Home / Publications / Microscopic model of charge density distribution for critical and supercritical states of carbon

Microscopic model of charge density distribution for critical and supercritical states of carbon

Nikita Borisovich Zorov 1
Nikita Borisovich Zorov
Sergei Gennadievich Ionov 1
Sergei Gennadievich Ionov
10.1070/MC1999v009n02ABEH001026
Published 1999-04-01
CommunicationVolume 9, Issue 2, 61-63
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Kudryashov S. I., Zorov N. B., Ionov S. G. Microscopic model of charge density distribution for critical and supercritical states of carbon // Mendeleev Communications. 1999. Vol. 9. No. 2. pp. 61-63.
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Kudryashov S. I., Zorov N. B., Ionov S. G. Microscopic model of charge density distribution for critical and supercritical states of carbon // Mendeleev Communications. 1999. Vol. 9. No. 2. pp. 61-63.
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TY - JOUR
DO - 10.1070/MC1999v009n02ABEH001026
UR - https://mendcomm.colab.ws/publications/10.1070/MC1999v009n02ABEH001026
TI - Microscopic model of charge density distribution for critical and supercritical states of carbon
T2 - Mendeleev Communications
AU - Kudryashov, Sergei Ivanovich
AU - Zorov, Nikita Borisovich
AU - Ionov, Sergei Gennadievich
PY - 1999
DA - 1999/04/01
PB - Mendeleev Communications
SP - 61-63
IS - 2
VL - 9
ER -
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@article{1999_Kudryashov,
author = {Sergei Ivanovich Kudryashov and Nikita Borisovich Zorov and Sergei Gennadievich Ionov},
title = {Microscopic model of charge density distribution for critical and supercritical states of carbon},
journal = {Mendeleev Communications},
year = {1999},
volume = {9},
publisher = {Mendeleev Communications},
month = {Apr},
url = {https://mendcomm.colab.ws/publications/10.1070/MC1999v009n02ABEH001026},
number = {2},
pages = {61--63},
doi = {10.1070/MC1999v009n02ABEH001026}
}
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Kudryashov, Sergei Ivanovich, et al. “Microscopic model of charge density distribution for critical and supercritical states of carbon.” Mendeleev Communications, vol. 9, no. 2, Apr. 1999, pp. 61-63. https://mendcomm.colab.ws/publications/10.1070/MC1999v009n02ABEH001026.

Abstract

Mass and charge density fluctuations of carbon in critical and supercritical states result in multiply charged negative and positive nanocluster ions which are the main components of the weakly ionised electronless carbon plasma.

References

1.
10.1070/MC1999v009n02ABEH001026_bib1
Fizicheskaya entsiklopediya, 1990
2.
10.1070/MC1999v009n02ABEH001026_bib2
Skripov
Termodinamicheskie svoistva zhidkostei v metastabil’nom sostoyanii, 1980
5.
Thermodynamic properties of carbon up to the critical point
Leider H.R., Krikorian O.H., Young D.A.
Carbon, 1973
6.
Delayed ionization ofC60andC70
Campbell E.E., Ulmer G., Hertel I.V.
Physical Review Letters, 1991
7.
Ionization and fragmentation of fullerene ions by electron impact
Völpel R., Hofmann G., Steidl M., Stenke M., Schlapp M., Trassl R., Salzborn E.
Physical Review Letters, 1993
8.
‘‘Magic number’’ carbon clusters: Ionization potentials and selective reactivity
Zimmerman J.A., Eyler J.R., Bach S.B., McElvany S.W.
Journal of Chemical Physics, 1991
9.
FROM FREE CLUSTERS TO CLUSTER-ASSEMBLED MATERIALS
MELINON P., PAILLARD V., DUPUIS V., PEREZ A., JENSEN P., HOAREAU A., PEREZ J.P., TUAILLON J., BROYER M., VIALLE J.L., PELLARIN M., BAGUENARD B., LERME J.
International Journal of Modern Physics B, 1995
10.
Kudryashov S.I., Karabutov A.A., Emel’yanov V.I., Zorov N.B.
Mendeleev Communications, 1997
11.
10.1070/MC1999v009n02ABEH001026_bib11
Haberland
Proc NATO Adv. Study Institute on Fundamental Processes of Atomic Dynamics, 1987
12.
10.1070/MC1999v009n02ABEH001026_bib12
Fiziko-khimicheskie svoistva poluprovodnikov, 1979
14.
10.1070/MC1999v009n02ABEH001026_bib14
Kalashnikov
Elektrichestvo, 1985
15.
10.1070/MC1999v009n02ABEH001026_bib15
Kudryashov
Techn. Digest of the 16th International Conference on Coherent and Nonlinear Optics ICONO’98, 1998