Material design and prospect of dual-functional materials for integrated carbon dioxide capture and conversion

Lu, Bowen; Fan, Yu; Zhi, Xinyu; Han, Ziqiang; Wu, Fan; Li, Xiaoshan; Luo, Cong; Zhang, Liqi

doi:10.1016/j.ccst.2024.100207

Cited by 11 publications

(1 citation statement)

References 93 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Most Ni-supported alumina catalysts for dry methane reforming have been created by coprecipitation or wet impregnation. The catalysts without additives were mostly unstable because the Ni nanoparticles did not interact with the support enough to minimize sintering at high temperatures, forming larger particles on the outer surface of the material and resulting in less active carbon types that hindered the reaction. , Similarly, coke deposition significantly reduces the stability of catalysts used in DRM. Typically, if the active site Ni is in its metallic form or zero oxidation state, then it becomes further deactivated by forming graphitic carbon nanorods via the top growth method .…”

Section: Future Prospects: Challenges and Opportunities In Icc-drmmentioning

confidence: 99%

Integrated CO₂ Capture and Dry Reforming of CH₄ to Syngas: A Review

Bhaskaran,

Singh,

Reddy

et al. 2024

Langmuir

View full text Add to dashboard Cite

Integrating carbon capture with dry reforming of methane offers a promising approach to addressing greenhouse gas emissions while producing valuable syngas. This review examines the complexities and progress made in this integrated process, wherein catalysts play a critical role in adsorbing carbon dioxide and facilitating the conversion of methane to syngas. The chemical process entails the concurrent capture of CO 2 emissions and their usage in dry reforming, a reaction in which CH 4 interacts with CO 2 to generate syngas, an essential precursor for various industrial applications. The dual-functional materials can adsorb carbon dioxide and actively reform to an end-use application. The much-studied Ca-based sorbents exhibit a theoretical carbon capture capacity of 17.8 mmol g −1 . However, during practical exploration of these materials as a dual-functional catalyst for integrated carbon capture and the dry reforming of methane, the uptake reduces to ∼13 mmol g −1 carbon capacity with 96.5 and 96% conversions of CO 2 and CH 4 , respectively. Therefore, a thorough analysis of the complex relationship between CO 2 capture and CH 4 reforming catalysis is attempted herein based on various reported materials. Design concepts, structural optimization, and performance evaluation analysis of the dual-functional materials reveal their importance in carbon capture and reformation technology. Additionally, this review covers the field difficulties, future perspectives, and attractive commercial implementation predictions. This scrutiny illustrates the significance of dual-functional materials for sustainable energy production and environmental protection.

show abstract

Section: Future Prospects: Challenges and Opportunities In Icc-drmmentioning

confidence: 99%

Integrated CO₂ Capture and Dry Reforming of CH₄ to Syngas: A Review

Bhaskaran,

Singh,

Reddy

et al. 2024

Langmuir

View full text Add to dashboard Cite

show abstract

Artificial intelligence‐driven sustainability: Enhancing carbon capture for sustainable development goals– A review

Manikandan,

Kaviya,

Shreeharan

et al. 2024

Sustainable Development

View full text Add to dashboard Cite

Artificial intelligence (AI) and environmental points are equally important components within the response to local weather change. Therefore, based on the efforts of reducing carbon emissions more efficiently and effectively, this study tries to focus on AI integration with carbon capture technology. The urgency of tackling climate change means we need more advanced carbon capture, and this is an area where AI can make a huge impact in how these technologies are operated and managed. It will minimize manufacturing emissions and improve both resource efficiency as well as our planet's environmental footprint by turning waste into something of value again. Artificial intelligence could be leveraged to analyze huge data sets from carbon capture plants, searching for optimal system settings and more efficient ways of identifying patterns in the available information at a larger scale than currently possible. In addition, AI incorporated sensors and monitoring mechanisms in the supply chain can identify any operational failure at reception itself allowing for timely action to protect those areas. Artificial intelligence also helps generative design for carbon capture materials, which allows researchers to explore new types of carbon‐absorbing material, including metal–organic frameworks and polymeric materials that are important in industrial CO2, such as moisture. In addition, it increases the accuracy of reservoir simulations and controls CO2 injection systems for storage or enhanced oil recovery. Through applying AI algorithms on reservoir geology, production performance and real‐time data this study would like to facilitate the optimization of injection processes as well as minimize CO2 emissions while assuring a maximum efficiency. Artificial intelligence integrates with renewable‐based carbon capture efforts that can be employed by AI‐driven smart grid systems to improve carbon capture methods.

show abstract

The advancement of porous bimetal nanostructures for electrochemical CO2 utilization to valuable products: Experimental and theoretical insights

Ipadeola,

Balogun,

Abdullah

2024

Carbon Capture Science & Technology

View full text Add to dashboard Cite

Material design and prospect of dual-functional materials for integrated carbon dioxide capture and conversion

Cited by 11 publications

References 93 publications

Integrated CO₂ Capture and Dry Reforming of CH₄ to Syngas: A Review

Integrated CO₂ Capture and Dry Reforming of CH₄ to Syngas: A Review

Artificial intelligence‐driven sustainability: Enhancing carbon capture for sustainable development goals– A review

The advancement of porous bimetal nanostructures for electrochemical CO2 utilization to valuable products: Experimental and theoretical insights

Contact Info

Product

Resources

About

Material design and prospect of dual-functional materials for integrated carbon dioxide capture and conversion

Cited by 11 publications

References 93 publications

Integrated CO2 Capture and Dry Reforming of CH4 to Syngas: A Review

Integrated CO2 Capture and Dry Reforming of CH4 to Syngas: A Review

Artificial intelligence‐driven sustainability: Enhancing carbon capture for sustainable development goals– A review

The advancement of porous bimetal nanostructures for electrochemical CO2 utilization to valuable products: Experimental and theoretical insights

Contact Info

Product

Resources

About

Integrated CO₂ Capture and Dry Reforming of CH₄ to Syngas: A Review

Integrated CO₂ Capture and Dry Reforming of CH₄ to Syngas: A Review