Weibull analysis of atmospheric pressure plasma generation and evidence for field emission in microwave split-ring resonators

Cohick, Zane; Hall, B. E. S.; Wolfe, Douglas E.; Lanagan, Michael T.

doi:10.1088/1361-6595/ab54e9

Cited by 4 publications

(4 citation statements)

References 55 publications

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“…Assuming that Paschen's law can be applied simply, p min increases to 100 times the value for metamolecule B when g decreases to the order of micrometers. Metamolecules with overall sizes of tens of millimeters and gaps of micrometers [43] may enable us to realize efficient nonlinear metamaterials that include atmospheric-pressure gas as a nonlinear element.…”

Section: Measurement Of Threshold Incident Power For Gas Dischargementioning

confidence: 99%

Low-power threshold gas discharge by enhanced local electric field in electromagnetically-induced-transparencylike metamolecules

Tamayama,

Yamada

2021

Preprint

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To realize efficient nonlinear metamaterials, we investigate a method for enhancing the local electric field in a metamolecule composed of two radiatively coupled cut-wire resonators where resonance of the cut-wire resonators and lowgroup-velocity propagation of an incident electromagnetic wave simultaneously occur. Numerical analysis shows that the local electric field in the metamolecule can be enhanced by decreasing the electrode size and the gap of the capacitor structure of the cut-wire resonators while keeping the equivalent electrical circuit parameters of the metamolecule constant. We measure and compare the threshold incident power for a gas discharge in the metamolecule fabricated in our previous study and that in the metamolecule with shrunken capacitor structures. The experiment reveals that shrinking the capacitor structure while keeping the resonance frequency of the metamolecule decreases the threshold incident power for a gas discharge and may increase the gas pressure where the threshold incident power is minimum. Further development of this work will enable us to realize efficient nonlinear metamaterials that have atmospheric-pressure gas as a nonlinear element.

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Section: Measurement Of Threshold Incident Power For Gas Dischargementioning

confidence: 99%

Low-power threshold gas discharge by enhanced local electric field in electromagnetically-induced-transparencylike metamolecules

Tamayama,

Yamada

2021

Preprint

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“…It is necessary to use fine processing techniques for fabricating the capacitor structures with g of the order of micrometers. For example, a microwave split-ring resonator with a gap of less than 10 µm has been fabricated using laser ablation [45]. When such fine processing techniques are used, thin metallic patterns usually need to be fabricated on a dielectric substrate.…”

Section: Measurement Of Threshold Incident Power For Gas Dischargementioning

confidence: 99%

Low-power threshold gas discharge by enhanced local electric field in electromagnetically-induced-transparency like metamolecules

Tamayama¹,

Yamada²

2021

J. Phys. D: Appl. Phys.

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To realize efficient nonlinear metamaterials, we investigate a method for enhancing the local electric field in a metamolecule composed of two radiatively coupled cut-wire resonators where resonance of the cut-wire resonators and low-group-velocity propagation of an incident electromagnetic wave simultaneously occurs. Numerical analysis shows that the local electric field in the metamolecule can be enhanced by decreasing the electrode size and the gap of the capacitor structure of the cut-wire resonators while keeping the equivalent electrical circuit parameters of the metamolecule constant. We measure and compare the threshold incident power for a gas discharge in a metamolecule fabricated in our previous study and that in a metamolecule with shrunken capacitor structures. The experiment reveals that shrinking the capacitor structure while keeping the resonance frequency of the metamolecule decreases the threshold incident power for a gas discharge and may increase the gas pressure where the threshold incident power is minimum. Further development of this work will enable us to realize efficient nonlinear metamaterials that have atmospheric-pressure gas as a nonlinear element.

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“…Additionally, the non-Paschen behaviour of microwave/RF breakdown in microgaps perhaps be contributed to the multiple effective lengths involved and differences between low-and high-frequency breakdown [15][16][17]. Until 2020, the first in-depth experimental investigation that really suggests the possibility and importance of field emission in breakdown for microwave/RF microplasmas was performed by Cohick et al [18].…”

Section: Introductionmentioning

confidence: 99%

Microplasma emission performances dependent on silicon nanowires morphologies

Ma¹,

Chen²,

Yaogong³

et al. 2022

J. Phys. D: Appl. Phys.

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Silicon nanowires (SiNWs) are introduced into microdischarge to improve microplasma properties due to its field emission electrons and field enhancement effect. The geometrical arrangement and dimensional features of SiNWs have desicive influence on field emission properties, thus the dependence of microplasma emission performances on the SiNWs morphologies is investigated in this paper. The different morphologies of SiNWs can be prepared by electrocatalytic metal-assisted chemical etching with varied etching currents. With the increase of etching current from 3 mA to 30 mA (AgNO3:HF:H2O2 = 0.02:4.6:0.1 mol l−1, deposition time 1 min and etching time 10 min), the field emission current density J of the SiNWs prepared at 20 mA etching current is the largest ∼0.28 mA cm−2 at a field 4.5 V μm−1, and turn-on field is the lowest of 3.52 V μm−1. Accordingly, the microplasma in the device fabricated on the SiNWs-decorated substrate (etching current at 20 mA) has the strongest average emission intensity of ∼11 565 a.u., the minimal relative standard deviation of emission intensity 4.9% and the fastest propagation velocity of 471 km s−1. The field emission electrons of SiNWs could inject more seed electrons into microcavity which causes higher electron collision probability, and the field enhancement effect at tips of SiNWs can provide more energy for the charged particles, which are helpful to the microdischarge. The most difficulty is to balance the distance of emitters and the percentage of SiNWs in entire emission region because the shielding effect will reduce while the surface emitter numbers will decrease when the distance of emitters increases. Here, a ‘proper percentage of SiNWs’ of 19.3% is obtained what indicates that if SiNWs percentage is greater than the threshold, field enhancement factor β eff is weakened by the decrease of aspect ratio and the increase of percentage. When SiNWs percentage is less than 19.3%, β eff will increase and be dominated by the percentage of SiNWs. The results are significant for the application of SiNWs in microdischarge devices.

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Weibull analysis of atmospheric pressure plasma generation and evidence for field emission in microwave split-ring resonators

Cited by 4 publications

References 55 publications

Low-power threshold gas discharge by enhanced local electric field in electromagnetically-induced-transparencylike metamolecules

Low-power threshold gas discharge by enhanced local electric field in electromagnetically-induced-transparencylike metamolecules

Low-power threshold gas discharge by enhanced local electric field in electromagnetically-induced-transparency like metamolecules

Microplasma emission performances dependent on silicon nanowires morphologies

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