Power exhaust concepts and divertor designs for Japanese and European DEMO fusion reactors

Asakura, N.; Hoshino, Kazuo; Kakudate, Satoshi; Subba, F.; Vorpahl, C.; Homma, Y.; Utoh, Hiroyasu; Someya, Youji; Sakamoto, Y.; Hiwatari, Ryoji; Suzuki, Satoshi; You, J.-H.; Siccinio, M.; Federici, G.

doi:10.1088/1741-4326/ac2ff4

Cited by 24 publications

(13 citation statements)

References 39 publications

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“…The anomalous diffusion coefficient

{D}_{\mathrm{a}}

is 0.3 m 2 s −1 with reference to other previous works. [ 24–26 ] On the other hand, in case B, although the velocity is calculated from Equations (1) and (2), the movement of guiding center in the direction perpendicular to magnetic fields is ignored. In other words, Equation (3) is not used.…”

Section: Analysis Modelmentioning

confidence: 99%

“…The background plasma parameters, including plasma density

{n}_{\mathrm{i}}

, ion temperature

{T}_{\mathrm{i}}

, and electron temperature

{T}_{\mathrm{e}}

, are fixed at 1 × 10 20 m −3 , 50 eV, and 50 eV, respectively, based on the SONIC simulation results. [ 25,26 ] These are the values at the divertor plate of JA DEMO reactor near a peak of heat load. Temperature and density plateaued in a width of about a few cm; hence, the background values are chosen as representative conditions.…”

Section: Analysis Modelmentioning

confidence: 99%

“…Enhancement of the radial transport by the large-angle elastic scattering may improve the result and also may affect design study of JA DEMO reactor. [25,26] In the SOLPS code, the large-angle elastic scattering is taken into account. However, how the elastic scattering affects the plasma transport in the direction perpendicular to magnetic field lines, especially in the detachment, has not been investigated in detail.…”

Section: Introductionmentioning

confidence: 99%

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Effect of elastic scattering between ions and neutral particles on ion transport perpendicular to magnetic fields in divertor plasmas

Umezaki,

Matsuura,

Hoshino

2023

Contributions to Plasma Physics

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In divertor plasmas, atomic processes play a significant role in reducing the divertor heat load. In particular, the elastic scattering between ions and neutral particles can be characterized as a large‐angle scattering; this is in contrast with Coulomb scattering, which is dominated by small‐angle scattering. In a large‐angle scattering, a large fraction of the ion energy is transferred to the neutral particle, and the particle flight direction can be changed significantly. This process can generate additional particle transport perpendicular to magnetic field lines and affect plasma density profile in neutral‐rich divertor regions. However, in most edge plasma simulation codes, the elastic scattering with neutral particles is not taken into account in the direction perpendicular to the magnetic field lines. In this study, we performed a 2D orbital calculation without other drifts such as diamagnetic and E × B drifts to assess the effect of the elastic scattering on the density profile. The peak density is found to be decreased by 11.1 (6.3)% compared with the model that ignores the transport due to the elastic scattering, even at 3.0 (5.0) T magnetic field similar to that of the JT‐60SA (JA DEMO reactor) class. In addition, the ion transport can be expressed as a diffusion model by integrating the differential cross section over the large‐angle scattering range . The proposed method may be easily introduced into any integrated codes to consider the elastic scattering.

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“…The anomalous diffusion coefficient

{D}_{\mathrm{a}}

Section: Analysis Modelmentioning

confidence: 99%

“…The background plasma parameters, including plasma density

{n}_{\mathrm{i}}

, ion temperature

{T}_{\mathrm{i}}

, and electron temperature

{T}_{\mathrm{e}}

Section: Analysis Modelmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Effect of elastic scattering between ions and neutral particles on ion transport perpendicular to magnetic fields in divertor plasmas

Umezaki,

Matsuura,

Hoshino

2023

Contributions to Plasma Physics

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“…It will be operated on a maximum fusion power of 500 MW [1,2]. Further demonstration reactors for power plants are under design [3][4][5][6][7]. Various design and material irradiation experiments are required to perform to support nuclear fusion power plants.…”

Section: Introductionmentioning

confidence: 99%

Physics design of 14 MeV neutron generator facility at the Institute for Plasma Research

Swami

2023

Plasma Sci. Technol.

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High energy and high yield neutron source is a prime requirement for technological studies related to fusion reactor development. It provides the high energy neutron environment for small-scale fusion reactor components research and testing such as tritium breeding, shielding, plasma-facing materials, reaction cross-section data study for fusion materials, etc. Along with ITER participation, the Institute of Plasma Research, India is developing an accelerator-based 14 MeV neutron source with a yield of 1012 n/s. The design of the source is based on the deuterium-tritium fusion reaction. The deuterium beam is accelerated and delivered to the tritium target to generate the 14 MeV neutrons. The deuterium beam energy and tritium availability in tritium target are the base parameters of the accelerator-based neutron source design. The paper gives the physics design of the neutron generator facility of IPR. It covers the requirements, design basis, and physics parameters of the neutron generator. As per the analytical results generator can produce more than 1x1012 n/s with a 110 keV D+ ion beam of 10 mA and a minimum 5 Ci tritium target. However, the detailed simulation with more realistic condition of deuteron ion interaction with tritium titanium target shows that the desired results cannot be achieved with 110 keV. The safe limit of the ion energy should be 300 keV as per simulation. At the 300 keV ion energy and 20 mA current, it reaches to the 1.6x1012 n/s. Moreover, to enhance the duration of steady state emission rate, the design parameters considered for the generator are 300 keV D+ ion beam with current of 20 mA and tritium target more than 20 Ci. The scope of the neutron source is not limited to the fusion reactor research studies, it is extended to the other area such as medical radioisotopes research, semiconductor devices irradiations, and many more.

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“…This can help to decrease the power flux density and electron temperature on divertor targets and prevent tungsten sputtering. Several publications, such as [2][3][4], explore possible impurity seeding and deuterium puffing rates to achieve conditions with electron temperatures and power flux density below 5 eV and 5 MW m −2 , respectively. However, until now, such modeling for EU-DEMO was performed without drifts or without kinetic neutrals.…”

Section: Introductionmentioning

confidence: 99%

SOLPS-ITER modeling of EU-DEMO Ar-seeded cases with drifts and kinetic neutrals

Korzueva,

Kaveeva,

Vekshina

et al. 2023

Plasma Phys. Control. Fusion

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SOLPS-ITER modeling of EU-DEMO tokamak burning plasma with Ar seeding was performed. The modeling includes drifts, kinetic neutrals and current description switched on. Simulation results are compared with ones without drifts. Power entering the edge plasma domain is 200 MW. Deuterium puff is 1.5E23 at/s for all cases, which corresponds to neutral deuterium pressure 10 Pa in the private flux region. Ar seeding rates are 8.0E19 at/s and 1.5E19 at/s, which corresponds to argon concentration on the separatrix in the range of 0.5-2\%. It's demonstrated that with such combination of parameters it's possible to achieve power loads lower than 5 MW/m^2 on both divertor targets. The temperature above 5 eV in the far SOL of the outer target still remains an issue. Along with drift and no drift cases, impurity accumulation mechanism in the high field side SOL is discussed.

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Power exhaust concepts and divertor designs for Japanese and European DEMO fusion reactors

Cited by 24 publications

References 39 publications

Effect of elastic scattering between ions and neutral particles on ion transport perpendicular to magnetic fields in divertor plasmas

Effect of elastic scattering between ions and neutral particles on ion transport perpendicular to magnetic fields in divertor plasmas

Physics design of 14 MeV neutron generator facility at the Institute for Plasma Research

SOLPS-ITER modeling of EU-DEMO Ar-seeded cases with drifts and kinetic neutrals

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