Influence of Multi‐Pin Anode Arrangement on Electric Field Distribution Characteristics and Its Application on Microgreen Seed Treatment

This research proposes the design of a multi‐corona discharge model to study the suitable electric field characteristics on sustaining a large stable plasma for microgreen seed treatment. The influence of an increase in the number of pin anode (NP) and the gap distances between two adjacent pins ano...

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Bibliographic Details
Published in:Physica status solidi. A, Applications and materials science Applications and materials science, 2021-01, Vol.218 (1), p.n/a
Main Authors: Tanakaran, Yottana, Matra, Khanit
Format: Article
Language:English
Subjects:
Air plasma
Anodes
Cathodes
corona discharge
Cultivation
Electric corona
electric field stress
Electric fields
Germination
germination rates
growth rates
multi-pin electrodes
Plasma
rat-tailed radish seed treatment
Seeds
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Summary:This research proposes the design of a multi‐corona discharge model to study the suitable electric field characteristics on sustaining a large stable plasma for microgreen seed treatment. The influence of an increase in the number of pin anode (NP) and the gap distances between two adjacent pins anode (GP) on electric field characteristics are studied by the finite‐element method. The results have indicated that the electric field characteristics from a large NP with the 5 mm GP are suitable to sustain the large stable air plasma because of the high virtual semi‐uniform electric field and the wider area of intense electric field stress. Then, the microgreen seeds are treated by the designed air multi‐corona discharge model on a copper cathode (CC) or water cathode (WC). The germination rates of plasma‐treated seeds on the CC and WC are higher than the ones of the control group of about 8% and 6% at 24 h cultivation time, respectively. The growth rates of plasma‐treated seeds on CC and WC are greater than the ones of the control group of about 3.5 and 2.5 times, respectively. It can be confirmed that both plasma‐treated cases have shown a positive effect on germination and growth enhancement. The optimum design of multi‐pin anode obtains the virtual semi‐uniform electric field, which is suitable to generate a uniform plasma on copper or tap water cathodes. The germination and growth rate of microgreen seeds that are treated by uniform plasma on the copper cathode are greater than that of tap water cathode.
ISSN:1862-6300
1862-6319
DOI:10.1002/pssa.202000240