communications, 13(1): 1250
Zhan G X, Yuan B L, Duan Y M, Bai Y F, Chen J J, Chen Z, Li J H (2023). Simulation and optimization of carbon dioxide capture using Water-Lean solvent from industrial flue gas. Chemical Engineering Journal, 474: 145773
Zhan X H, Lv B H, Yang K X, Jing G H, Zhou Z M (2020). Dual-functionalized ionic liquid biphasic solvent for carbon dioxide capture: High-efficiency and energy saving. Environmental Science & Technology, 54(10): 6281–6288
Zhang C, Zhang J F, Yu Y S, Zhang Z X, Wang G G X (2021a). Adsorption mechanism of CO2 on the single atom doped or promoted Li4SiO4(010) surface from first principles. Computational & Theoretical Chemistry, 1205: 113424
Zhang C, Zhang X Q, Su T Y, Zhang Y H, Wang L W, Zhu X C (2023a). Modification schemes of efficient sorbents for trace CO2 capture. Renewable & Sustainable Energy Reviews, 184: 113473
Zhang K X, Wu J S, Yoo H, Lee Y J (2021b). Machine learning-based approach for tailor-made design of ionic liquids: application to CO2 capture. Separation and Purification Technology, 275: 119117
Zhang R, Liu R X, Barzagli F, Sanku M G, Li C, Xiao M (2023b). CO2 absorption in blended amine solvent: speciation, equilibrium solubility and excessive property. Chemical Engineering Journal, 466: 143279
Zhang R, Zhang X W, Yang Q, Yu H, Liang Z W, Luo X (2017). Analysis of the reduction of energy cost by using MEA-MDEA-PZ solvent for post-combustion carbon dioxide capture (PCC). Applied Energy, 205: 1002–1011
Zhang S H, Shen Y, Shao P J, Chen J M, Wang L D (2018). Kinetics, thermodynamics, and mechanism of a novel biphasic solvent for CO2 capture from flue gas. Environmental Science & Technology, 52(6): 3660–3668
Zhang S Q, Chen C, Ahn W S (2019). Recent progress on CO2 capture using amine-functionalized silica. Current Opinion in Green and Sustainable Chemistry, 16: 26–32
Zhang Y Y, Sun M Y, Li L, Xu R S, Pan Y Q, Wang T H (2022). Carbon molecular sieve/ZSM-5 mixed matrix membranes with enhanced gas separation performance and the performance recovery of the aging membranes. Journal of Membrane Science, 660: 120869
Zhao H B, Wang K, Fang Y F, Ma J C, Mei D F, Zheng C G (2014). Characterization of natural copper ore as oxygen carrier in chemical-looping with oxygen uncoupling of anthracite. International Journal of Greenhouse Gas Control, 22: 154–164
Zhao Y Y, Wang J H, Ji Z Y, Liu J, Guo X F, Yuan J S (2020). A novel technology of carbon dioxide adsorption and mineralization via seawater decalcification by bipolar membrane electrodialysis system with a crystallizer. Chemical Engineering Journal, 381: 122542
Zhao Z Q, Zhang H, Jiao C, Wang Q F, Lin X L (2021). Review on global CCUS technology and application. Modern Chemical Industry, 41(4): 5–10
Zheng B, Ciais P, Chevallier F, Yang H, Canadell J G, Chen Y, Van Der Velde I R, Aben I, Chuvieco E, Davis S J, et al. (2023). Record-high CO2 emissions from boreal fires in 2021. Science, 379(6635): 912–917
Zheng Q W, Huang L, Zhong Z Y, Louis B, Wang Q (2020). Development of KNaTiO3 as a novel high-temperature CO2 capturing material with fast sorption rate and high reversible sorption capacity. Chemical Engineering Journal, 380: 122444
Zhou X B, Li X L, Wei J W, Fan Y M, Liao L, Wang H Q (2020). Novel nonaqueous liquid-liquid biphasic solvent for energy-efficient carbon dioxide capture with low corrosivity. Environmental Science & Technology, 54(24): 16138–16146
Zhou X B, Liu C, Zhang J, Fan Y M, Zhu Y N, Zhang L H, Tang S, Mo S P, Zhu H X, Zhu Z Q (2023). Novel 2-amino-2-methyl-1-propanol-based biphasic solvent for energy-efficient carbon dioxide capture using tetraethylenepentamine as a phase change regulator. Energy, 270: 126930
Zhou Y, Zhang J L, Wang L, Cui X L, Liu X L, Wong S S, An H, Yan N, Xie J Y, Yu C, et al. (2021). Self-assembled iron-containing mordenite monolith for carbon dioxide sieving. Science, 373(6552): 315
Zhu P, Wu Z Y, Elgazzar A, Dong C X, Wi T U, Chen F Y, Xia Y, Feng Y G, Shakouri M, Kim J Y, et al. (2023). Continuous carbon capture in an electrochemical solid-electrolyte reactor. Nature, 618(7967): 959–966
Acknowledgements
This research was supported by the Zhejiang Provincial Natural Science Foundation of China (No. LDT23E0601), the “Pioneer” and “Leading Goose” R&D Program of Zhejiang (China) (No. 2022C03146), the National Natural Science Foundation of China (Nos. U23A20677 and 20026610) and the National Funded Postdoctoral Researcher Program of China (No. GZC20232363).
Author information
Authors and Affiliations
Corresponding author
Ethics declarations
Conflict of Interest The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.
Additional information
Highlights
• Recent advances in promising CCUS technologies are assessed.
• Research status and trends in CCUS are visually analyzed.
• Carbon capture remains a hotspot of CCUS research.
• State-of-the-art capture technologies is summarized.
• Perspective research of carbon capture is proposed
Author Biography
Xiang Gao is a Member of the Chinese Academy of Engineering and holds Fellowships from the Institution of Engineering and Technology, the Chinese Society for Environmental Sciences, and the Chinese Society for Electrical Engineering. He currently serves as President of Zhejiang University of Technology, Director of the Institute of Carbon Neutrality at Zhejiang University, and Director of Baima Lake Laboratory. Dedicated to the research in the field of energy and the environment, his work spans fundamental theoretical research, key technology development, and engineering applications. His achievements have been recognized with numerous awards, including the First Prize and the Second Prize of the State Technological Invention Awards, the Second Prize of the State Scientific and Technological Progress Award, two Second Prizes of the National Teaching Achievement Award, the Scientific and Technological Innovation Award of Ho Leung Ho Lee Foundation, the National Award for Excellence in Innovation, and the National May Day Labor Medal, etc.
Rights and permissions
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article’s Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article’s Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/.
About this article
Cite this article
Zhang, S., Shen, Y., Zheng, C. et al. Recent advances, challenges, and perspectives on carbon capture. Front. Environ. Sci. Eng. 18, 75 (2024). https://doi.org/10.1007/s11783-024-1835-0
Received:
Revised:
Accepted:
Published:
DOI: https://doi.org/10.1007/s11783-024-1835-0