Direct air capture (DAC) represents a promising technology for mitigating climate change by extracting CO 2 from the atmosphere. This study introduces a novel application for effective CO 2 capture from dispersed emission sources, integrated with a liquid electrolysis system to improve capture cycle efficiency. By focusing on distributed sources, the DAC application overcomes the constraints of traditional stationary CO 2 capture methods. It employs a thin-layer moving bed spray and air convection to capture CO 2 in lean liquid, which converts into rich trap liquid when the carbonate concentration exceeds a certain threshold. Electrolysis is then used to recover the lean liquid. This design allows for quick, energy-efficient CO 2 absorption even under low partial pressure conditions (462 ppm). The technology is designed to facilitate significant CO 2 capture while concurrently generating high-purity hydrogen and collecting carbon dioxide. By reusing the capture liquid, an integrated capture and desorption process is realized. In a test with 1 M KOH as a lean trap solution and a wind speed of 9 m/s, a rich trap solution was obtained after 13 h, lowering the CO 2 concentration at the outlet by 97 ppm compared to the input air, demonstrating the device's effectiveness.