What question did this study set out to answer?

The aim is to understand how flow rate and inlet design affect CO2 decomposition and discharge performance in an AC-RGA reactor.

April 16, 2026

Effect of Multi‐Inlet Flow Uniformity on Discharge Characteristics and CO 2 Decomposition in an AC‐Driven Rotating Gliding Arc System

Key Points

The aim is to understand how flow rate and inlet design affect CO2 decomposition and discharge performance in an AC-RGA reactor.
Examined gas flow rates and inlet configurations
Conducted optical emission spectroscopy
Analyzed exhaust temperatures
The four-inlet design provided a more uniform flow field
Enhanced CO2 conversion and energy efficiency were observed
Uniform flow reduced voltage fluctuations and CO/O recombination

Abstract

ABSTRACT The AC‐driven rotating gliding arc (AC‐RGA) reactor offers advantages in simplifying discharge systems and reducing energy losses. Using CO 2 as the working gas, this study examines how gas flow rate and inlet configuration influence arc dynamics, electrical behavior, and CO 2 conversion. Compared with the single‐inlet design, the four‐inlet configuration generates a more uniform flow field, stabilizing arc rotation, reducing voltage fluctuations, and enhancing CO 2 conversion and energy efficiency. Optical emission spectroscopy and exhaust temperature analyses indicate that the uniform flow suppresses CO and O recombination while promoting CO 2 + formation, thereby improving decomposition efficiency and highlighting the importance of flow uniformity in optimizing AC‐RGA performance.

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Effect of Multi‐Inlet Flow Uniformity on Discharge Characteristics and CO 2 Decomposition in an AC‐Driven Rotating Gliding Arc System

Key Points

Abstract

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