Stable potential formation with neutral and dust particles in expanding magnetic field near divertor plate

Stable potential formation with neutral and dust particles in expanding magnetic field near divertor plate

The effects of neutral and dust particles for the stable or monotonically changing potential formation in an expanding magnetic field toward the divertor plate was investigated in a quasi-neutral plasma by using one-dimensional kinetic analysis. Unless there are plasma ion sources, such as ionizatio...

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Datum:2002
Hauptverfasser: Tomita, Yu., Chutov, Yu.I.
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Sprache:English
Veröffentlicht: Національний науковий центр «Харківський фізико-технічний інститут» НАН України 2002
Schriftenreihe:Вопросы атомной науки и техники
Schlagworte:
Magnetic confinement
Online Zugang:https://nasplib.isofts.kiev.ua/handle/123456789/80256
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Zitieren:Stable potential formation with neutral and dust particles in expanding magnetic field near divertor plate / Yu. Tomita, Yu.I. Chutov // Вопросы атомной науки и техники. — 2002. — № 4. — С. 39-41. — Бібліогр.: 5 назв. — англ.

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spelling nasplib_isofts_kiev_ua-123456789-802562025-02-09T13:43:49Z Stable potential formation with neutral and dust particles in expanding magnetic field near divertor plate Tomita, Yu. Chutov, Yu.I. Magnetic confinement The effects of neutral and dust particles for the stable or monotonically changing potential formation in an expanding magnetic field toward the divertor plate was investigated in a quasi-neutral plasma by using one-dimensional kinetic analysis. Unless there are plasma ion sources, such as ionization of neutral particles, the required ion flow velocity for injected ions to form the stable potential has to be larger than an ion sound velocity, i.e. the generalized Bohm’s criterion. It was clarified that the plasma ion sources mitigate this requirement. On the other hand, since the dust particles decrease the plasma ion density due to absorption to them, the required ion flow velocity for injected ions increases. The numerical values of these effects are presented. The decreasing magnetic field in a plate direction also increases this required velocity. This collaborated research was supported by the Heiwa-Nakajima Foundation. 2002 Article Stable potential formation with neutral and dust particles in expanding magnetic field near divertor plate / Yu. Tomita, Yu.I. Chutov // Вопросы атомной науки и техники. — 2002. — № 4. — С. 39-41. — Бібліогр.: 5 назв. — англ. 1562-6016 PACS: 52.55Hc; 52.55Rk https://nasplib.isofts.kiev.ua/handle/123456789/80256 en Вопросы атомной науки и техники application/pdf Національний науковий центр «Харківський фізико-технічний інститут» НАН України
institution Digital Library of Periodicals of National Academy of Sciences of Ukraine
collection DSpace DC
language English
topic Magnetic confinement
Magnetic confinement
spellingShingle Magnetic confinement
Magnetic confinement
Tomita, Yu.
Chutov, Yu.I.
Stable potential formation with neutral and dust particles in expanding magnetic field near divertor plate
Вопросы атомной науки и техники
description The effects of neutral and dust particles for the stable or monotonically changing potential formation in an expanding magnetic field toward the divertor plate was investigated in a quasi-neutral plasma by using one-dimensional kinetic analysis. Unless there are plasma ion sources, such as ionization of neutral particles, the required ion flow velocity for injected ions to form the stable potential has to be larger than an ion sound velocity, i.e. the generalized Bohm’s criterion. It was clarified that the plasma ion sources mitigate this requirement. On the other hand, since the dust particles decrease the plasma ion density due to absorption to them, the required ion flow velocity for injected ions increases. The numerical values of these effects are presented. The decreasing magnetic field in a plate direction also increases this required velocity.
format Article
author Tomita, Yu.
Chutov, Yu.I.
author_facet Tomita, Yu.
Chutov, Yu.I.
author_sort Tomita, Yu.
title Stable potential formation with neutral and dust particles in expanding magnetic field near divertor plate
title_short Stable potential formation with neutral and dust particles in expanding magnetic field near divertor plate
title_full Stable potential formation with neutral and dust particles in expanding magnetic field near divertor plate
title_fullStr Stable potential formation with neutral and dust particles in expanding magnetic field near divertor plate
title_full_unstemmed Stable potential formation with neutral and dust particles in expanding magnetic field near divertor plate
title_sort stable potential formation with neutral and dust particles in expanding magnetic field near divertor plate
publisher Національний науковий центр «Харківський фізико-технічний інститут» НАН України
publishDate 2002
topic_facet Magnetic confinement
url https://nasplib.isofts.kiev.ua/handle/123456789/80256
citation_txt Stable potential formation with neutral and dust particles in expanding magnetic field near divertor plate / Yu. Tomita, Yu.I. Chutov // Вопросы атомной науки и техники. — 2002. — № 4. — С. 39-41. — Бібліогр.: 5 назв. — англ.
series Вопросы атомной науки и техники
work_keys_str_mv AT tomitayu stablepotentialformationwithneutralanddustparticlesinexpandingmagneticfieldneardivertorplate
AT chutovyui stablepotentialformationwithneutralanddustparticlesinexpandingmagneticfieldneardivertorplate
first_indexed 2025-11-26T11:36:38Z
last_indexed 2025-11-26T11:36:38Z
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fulltext divertor plate plasma flow from SOL L z quasi-neutral plasma with neutral and dust particles B(z) φ (z)0 STABLE POTENTIAL FORMATION WITH NEUTRAL AND DUST PARTICLES IN EXPANDING MAGNETIC FIELD NEAR DIVERTOR PLATE Yukihiro Tomita National Institute for Fusion Science, Toki, Gifu 509-5292 Japan Yuriy I. Chutov Taras Shevchenko Kiev University, Volodymyrs'ka 64, 252017 Kiev-17, Ukraine The effects of neutral and dust particles for the stable or monotonically changing potential formation in an expanding magnetic field toward the divertor plate was investigated in a quasi-neutral plasma by using one-dimensional kinetic analysis. Unless there are plasma ion sources, such as ionization of neutral particles, the required ion flow velocity for injected ions to form the stable potential has to be larger than an ion sound velocity, i.e. the generalized Bohm’s criterion. It was clarified that the plasma ion sources mitigate this requirement. On the other hand, since the dust particles decrease the plasma ion density due to absorption to them, the required ion flow velocity for injected ions increases. The numerical values of these effects are presented. The decreasing magnetic field in a plate direction also increases this required velocity. PACS: 52.55Hc; 52.55Rk I. INTRODUCTION The electrostatic potential can strongly influence the behavior of plasma particles near a divertor region. In fusion devices, the magnetic field is expanding in the plate direction; i.e. the magnitude of the magnetic field is decreasing to the plate. In this configuration, ions are accelerated to the plate due to the gradient of the magnetic field, so-called the mirror force. The neutral particles play an important role to remove the heat flow from the core plasma to the divertor plate. The dust particles have also same effects as neutrals. In LHD (Large Helical Device) the collection of dust particles was reported [1], where the dust particles have the size of about 10 µm with the surface mass density of around 100 mg/m2. In this study, the effects of neutral and dust particles on formation of stable electrostatic potential in nonuniform magnetic field are discussed. II. ION VELOCITY DISTRIBUTION AND DENSITY The model geometry for a one-dimensional analysis is shown in Fig 1, where the divertor plate is located at the position of z = L. The magnitude of magnetic field B (z), which is directed toward the z direction, decreases to the plate ( d B / d z < 0) so slowly that the magnetic moment of ions µ is conserved during their motion. The neutral and dust particles are uniformly distributed in front of the divertor plate. The plasma flow from the point z = 0 is taken account, which corresponds the plasma flow from the SOL (Scrape-Off Layer) region to the divertor region. The electrons are assumed to satisfy the Boltzmann relation with the uniform electron temperature. In this analysis we investigate the potential formation φ (z) with the magnetic field monotonically decreasing in the divertor plate direction. The ion velocity distribution function is expressed from Boltzmann equation in ( , , )z ε µ space, where ε is the total energy of an ion   2 / 2 ( ) ( )i z iB z zqM µ φυ + + which is one of the constants of motion of ions: ( , , ) ( , , ) ( , , ) ( , , )i z i d zf z z zS Sz ε µ ε µ ε µ ε µυ ∂ = − ∂ Fig.1. Geometrical model for a one-dimensional analysis. where the charge and the mass of plasma ion are denoted by qi and Mi , respectively. The particle velocity toward the plate zυ should be expressed by the variables ( , , )z ε µ : 2 2[ ( ) ( ) ] / iz iB z zq Mε µ φυ = − − . In this study, the plasma ion source Si due to electron impact ionization of neutral atoms and the plasma ion sink Sd due to absorption to dust particles are considered as well as the plasma flow from the SOL region. The ion source Si is introduced as [2,3]: 2 2 2 ( , , ) ( ) ( , , ) 4 exp[ ( , , ) / 2 ] i i e s i z s i s Mz z zS n n T zM T ε µ ε µσ υ υ π ε µυ = < > × − where ns is the uniform density of the neutral atoms, iσ υ< > is the ionization rate by electron impact and Ts is the temperature of source ions, which is assumed spatially uniform. In this distribution function, the ion velocity υ Problems of Atomic Science and Technology. 2002. № 4. Series: Plasma Physics (7). P. 39-41 39 and zυ should be expressed by the function of (z, ε, µ). Taking into account the turn of generated ions with negative velocity in z-direction ( 0zυ < ) in the decreasing potential and magnetic field, the density of the generated source ions is obtained in case of a weak nonuniformity of magnetic field and potential as following: 0 0 ( ) exp[ ( ) / ] 2 exp[( / / ) ( )] i si s s e i i s L s ei Mz zqn n n T T dz e zq T T π φσ υ φ = −< > ′ ′× +∫ where ne0 is the electron density at the position of φ = 0. The injected plasma ion distribution function from the SOL region is determined by the absorption to dust particles. Since the dust particles is at rest due to their heavy masses, the plasma ion absorption rate is expressed by ( , , ) ( ) ( , , )d d d iz zfS nε µ υ υ ε µσ= From this expression the injected ion density is obtained as follows. 0 2 0 (0) 0 ( , )2 ( )( ) ( , , ) exp{ [ ( , , )] ( , , ) / ( , , ) } i i n zBi z d d z fB zz d dn zM dz z z zn µ ε µπ µ ε ε µυ υ ε µ υ ε µ ε µσ υ ∞ ∞ = ∫ ∫ ′ ′ ′ ′× − ∫ These expressions of plasma ion densities are used to study the stable electrostatic potential formation. III. POTENTIAL FORMATION The potential formation in the quasi-neutral plasma immersed in the expanding magnetic field is investigated by using the charge neutrality condition with negatively charged ( Zd ) dust particle density nd: d i ie d i s inn n n nZ Z Z+ = + and the equality of the density gradients for uniformly distributed dust particles: ( )i s ine i d dn nd n Zd z d z d z = + The density gradient of electron is obtained from its Boltzmann distribution: ( )e e e d e dn znd z d zT φ= The density gradient of plasma ion source generated by the electron impact ionization is expressed from Eq.(3). ( )i s i i s s d qn d znd z d zT φ= − From considering the spatial dependence of the injected ion density Eq.(5), we can easily obtain its density gradient. 2 2 2 ln 1 ln[ / 2 / ] in z z i d d z dz zz i d n d B d B d z d z d z q d n nd zM υ υ φ υσ υυ ⊥ − = + < > + − < >< > where the quantity z< ⋅⋅ ⋅ > denotes the average over the velocity distribution function of the injected ions. The equality condition (6) of the quasi-neutral plasma gives the relation between spatial dependences of the potential, the magnetic field and the ion velocity. 2 2 2 1 ln[ (1 / 2 / ] i ii s ini z ze se e i d d zz zz i qn nZ Ze d d d B d z d z d zn nT T q d nd zM φ φ υ υ φ υσ υυ ⊥ − = − + + < > + − < >< > First we investigate the effects of neutral particles without dust particles ( 0dn = ) on stable potential formation. The spatial variation of potential and magnetic field is expressed from Eq.(10) and 0dn = . 2 2 2 1 ln(1 )/ 2 (1 ) / (1 ) e z z i e i e i s i sz zi s d BT e d Z T Z T M T υ υ φ υ δ δ ⊥ − + < > = − + + −< > Here i sδ is defined by the ratio of the density of the generated ions to the electron density : /ii s i s en nZδ ≡ . In our case of decreasing potential and magnetic field, LHS of Eq. (11) is positive. Hence in order to be formed the monotonically decreasing potential in the decreasing magnetic field in the plate direction, the ion flow velocity have to be satisfied the following condition: 1 22 / (1 ) / (1 )i e s i s i sz z s Z Tc T δ δυ −− ≥ − +< > where sc ( /i e iZ T M= ) is the ion sound speed. Without plasma source inside quasi-neutral plasma ( 0i sδ = ), this relation leads the generalized Bohm's criterion [4,5]: 12 1z zυ −− ≥< > The effect of ion source is shown in Fig. 2 for the case of 1, 10 eVi eZ T= = , and 0.03 eVsT = , which corresponds to the room temperature of 20 C° . This result shows ion source in a divertor region mitigates the generalized Bohm's criterion (for example: the 1 % of source ions decreases this limit to 0.48). It is clearly understand the existence of dust particles increases the limit of ion flow velocity because they decrease the density of plasma ions due to absorption. The requirement for the ion flow velocity is obtained from Eq.(10). 40 1 22 1 / / 1 / / dis d e sz z i e e i s d d z z s n nZ c Z T Tn ed d zT δ υ υδ σ υ φ −− − + ≥< > + + < > Fig. 2 Limit value of 1 22 / sz z cυ −−< > as a function of concentration of plasma ion generated by ionization, where 1, 10 eVi eZ T= = and 0.03 eVsT = . The third terms of the fraction of RHS indicate the effects of dust particles, where note that the potential gradient is negative ( / 0d d zφ < ). The effect of dust particles on stable potential formation is shown in Fig. 3, where 1, 10 eV, 0.03 eV,i e sZ T T= = = 30.01, 10di s Zδ = = and the parameter dν is defined by the ratio of the characteristic length of potential decrease to the mean- free path of the absorption to dust particles: / / /ed e d z z e d d zn Tυ φν σ υ≡ < > . Fig. 3. Effects of dust particles ( Zd = 103 ) on the limit value of 1 22 / sz z cυ −−< > for the same parameters as Fig. 2 and / / /ed e d z z e d d zn Tυ φν σ υ≡ < > . In this case the limiting factor for injected ion flow velocity becomes 0.58, which is compared to the value of 0.48 without dust particles. IV. CONCLUDING REMARKS The effects of neutral and dust particles on monotonically changing electrostatic potential were investigated in quasi-neutral plasma with nonuniform magnetic field by using of one-dimensional kinetic analysis. It is clarified that plasma ion source, such as ionization of neutrals, mitigates the condition for the input flow velocity. For example, in case of Zi = 1, Te = 10 eV , and Ts = 0.03 eV and the density ratio of the generated ions to the electron density of 0.01 without dust particles, the injected ion flow velocity have to be larger than 0.48 cs. Please note that without neutrals this factor is 1.0, i.e. generalized Bohm’s criterion. Plasma ion sink, such as absorption to dust particles, increases this required ion flow velocity. In the same values of above plasma parameters and the density of dust particles with Zd = 103 to the electron density of 10-4, this limit factor increases from 0.48 to 0.58. The expanding magnetic field in the direction of the plate increases the required flow velocity. There are few future issues left: 1) Two-dimensional kinetic analysis has to be carried out in order to take into account of ion motion in divergence free magnetic field. 2) Other processes, such as Coulomb collisions, charge exchange collisions, should be included in this analysis. ACKNOWLEDGMENT This collaborated research was supported by the Heiwa- Nakajima Foundation. REFERENCES [1] A. Sagara, S. Masuzaki, et al., 15th International Conference on Plasma Surface Interactions in Controlled Fusion Devices, May 27 - 31, 2002, Gifu, Japan, Program and Book of Abstracts.- p. R-01 and P. Sharpe et al., ibid. p. P3-46. [2] G.A. Emmert, R.M. Wieland, A.T. Mense, and J.N. Davidson, Phys. Fluids, 23 (1980) 803. [3] R.C. Bissell and C. Johnson, and P.C. Stangeby, Phys. Fluids, B1 (1989) 1133. [4] D. Bohm, The Characteristics of Electrical Discharges in Magnetic Fields, edited by A. Guthrie and R.K. Wakerling ( McGraw-Hill, New York, 1949), Chap.4, p.77. [5] E.R. Harrison and W.B. Thompson, Proc. Phys. Soc. London, 74 (1959) 145. 41 0 0.2 0.4 0.6 0.8 1 0 0.002 0.004 0.006 0.008 0.01 ( 1 - δ i s ) / ( 1 + Z i T e δ i s / T s ) δ i s ( = Z i n i s / ne ) 0.2 0.22 0.24 0.26 0.28 0.3 0.32 0.34 0 0.2 0.4 0.6 0.8 1 1 - δ i s + Z d n d / n e Z i T e δ i s / T s - ν d n d / n e ( nd / ne ) / 10 -4 ν d = 10 4 103 National Institute for Fusion Science, Toki, Gifu 509-5292 Japan Taras Shevchenko Kiev University, Volodymyrs'ka 64, 252017 Kiev-17, Ukraine III. POTENTIAL FORMATION ACKNOWLEDGMENT REFERENCES

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