Abstract

With the increase in the greenhouse effect and reduction of fossil fuel resources, it is urgent to find a feasible solution to directly convert power to chemicals using renewable energy and achieving zero carbon emissions targets. It is necessary to convert renewable energy (i.e., solar, wind, water, etc.) into electrical power replacing fossil-fuel-fired power. Therefore, the power-to-chemicals approach is gaining more and more attention. In the past two decades, non-thermal plasma, electro-catalysis, photo-catalysis, and their hybrid approaches have shown great potential for the power-to-chemicals solution. This paper introduces the application of plasma technology in energy conversion, focusing on three main routes for plasma-enabled ammonia synthesis, and analyses the state-of-the-art. Research results of ammonia synthesis based on plasma technology are discussed. The application of advanced in situ diagnostics evidences the importance of specific intermediate species and reaction pathways. Electrons, vibrationally-excited species, free radicals, and surface-adsorbed species play important roles in plasma-catalytic ammonia synthesis. Combined with experiments and simulations, the mechanisms of plasma-catalytic ammonia synthesis are examined. Vibrationally-excited species can effectively reduce the catalytic surface energy barrier. The techno-economics of the plasma-enabled ammonia synthesis technology is discussed in view of its competitive advantages. It is emphasized that the power-to-chemicals approach can be adapted for most chemical manufacturers, and these methods would play crucial roles in reducing carbon emissions and environmental pollution. Finally, suggestions are provided for the sustainable development of the power-to-chemicals industry in the future.

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