The main features of self-consistent pressure profile formation

Razumova, K.A.; Андреев, В. В.; Dnestrovskij, A. Yu.; Kislov, A. Ya.; Kirneva, N.; Лысенко, С. Е.; Pavlov, Yu.D.; Poznyak, V. I.; Shafranov, T.V.; Trukhina, E.V.; Zhuravlev, V. A.; Donné, A. J. H.; Hogeweij, G. M. D.

doi:10.1088/0741-3335/50/10/105004

Cited by 21 publications

(34 citation statements)

References 17 publications

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“…[17] and references therein). However, a systematic study of how their interplay produces the self-consistent steady-state from equation (13) has not yet been addressed in details. We will address this issue in the next sections using the linear limit of the theory, which is discussed in the following subsection.…”

Section: Gyrokinetic Evaluation Of Particle Transport Contributionsmentioning

confidence: 99%

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The role of ion and electron electrostatic turbulence in characterizing stationary particle transport in the core of tokamak plasmas

Fable¹,

Angioni

Sauter

2009

Plasma Phys. Control. Fusion

107

173

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Abstract. A general feature of particle transport in the core of Tokamak plasmas is that, when core particle sources are small, a stationary peaked density profile is provided by a balance of outward diffusion and inward convection, driven by either neoclassical or turbulent mechanisms. The turbulent contribution to the off-diagonal elements of the transport matrix is very sensitive on the type of dominant instability of the background turbulence. We present here a detailed quasilinear gyrokinetic analysis of stationary turbulent particle transport by means of analytical and numerical calculations to show how the actual parametric dependence of the stationary normalized density gradient can strongly vary between an Ion Temperature Gradient (ITG) dominated turbulence and a Trapped Electron Mode (TEM) dominated turbulence regime. It is also shown how the maximal achievable normalized density gradient is reached when the turbulence regime is in a mixed state. This result is interpreted as the interplay of different physical mechanisms arising from (linear) wave-particle resonances. The results presented here are addressed to interpret some of the still unresolved issue in interpreting known experimental results.

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Section: Gyrokinetic Evaluation Of Particle Transport Contributionsmentioning

confidence: 99%

“…The relative weight between the thermodiffusive part of the total normalized density gradient, namely −C T R/L Te , and the other contribution C P , is also changed with R/L Te . The temperature normalized gradients are set at: R/L Te = [5,7,9,11,13] and R/L Ti = [6, 9, 12]. > 0).…”

Section: Parameters Setmentioning

confidence: 99%

The role of ion and electron electrostatic turbulence in characterizing stationary particle transport in the core of tokamak plasmas

Fable¹,

Angioni

Sauter

2009

Plasma Phys. Control. Fusion

107

173

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“…The transport barrier formation near the low-order rational tori found numerically in Hamiltonian systems perturbed by a weak turbulent field at the large Kubo numbers, probably, may have some sort of relation to the transport barriers in fusion experiments (see, e.g., a review [4]). As was mentioned above there is a possible relation between the density of rational magnetic surfaces (or tori) and the transport of particles and energy, particularly, the transport barrier formation in fusion experiments, which has been already discussed in a number of papers [12][13][14][15][16][17][18][19][20][21][22][23][24][25]. Unlike qualitative arguments given in those works we have explicitly shown the formation of transport barriers in Hamiltonian systems by direct numerical calculations and explored the conditions at which such barriers are created.…”

Section: Discussionmentioning

confidence: 90%

“…7 in the whole region 0 < J < 1 for the large Kubo number K = 100 (a) and in the region 0.5 < J < 0.55 located near the rational tori ω = 1/3 for the several values of K = 1,2,5, and 100 (b). The values for the other parameters are chosen: q 0 = 0.8, q a = 5, γ ≡ 1, 20 n 50, and α = 5/6, which corresponds to the power spectrum |H mn | 2 ∼ n −5/3 , and the 1 The existence of gaps in the density of rational tori has been pointed out already in many above-mentioned works [15][16][17][18][19][20][21][22][23][24][25], however, no quantitative estimations have been presented. Moreover, I could not find the results obtained here in existing literature, although one could expect that this problem has been treated already in number theory or in other fields of physics.…”

Section: A Monotonic Profilementioning

confidence: 99%

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Chaotic transport in Hamiltonian systems perturbed by a weak turbulent wave field

Abdullaev

2011

Phys. Rev. E

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Chaotic transport in a Hamiltonian system perturbed by a weak turbulent wave field is studied. It is assumed that a turbulent wave field has a wide spectrum containing up to thousands of modes whose phases are fluctuating in time with a finite correlation time. To integrate the Hamiltonian equations a fast symplectic mapping is derived. It has a large time-step equal to one full turn in angle variable. It is found that the chaotic transport across tori caused by the interactions of small-scale resonances have a fractal-like structure with the reduced or zero values of diffusion coefficients near low-order rational tori thereby forming transport barriers there. The density of rational tori is numerically calculated and its properties are investigated. It is shown that the transport barriers are formed in the gaps of the density of rational tori near the low-order rational tori. The dependencies of the depth and width of transport barriers on the wave field spectrum and the correlation time of fluctuating turbulent field (or the Kubo number) are studied. These numerical findings may have importance in understanding the mechanisms of transport barrier formation in fusion plasmas.

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New mechanism of runaway electron diffusion due to microturbulence in tokamaks

2012

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Chaotic transport of runaway electrons in a toroidal system in the presence of a weak small-scale magnetic turbulent field with a wide mode spectrum is studied. Using a fast running mapping, the radial profiles of turbulent diffusion coefficients are calculated. It is found that at large Kubo numbers the chaotic transport of the electrons is described by a fractal-like radial dependence of the diffusion coefficients with reduced or zero values near low-order rational drift surfaces which form transport barriers. The latter can be one of the main reasons of the improved confinement of runaway electrons in tokamaks. One can expect that this effect may lead to the formation of the nested beams of runaway electrons. [http://dx

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The main features of self-consistent pressure profile formation

Cited by 21 publications

References 17 publications

The role of ion and electron electrostatic turbulence in characterizing stationary particle transport in the core of tokamak plasmas

The role of ion and electron electrostatic turbulence in characterizing stationary particle transport in the core of tokamak plasmas

Chaotic transport in Hamiltonian systems perturbed by a weak turbulent wave field

New mechanism of runaway electron diffusion due to microturbulence in tokamaks

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