Aerosol Formation During Laser Ablation in a Magnetic Field

被引:0
|
作者
V. F. Myshkin
I. V. Tuksov
Wang Cailun
A. V. Lukin
V. A. Khan
D. V. Lychagin
D. M. Khorokhorin
S. F. Balandin
机构
[1] Tomsk Polytechnic University,
[2] Zuev Institute of Atmospheric Optics,undefined
[3] Siberian Branch of the Russian Academy of Sciences,undefined
[4] Tomsk State University,undefined
[5] Mining and Chemical Combine,undefined
来源
Atomic Energy | 2021年 / 131卷
关键词
D O I
暂无
中图分类号
学科分类号
摘要
Data on the particle size distribution of Al2O3, Zr2O3, and ChS-68 nonmagnetic steel dispersed particles formed from laser plasma in a weak magnetic field are presented. It was found that dispersed particles formed in a magnetic field have sharper edges and smaller sizes than without a magnetic field. A model of physicochemical processes that explains this result is presented. It is shown that the formation probability of a singlet pair of electrons of unpaired electrons of an adsorbed atom and an atom on the surface of a dispersed particle in the first collision increases in a magnetic field. Therefore, in a magnetic field, condensation nuclei form faster and diameter growth of the dispersed particles is greater.
引用
收藏
页码:32 / 36
页数:4
相关论文
共 50 条
  • [21] The effect of nanoparticle presence on aerosol formation during nanoparticle-enhanced laser ablation inductively coupled plasma mass spectrometry
    Holá, Markéta
    Salajková, Zita
    Hrdlička, Aleš
    Ondráček, Jakub
    Novotný, Karel
    Pavliňák, David
    Vojtíšek-Lom, Michal
    Čelko, Ladislav
    Pořízka, Pavel
    Kanický, Viktor
    Prochazka, David
    Novotný, Jan
    Kaiser, Jozef
    Journal of Analytical Atomic Spectrometry, 2020, 35 (12): : 2893 - 2900
  • [22] The effect of nanoparticle presence on aerosol formation during nanoparticle-enhanced laser ablation inductively coupled plasma mass spectrometry
    Hola, Marketa
    Salajkova, Zita
    Hrdlicka, Ales
    Ondracek, Jakub
    Novotny, Karel
    Pavlinak, David
    Vojtisek-Lom, Michal
    Celko, Ladislav
    Porizka, Pavel
    Kanicky, Viktor
    Prochazka, David
    Novotny, Jan
    Kaiser, Jozef
    JOURNAL OF ANALYTICAL ATOMIC SPECTROMETRY, 2020, 35 (12) : 2893 - 2900
  • [23] Formation of molecules during laser ablation of graphite in ammonia atmosphere
    Hermann, J
    Vivien, C
    Perrone, A
    Boulmer-Leborgne, C
    JOURNAL DE PHYSIQUE IV, 1999, 9 (P5): : 147 - 148
  • [24] Ripple formation in the chromium thin film during laser ablation
    Regelskis, Kestutis
    Raciukaitis, Gediminas
    Gedvilas, Mindaugas
    APPLIED SURFACE SCIENCE, 2007, 253 (15) : 6584 - 6587
  • [25] Nanoparticle formation and emission during laser ablation of ceramic tiles
    Salmatonidis, Apostolos
    Viana, Mar
    Perez, Noemi
    Alastuey, Andres
    de la Fuente, German F.
    Angurel, Luis Alberto
    Sanfelix, Vicenta
    Monfort, Eliseo
    JOURNAL OF AEROSOL SCIENCE, 2018, 126 : 152 - 168
  • [26] Formation of nanoparticles during laser ablation of an iron target in a liquid
    Sukhov, I. A.
    Simakin, A. V.
    Shafeev, G. A.
    Viau, G.
    Garcia, C.
    QUANTUM ELECTRONICS, 2012, 42 (05) : 453 - 456
  • [27] Onset of crater formation during short pulse laser ablation
    Maul, J
    Strachnov, I
    Karpuk, S
    Bernhard, P
    Oelsner, A
    Schönhense, G
    Huber, G
    APPLIED PHYSICS A-MATERIALS SCIENCE & PROCESSING, 2006, 82 (01): : 43 - 47
  • [28] Observations of plasma formation during picosecond laser ablation of metals
    Mao, SS
    Mao, XL
    Greif, R
    Russo, RE
    LASER PLASMA GENERATION AND DIAGNOSTICS, 2000, 3935 : 113 - 119
  • [29] Onset of crater formation during short pulse laser ablation
    J. Maul
    I. Strachnov
    S. Karpuk
    P. Bernhard
    A. Oelsner
    G. Schönhense
    G. Huber
    Applied Physics A, 2006, 82 : 43 - 47
  • [30] Experimental study of aerosol production by laser ablation
    Boulaud, D., 1600, (23):
12345