Research output: Contribution to journal › Article › peer-review
Mass spectrometry of clustered flows during gas ionization by low-temperature plasma in the diffuser part of the nozzle. / Khudozhitkov, V. E.; Zarvin, A. E.; Kalyada, V. V.
In: Physics of Plasmas, Vol. 32, No. 3, 033508, 13.03.2025.Research output: Contribution to journal › Article › peer-review
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TY - JOUR
T1 - Mass spectrometry of clustered flows during gas ionization by low-temperature plasma in the diffuser part of the nozzle
AU - Khudozhitkov, V. E.
AU - Zarvin, A. E.
AU - Kalyada, V. V.
N1 - This research was carried out on the equipment of the Center for Collective Use “Applied Physics” of Novosibirsk State University with the financial support of the Ministry of Education and Science of the Russian Federation (Grant No. FSUS-2025-0008).
PY - 2025/3/13
Y1 - 2025/3/13
N2 - This paper presents a technique for mass spectrometry of an ionized cluster flow in the variant of its ionization in a supersonic nozzle when gas flows into a rarefied space. The purpose of the implementation of the methodology presented in the work is its further use for conducting research on the initiation of intracluster energy exchange. To ionize the gas flow in the nozzle, a scheme for generating an effective discharge directly in the diffuser part of a supersonic nozzle has been developed and implemented. The results obtained under the conditions of traditional mass spectrometry of neutral fluxes with particle ionization directly in the mass spectrometer detector (EBMS method) and under the conditions of ionization of a supersonic jet at a selected distance from the nozzle by a high-voltage electron beam (HVEB method) are compared with the results obtained by the discharge ionization method in the nozzle (DIN method). It has been experimentally revealed that when using the DIN method, a significantly larger number of ions are formed than when using the HVEB method, which is an undoubted advantage of the developed method. It is shown that the heating of the nozzle leads to some delay in the condensation process, but a relatively small correction of the stagnation pressure compensates for this loss. The results of trial experiments on the search for conditions for ion-cluster energy exchange are presented using the example of an argon-methane mixture flow.
AB - This paper presents a technique for mass spectrometry of an ionized cluster flow in the variant of its ionization in a supersonic nozzle when gas flows into a rarefied space. The purpose of the implementation of the methodology presented in the work is its further use for conducting research on the initiation of intracluster energy exchange. To ionize the gas flow in the nozzle, a scheme for generating an effective discharge directly in the diffuser part of a supersonic nozzle has been developed and implemented. The results obtained under the conditions of traditional mass spectrometry of neutral fluxes with particle ionization directly in the mass spectrometer detector (EBMS method) and under the conditions of ionization of a supersonic jet at a selected distance from the nozzle by a high-voltage electron beam (HVEB method) are compared with the results obtained by the discharge ionization method in the nozzle (DIN method). It has been experimentally revealed that when using the DIN method, a significantly larger number of ions are formed than when using the HVEB method, which is an undoubted advantage of the developed method. It is shown that the heating of the nozzle leads to some delay in the condensation process, but a relatively small correction of the stagnation pressure compensates for this loss. The results of trial experiments on the search for conditions for ion-cluster energy exchange are presented using the example of an argon-methane mixture flow.
UR - https://www.mendeley.com/catalogue/b9bb9e7b-7291-351f-b28c-7d37f92785c2/
UR - https://www.scopus.com/record/display.uri?eid=2-s2.0-105000072994&origin=inward&txGid=94126a4fbb53f89ec2e520b2acff4647
U2 - 10.1063/5.0250894
DO - 10.1063/5.0250894
M3 - Article
VL - 32
JO - Physics of Plasmas
JF - Physics of Plasmas
SN - 1070-664X
IS - 3
M1 - 033508
ER -
ID: 65117843