AI Article Synopsis
- Atmospheric pressure dielectric barrier discharge (DBD) plasma is an innovative technique for cleaning air in public spaces, but the effects of power supply on its disinfection abilities are not well understood.
- A study used a nanosecond pulsed power supply with a specific DBD setup to investigate how different settings and environmental factors influenced the effectiveness of bacterial inactivation.
- Results showed that higher discharge power and optimal humidity levels significantly improved air disinfection efficiency, achieving around 99% effectiveness at a relative humidity of 50%-60%.
Article Abstract
Atmospheric pressure dielectric barrier discharge (DBD) plasma is an emerging and promising technique for air disinfection in public environments. Power supply is a crucial factor but it remains unclear about its impacts on the air disinfection performance of plasmas. In this work, a nanosecond (ns) pulsed power supply was applied to drive an in-duct grating-like DBD array to achieve fast single-pass air disinfection. The influence of pulse parameters and environmental factors on both the discharge characteristics and the single-pass bacterial inactivation efficiency were uncovered. At a close relative humidity (RH) level, the efficiency was dominated by the discharge power, namely, specific input energy could serve as the disinfection dose. A higher frequency, shorter pulse rising time, and suitable pulse width are preferred to obtain a higher Z value. The pulsed source was not notably superior to an alternating current source, or even worse at a low voltage frequency at the same discharge power. Airflow humidity was a predominant factor to improve the efficiency and a single-pass efficiency of ∼ 99% and a Z value of 2.2 L/J were achieved under an optimal RH of 50%-60%. This work provides fundamental knowledge of ns-pulsed DBD on discharge characteristics and air disinfection behaviors.
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| http://dx.doi.org/10.1016/j.jhazmat.2024.134487 | DOI Listing |
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