期刊
CARBON
卷 197, 期 -, 页码 301-310出版社
PERGAMON-ELSEVIER SCIENCE LTD
DOI: 10.1016/j.carbon.2022.06.024
关键词
Nanocarbon materials; Low-temperature plasma nanotechnology; Vertical graphenes; Greenhouse gas conversion; Supercapacitors
资金
- National Natural Science Foundation of China [52076188]
- Royal Society Newton Advanced Fellowship [52061130218]
- State Key Laboratory of Clean Energy Utilization Open Fund [ZJU-CEU2019002]
- Austraian Research Council (ARC)
- QUT Centre for Materials Scinece
This study demonstrates a feasible and scalable process to convert CO2 and CH4 greenhouse gases into high-value products using cleaner, sustainable, and renewable-energy-electrified processes. The results show that this approach is environmentally friendly, can be widely adopted at an industry-relevant scale, and contributes to achieving global targets of zero carbon emissions.
Conversion of CO2 and CH4 greenhouse gases (GHGs) into high-value products using cleaner, sustainable, and renewable-energy-electrified processes is a critical step towards the ultimate decarbonization of our economy and society. Here, we demonstrate an industry-relevant, scalable, plasma-electrified roll-to-roll process to produce vertical graphenes (VGs) for energy storage and syngas from the GHG feedstock with a one-round conversion efficiency of similar to 80%. The growth temperature of VGs from an appropriate mixture of CO2 and CH4 is reduced from the expected 700 degrees C to only 300 degrees C due to the effective dissociation of CH4 caused by reactive plasma-generated oxygen-containing species. A new pilot-scale process is developed to fabricate highly-branched VGs from CH4 + CO2 gas mixture on a large area (10 x 100 cm(2)) nickel foil under plasmas generated by a roll-toroll linear microwave antenna. The analysis of gaseous products and carbon mass flow reveals that most of the GHG mix is effectively converted into the high-value syngas (CO and H-2). Our results demonstrate the integrated re-carbon (re-use of GHGs), up-carbon (conversion of GHG into high-value carbon-based products, HVCBPs), and de-carbon (using the electrification to reduce process-related carbon emissions while producing HVCBPs for clean energy storage) approach that is environmentally benign, scalable, and industry-relevant. Widespread adoption of similar re-carbon - up-carbon - de-carbon process cycles at industry-relevant scales will significantly enhance the production of active nanocarbon materials for diverse applications, while contributing to the achievement of the ultimate zero-carbon-emissions global targets.
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