Seed-packed dielectric barrier device for plasma agriculture: understanding its electrical properties through an equivalent electrical model

TL;DR

This study develops and validates an equivalent electrical model to understand how seed packing in a dielectric barrier device influences plasma electrical properties and germination outcomes across different seed types.

Contribution

The paper introduces a novel equivalent electrical model for plasma-seed interactions and demonstrates its ability to analyze seed effects on plasma properties and germination.

Findings

Seed packing increases gas capacitance and alters filament breakdown voltages.

The model estimates contact volume and seed capacitance in packed-bed configurations.

Plasma treatment enhances germination in four out of six seed types.

Abstract

Seeds have been packed in a dielectric barrier device where cold atmospheric plasma has been generated to improve their germinative properties. A special attention has been paid on understanding the resulting plasma electrical properties through an equivalent electrical model whose experimental validity has been demonstrated here. In this model, the interelectrode gap is subdivided into 4 types of elementary domains, according to whether they contain electric charges (or not) and according to their type of medium (gas, seed or insulator). The model enables to study the influence of seeds on the plasma electrical properties by measuring and deducing several parameters (charge per filament, gas capacitance, plasma power, ...) either in no-bed configuration (i.e. no seed in the reactor) or in packed-bed configuration (seeds in the reactor). In that second case, we have investigated how seeds can influence the plasma electrical parameters considering six specimens of seeds (beans, radishes, corianders, lentils, sunflowers and corns). The influence of molecular oxygen (0-100 sccm) mixed with a continuous flow rate of helium (2 slm) is also investigated, especially through filaments breakdown voltages, charge per filament and plasma power. It is demonstrated that such bed-packing drives to an increase in the gas capacitance, to a decrease in the beta-parameter and to variations of the filaments' breakdown voltages in a seed-dependent manner. Finally, we show how the equivalent electrical model can be used to assess the total volume of the contact points, the capacitance of the seeds in the packed-bed configuration and we demonstrate that germinative effects can be induced by plasma on four of the six agronomical specimens.