High-resolution electric field and temperature distributions in positive streamers

Siebe Dijcks; Lukáš Kusýn; Jesper Janssen; Petr Bílek; Sander Nijdam; Tomáš Hoder

doi:10.3389/fphy.2023.1120284

High-resolution electric field and temperature distributions in positive streamers

Siebe Dijcks, Lukáš Kusýn, Jesper Janssen, Petr Bílek, Sander Nijdam (Corresponding author), Tomáš Hoder

Elementary Processes in Gas Discharges

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Abstract

In this work, we aim to take a detailed experimental picture of the positive streamer. We apply optical emission spectroscopy to the first negative system (FNS, (Formula presented.)) of (Formula presented.) and the second positive system (SPS, C³Π_u → B³Π_g) of N₂. Large, centimeter wide, and highly reproducible streamers are created in pure nitrogen and synthetic air, at pressures ranging from 33 to 266 mbar. Direct time resolved spectral imaging of the space charge layer resulted in spatiotemporal maps of the calculated reduced electric field strength (E/N) and rovibrational temperature in sub-nanosecond and sub-millimetre resolution. The E/N peaks at approximately 540 and 480 Td, directly in front of the space charge layer, for synthetic air and pure nitrogen respectively, as determined by using the intensity ratio method of FNS and SPS. A global model for pure nitrogen in PLASIMO uses the experimentally determined E/N distribution to draw a picture of the gas kinetics around the space charge layer passage. In addition, the results of the global model serve as a reference to interpret the rotational and vibrational temperatures obtained from experimental FNS and SPS emissions.

Original language	English
Article number	1120284
Number of pages	15
Journal	Frontiers in Physics
Volume	11
DOIs	https://doi.org/10.3389/fphy.2023.1120284
Publication status	Published - 3 Apr 2023

Bibliographical note

Funding Information:
This publication (SD& SN) is part of the project ‘Let CO Spark’ (with project number 15052) of the research programme Open Technology Programme which is (partly) financed by the Dutch Research Council (NWO). LK and TH were supported both by the Czech Science Foundation under contract no.21-16391S and Project LM2018097 funded by the Ministry of Education, Youth and Sports of the Czech Republic. 2

Funding

This publication (SD& SN) is part of the project ‘Let CO Spark’ (with project number 15052) of the research programme Open Technology Programme which is (partly) financed by the Dutch Research Council (NWO). LK and TH were supported both by the Czech Science Foundation under contract no.21-16391S and Project LM2018097 funded by the Ministry of Education, Youth and Sports of the Czech Republic. 2

Keywords

nanosecond pulsed discharge
non-equilibrium
OES
optical emission spectroscopy
plasma
reduced electric field
streamer discharge

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title = "High-resolution electric field and temperature distributions in positive streamers",

abstract = "In this work, we aim to take a detailed experimental picture of the positive streamer. We apply optical emission spectroscopy to the first negative system (FNS, (Formula presented.)) of (Formula presented.) and the second positive system (SPS, C3Πu → B3Πg) of N2. Large, centimeter wide, and highly reproducible streamers are created in pure nitrogen and synthetic air, at pressures ranging from 33 to 266 mbar. Direct time resolved spectral imaging of the space charge layer resulted in spatiotemporal maps of the calculated reduced electric field strength (E/N) and rovibrational temperature in sub-nanosecond and sub-millimetre resolution. The E/N peaks at approximately 540 and 480 Td, directly in front of the space charge layer, for synthetic air and pure nitrogen respectively, as determined by using the intensity ratio method of FNS and SPS. A global model for pure nitrogen in PLASIMO uses the experimentally determined E/N distribution to draw a picture of the gas kinetics around the space charge layer passage. In addition, the results of the global model serve as a reference to interpret the rotational and vibrational temperatures obtained from experimental FNS and SPS emissions.",

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author = "Siebe Dijcks and Luk{\'a}{\v s} Kus{\'y}n and Jesper Janssen and Petr B{\'i}lek and Sander Nijdam and Tom{\'a}{\v s} Hoder",

note = "Funding Information: This publication (SD\& SN) is part of the project {\textquoteleft}Let CO Spark{\textquoteright} (with project number 15052) of the research programme Open Technology Programme which is (partly) financed by the Dutch Research Council (NWO). LK and TH were supported both by the Czech Science Foundation under contract no.21-16391S and Project LM2018097 funded by the Ministry of Education, Youth and Sports of the Czech Republic. 2 ",

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AU - Nijdam, Sander

AU - Hoder, Tomáš

N1 - Funding Information: This publication (SD& SN) is part of the project ‘Let CO Spark’ (with project number 15052) of the research programme Open Technology Programme which is (partly) financed by the Dutch Research Council (NWO). LK and TH were supported both by the Czech Science Foundation under contract no.21-16391S and Project LM2018097 funded by the Ministry of Education, Youth and Sports of the Czech Republic. 2

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Y1 - 2023/4/3

N2 - In this work, we aim to take a detailed experimental picture of the positive streamer. We apply optical emission spectroscopy to the first negative system (FNS, (Formula presented.)) of (Formula presented.) and the second positive system (SPS, C3Πu → B3Πg) of N2. Large, centimeter wide, and highly reproducible streamers are created in pure nitrogen and synthetic air, at pressures ranging from 33 to 266 mbar. Direct time resolved spectral imaging of the space charge layer resulted in spatiotemporal maps of the calculated reduced electric field strength (E/N) and rovibrational temperature in sub-nanosecond and sub-millimetre resolution. The E/N peaks at approximately 540 and 480 Td, directly in front of the space charge layer, for synthetic air and pure nitrogen respectively, as determined by using the intensity ratio method of FNS and SPS. A global model for pure nitrogen in PLASIMO uses the experimentally determined E/N distribution to draw a picture of the gas kinetics around the space charge layer passage. In addition, the results of the global model serve as a reference to interpret the rotational and vibrational temperatures obtained from experimental FNS and SPS emissions.

AB - In this work, we aim to take a detailed experimental picture of the positive streamer. We apply optical emission spectroscopy to the first negative system (FNS, (Formula presented.)) of (Formula presented.) and the second positive system (SPS, C3Πu → B3Πg) of N2. Large, centimeter wide, and highly reproducible streamers are created in pure nitrogen and synthetic air, at pressures ranging from 33 to 266 mbar. Direct time resolved spectral imaging of the space charge layer resulted in spatiotemporal maps of the calculated reduced electric field strength (E/N) and rovibrational temperature in sub-nanosecond and sub-millimetre resolution. The E/N peaks at approximately 540 and 480 Td, directly in front of the space charge layer, for synthetic air and pure nitrogen respectively, as determined by using the intensity ratio method of FNS and SPS. A global model for pure nitrogen in PLASIMO uses the experimentally determined E/N distribution to draw a picture of the gas kinetics around the space charge layer passage. In addition, the results of the global model serve as a reference to interpret the rotational and vibrational temperatures obtained from experimental FNS and SPS emissions.

KW - nanosecond pulsed discharge

KW - non-equilibrium

KW - OES

KW - optical emission spectroscopy

KW - plasma

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KW - streamer discharge

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High-resolution electric field and temperature distributions in positive streamers

Abstract

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Keywords

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