VUV irradiance measurement of a 2.45 GHz microwave-driven hydrogen discharge

Komppula, J.; Tarvainen, O.; Kalvas, Taneli; Koivisto, H.; Kronholm, Risto; Laulainen, Janne; Myllyperkiö, Pasi

doi:10.1088/0022-3727/48/36/365201

Cited by 21 publications

(38 citation statements)

References 27 publications

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“…Total photon emission of at least 15-30% of the discharge power in VUV-range has been measured with a filament driven arc discharge 39 . For a 2.45 GHz microwave discharge the corresponding number is approximately 10% 40 . These values are consistent with this study.…”

Section: Discussionmentioning

confidence: 99%

Plasma heating power dissipation in low temperature hydrogen plasmas

Komppula

Tarvainen

2015

Physics of Plasmas

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Theoretical framework for power dissipation in low temperature plasmas in corona equilibrium is developed. The framework is based on fundamental conservation laws and reaction cross sections and is only weakly sensitive to plasma parameters, e.g. electron temperature and density. The theory is applied to low temperature atomic and molecular hydrogen laboratory plasmas for which the plasma heating power dissipation to photon emission, ionization and chemical potential is calculated. The calculated photon emission is compared to recent experimental results.

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Section: Discussionmentioning

confidence: 99%

Plasma heating power dissipation in low temperature hydrogen plasmas

Komppula

Tarvainen

2015

Physics of Plasmas

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“…Theoretical calculations based on fundamental conservation laws and reaction cross sections show that at least 10% of plasma heating power is dissipated via photon emission in low temperature hydrogen plasmas. 9 The theoretical result is supported by experimental evidence showing that low temperature hydrogen plasmas are strong sources of vacuum ultraviolet (VUV) radiation with up to 15%-30% of the discharge power radiated at wavelengths of 120-250 nm in filamentdriven arc discharge, 10 up to 8% of the injected microwave power at 80-250 nm in ECR discharge, 11 and up to 21% of RF power at 117-280 nm in RF discharge. 12 Electrons in the conduction band of a metal follow the Fermi-Dirac distribution which can be used to derive the following relation for the quantum efficiency Y of the PE emission: 13 Y / ðh À /Þ 2 ðU 0 À hÞ 1=2 ; when h !…”

Section: Introductionmentioning

confidence: 83%

Hydrogen plasma induced photoelectron emission from low work function cesium covered metal surfaces

et al. 2017

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Experimental results of hydrogen plasma induced photoelectron emission from cesium covered metal surfaces under ion source relevant conditions are reported. The transient photoelectron current during the Cs deposition process is measured from Mo, Al, Cu, Ta, Y, Ni, and stainless steel (SAE 304) surfaces. The photoelectron emission is 2-3.5 times higher at optimal Cs layer thickness in comparison to the clean substrate material. Emission from the thick layer of Cs is found to be 60%-80% lower than the emission from clean substrates. Published by AIP Publishing.

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“…In addition it can be expected that their hydrogen atom or proton fraction is more significant in comparison to arc discharge sources. The difference between the discharge types has been experimentally verified by comparing the volumetric rates of molecular ionization and excitation in an ECR discharge [28] and an arc discharge [29] indicating that the ionization and vibrational heating rates/kW of input power are higher in the arc discharge. Thus, from the -H volume production point-of-view RF or ECR discharges cannot be expected to be as power efficient as arc discharge sources.…”

Section: Electron Heating In Rf and Ecr Dischargesmentioning

confidence: 97%

Radiofrequency and 2.45 GHz electron cyclotron resonance H⁻volume production ion sources

Tarvainen

Peng

2016

New J. Phys.

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The volume production of negative hydrogen ions ( -H ) in plasma ion sources is based on dissociative electron attachment (DEA) to rovibrationally excited hydrogen molecules (H 2 ), which is a two-step process requiring both, hot electrons for ionization, and vibrational excitation of the H 2 and cold electrons for the -H formation through DEA. Traditionally -H ion sources relying on the volume production have been tandem-type arc discharge sources equipped with biased filament cathodes sustaining the plasma by thermionic electron emission and with a magnetic filter separating the main discharge from the -H formation volume. The main motivation to develop ion sources based on radiofrequency (RF) or electron cyclotron resonance (ECR) plasma discharges is to eliminate the apparent limitation of the cathode lifetime. In this paper we summarize the principles of -H volume production dictating the ion source design and highlight the differences between the arc discharge and RF/ECR ion sources from both, physics and technology point-of-view. Furthermore, we introduce the state-of-the-art RF and ECR -H volume production ion sources and review the challenges and future prospects of these yet developing technologies. Volume production of -HModern -H plasma ion sources rely on two ion formation processes, resonant-tunneling ionization on low work function surfaces [4] and volumetric ionization occurring in the plasma discharge [5]. Only the volume production will be discussed hereafter.

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VUV irradiance measurement of a 2.45 GHz microwave-driven hydrogen discharge

Cited by 21 publications

References 27 publications

Plasma heating power dissipation in low temperature hydrogen plasmas

Plasma heating power dissipation in low temperature hydrogen plasmas

Hydrogen plasma induced photoelectron emission from low work function cesium covered metal surfaces

Radiofrequency and 2.45 GHz electron cyclotron resonance H⁻volume production ion sources

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VUV irradiance measurement of a 2.45 GHz microwave-driven hydrogen discharge

Cited by 21 publications

References 27 publications

Plasma heating power dissipation in low temperature hydrogen plasmas

Plasma heating power dissipation in low temperature hydrogen plasmas

Hydrogen plasma induced photoelectron emission from low work function cesium covered metal surfaces

Radiofrequency and 2.45 GHz electron cyclotron resonance H−volume production ion sources

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Radiofrequency and 2.45 GHz electron cyclotron resonance H⁻volume production ion sources