Ion temperature clamping in Wendelstein 7-X electron cyclotron heated plasmas

M. N.A. Beurskens; S. A. Bozhenkov; O. Ford; P. Xanthopoulos; A. Zocco; Y. Turkin; A. Alonso; C. Beidler; I. Calvo; D. Carralero; T. Estrada; G. Fuchert; O. Grulke; M. Hirsch; K. Ida; M. Jakubowski; C. Killer; M. Krychowiak; S. Kwak; S. Lazerson; A. Langenberg; R. Lunsford; N. Pablant; E. Pasch; A. Pavone; F. Reimold; Th Romba; A. Von Stechow; H. M. Smith; T. Windisch; M. Yoshinuma; D. Zhang; R. C. Wolf

doi:10.1088/1741-4326/ac1653

Ion temperature clamping in Wendelstein 7-X electron cyclotron heated plasmas

M. N.A. Beurskens
, S. A. Bozhenkov
, O. Ford
, P. Xanthopoulos
, A. Zocco
, Y. Turkin
, A. Alonso
, C. Beidler
, I. Calvo
, D. Carralero
, T. Estrada
, G. Fuchert
, O. Grulke
, M. Hirsch
, K. Ida
, M. Jakubowski
, C. Killer
, M. Krychowiak
, S. Kwak
, S. Lazerson

A. Langenberg, R. Lunsford, N. Pablant, E. Pasch, A. Pavone, F. Reimold, Th Romba, A. Von Stechow, H. M. Smith, T. Windisch, M. Yoshinuma, D. Zhang, R. C. Wolf

Research output: Contribution to journal › Article › peer-review

67 Scopus citations

Abstract

The neoclassical transport optimization of the Wendelstein 7-X stellarator has not resulted in the predicted high energy confinement of gas fueled electron-cyclotron-resonance-heated (ECRH) plasmas as modelled in (Turkin et al 2011 Phys. Plasmas 18 022505) due to high levels of turbulent heat transport observed in the experiments. The electron-turbulent-heat transport appears non-stiff and is of the electron temperature gradient (ETG)/ion temperature gradient (ITG) type (Weir et al 2021 Nucl. Fusion 61 056001). As a result, the electron temperature T e can be varied freely from 1 keV-10 keV within the range of P ECRH = 1-7 MW, with electron density n e values from 0.1-1.5 × 1020 m-3. By contrast, in combination with the broad electron-to-ion energy-exchange heating profile in ECRH plasmas, ion-turbulent-heat transport leads to clamping of the central ion temperature at T i ∼ 1.5 keV ± 0.2 keV. In a dedicated ECRH power scan at a constant density of n e = 7 × 1019 m-3, an apparent 'negative ion temperature profile stiffness' was found in the central plasma for (r/a < 0.5), in which the normalized gradient ∇T i/T i decreases with increasing ion heat flux. The experiment was conducted in helium, which has a higher radiative density limit compared to hydrogen, allowing a broader power scan. This 'negative stiffness' is due to a strong exacerbation of turbulent transport with an increasing ratio of T e/T i in this electron-heated plasma. This finding is consistent with electrostatic microinstabilities, such as ITG-driven turbulence. Theoretical calculations made by both linear and nonlinear gyro-kinetic simulations performed by the GENE code in the W7-X three-dimensional geometry show a strong enhancement of turbulence with an increasing ratio of T e/T i. The exacerbation of turbulence with increasing T e/T i is also found in tokamaks and inherently enhances ion heat transport in electron-heated plasmas. This finding strongly affects the prospects of future high-performance gas-fueled ECRH scenarios in W7-X and imposes a requirement for turbulence-suppression techniques.

Original language	English (US)
Article number	116072
Journal	Nuclear Fusion
Volume	61
Issue number	11
DOIs	https://doi.org/10.1088/1741-4326/ac1653
State	Published - Nov 2021

All Science Journal Classification (ASJC) codes

Nuclear and High Energy Physics
Condensed Matter Physics

Keywords

electron heated plasmas
ion heat transport
ion temperature clamping Electron cyclotron heating
neoclassically optimised stellarator
power balance
profile stiffness
turbulent transport

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10.1088/1741-4326/ac1653

Cite this

Beurskens, M. N. A., Bozhenkov, S. A., Ford, O., Xanthopoulos, P., Zocco, A., Turkin, Y., Alonso, A., Beidler, C., Calvo, I., Carralero, D., Estrada, T., Fuchert, G., Grulke, O., Hirsch, M., Ida, K., Jakubowski, M., Killer, C., Krychowiak, M., Kwak, S., ... Wolf, R. C. (2021). Ion temperature clamping in Wendelstein 7-X electron cyclotron heated plasmas. Nuclear Fusion, 61(11), Article 116072. https://doi.org/10.1088/1741-4326/ac1653

@article{991b4c2d8638409794a6fc67e2af265f,

title = "Ion temperature clamping in Wendelstein 7-X electron cyclotron heated plasmas",

abstract = "The neoclassical transport optimization of the Wendelstein 7-X stellarator has not resulted in the predicted high energy confinement of gas fueled electron-cyclotron-resonance-heated (ECRH) plasmas as modelled in (Turkin et al 2011 Phys. Plasmas 18 022505) due to high levels of turbulent heat transport observed in the experiments. The electron-turbulent-heat transport appears non-stiff and is of the electron temperature gradient (ETG)/ion temperature gradient (ITG) type (Weir et al 2021 Nucl. Fusion 61 056001). As a result, the electron temperature T e can be varied freely from 1 keV-10 keV within the range of P ECRH = 1-7 MW, with electron density n e values from 0.1-1.5 × 1020 m-3. By contrast, in combination with the broad electron-to-ion energy-exchange heating profile in ECRH plasmas, ion-turbulent-heat transport leads to clamping of the central ion temperature at T i ∼ 1.5 keV ± 0.2 keV. In a dedicated ECRH power scan at a constant density of n e = 7 × 1019 m-3, an apparent 'negative ion temperature profile stiffness' was found in the central plasma for (r/a < 0.5), in which the normalized gradient ∇T i/T i decreases with increasing ion heat flux. The experiment was conducted in helium, which has a higher radiative density limit compared to hydrogen, allowing a broader power scan. This 'negative stiffness' is due to a strong exacerbation of turbulent transport with an increasing ratio of T e/T i in this electron-heated plasma. This finding is consistent with electrostatic microinstabilities, such as ITG-driven turbulence. Theoretical calculations made by both linear and nonlinear gyro-kinetic simulations performed by the GENE code in the W7-X three-dimensional geometry show a strong enhancement of turbulence with an increasing ratio of T e/T i. The exacerbation of turbulence with increasing T e/T i is also found in tokamaks and inherently enhances ion heat transport in electron-heated plasmas. This finding strongly affects the prospects of future high-performance gas-fueled ECRH scenarios in W7-X and imposes a requirement for turbulence-suppression techniques.",

keywords = "electron heated plasmas, ion heat transport, ion temperature clamping Electron cyclotron heating, neoclassically optimised stellarator, power balance, profile stiffness, turbulent transport",

author = "Beurskens, \{M. N.A.\} and Bozhenkov, \{S. A.\} and O. Ford and P. Xanthopoulos and A. Zocco and Y. Turkin and A. Alonso and C. Beidler and I. Calvo and D. Carralero and T. Estrada and G. Fuchert and O. Grulke and M. Hirsch and K. Ida and M. Jakubowski and C. Killer and M. Krychowiak and S. Kwak and S. Lazerson and A. Langenberg and R. Lunsford and N. Pablant and E. Pasch and A. Pavone and F. Reimold and Th Romba and \{Von Stechow\}, A. and Smith, \{H. M.\} and T. Windisch and M. Yoshinuma and D. Zhang and Wolf, \{R. C.\}",

note = "Publisher Copyright: {\textcopyright} 2021 EURATOM.",

year = "2021",

month = nov,

doi = "10.1088/1741-4326/ac1653",

language = "English (US)",

volume = "61",

journal = "Nuclear Fusion",

issn = "0029-5515",

publisher = "IOP Publishing Ltd.",

number = "11",

}

Beurskens, MNA, Bozhenkov, SA, Ford, O, Xanthopoulos, P, Zocco, A, Turkin, Y, Alonso, A, Beidler, C, Calvo, I, Carralero, D, Estrada, T, Fuchert, G, Grulke, O, Hirsch, M, Ida, K, Jakubowski, M, Killer, C, Krychowiak, M, Kwak, S, Lazerson, S, Langenberg, A, Lunsford, R , Pablant, N, Pasch, E, Pavone, A, Reimold, F, Romba, T, Von Stechow, A, Smith, HM, Windisch, T, Yoshinuma, M, Zhang, D & Wolf, RC 2021, 'Ion temperature clamping in Wendelstein 7-X electron cyclotron heated plasmas', Nuclear Fusion, vol. 61, no. 11, 116072. https://doi.org/10.1088/1741-4326/ac1653

TY - JOUR

T1 - Ion temperature clamping in Wendelstein 7-X electron cyclotron heated plasmas

AU - Beurskens, M. N.A.

AU - Bozhenkov, S. A.

AU - Ford, O.

AU - Xanthopoulos, P.

AU - Zocco, A.

AU - Turkin, Y.

AU - Alonso, A.

AU - Beidler, C.

AU - Calvo, I.

AU - Carralero, D.

AU - Estrada, T.

AU - Fuchert, G.

AU - Grulke, O.

AU - Hirsch, M.

AU - Ida, K.

AU - Jakubowski, M.

AU - Killer, C.

AU - Krychowiak, M.

AU - Kwak, S.

AU - Lazerson, S.

AU - Langenberg, A.

AU - Lunsford, R.

AU - Pablant, N.

AU - Pasch, E.

AU - Pavone, A.

AU - Reimold, F.

AU - Romba, Th

AU - Von Stechow, A.

AU - Smith, H. M.

AU - Windisch, T.

AU - Yoshinuma, M.

AU - Zhang, D.

AU - Wolf, R. C.

PY - 2021/11

Y1 - 2021/11

N2 - The neoclassical transport optimization of the Wendelstein 7-X stellarator has not resulted in the predicted high energy confinement of gas fueled electron-cyclotron-resonance-heated (ECRH) plasmas as modelled in (Turkin et al 2011 Phys. Plasmas 18 022505) due to high levels of turbulent heat transport observed in the experiments. The electron-turbulent-heat transport appears non-stiff and is of the electron temperature gradient (ETG)/ion temperature gradient (ITG) type (Weir et al 2021 Nucl. Fusion 61 056001). As a result, the electron temperature T e can be varied freely from 1 keV-10 keV within the range of P ECRH = 1-7 MW, with electron density n e values from 0.1-1.5 × 1020 m-3. By contrast, in combination with the broad electron-to-ion energy-exchange heating profile in ECRH plasmas, ion-turbulent-heat transport leads to clamping of the central ion temperature at T i ∼ 1.5 keV ± 0.2 keV. In a dedicated ECRH power scan at a constant density of n e = 7 × 1019 m-3, an apparent 'negative ion temperature profile stiffness' was found in the central plasma for (r/a < 0.5), in which the normalized gradient ∇T i/T i decreases with increasing ion heat flux. The experiment was conducted in helium, which has a higher radiative density limit compared to hydrogen, allowing a broader power scan. This 'negative stiffness' is due to a strong exacerbation of turbulent transport with an increasing ratio of T e/T i in this electron-heated plasma. This finding is consistent with electrostatic microinstabilities, such as ITG-driven turbulence. Theoretical calculations made by both linear and nonlinear gyro-kinetic simulations performed by the GENE code in the W7-X three-dimensional geometry show a strong enhancement of turbulence with an increasing ratio of T e/T i. The exacerbation of turbulence with increasing T e/T i is also found in tokamaks and inherently enhances ion heat transport in electron-heated plasmas. This finding strongly affects the prospects of future high-performance gas-fueled ECRH scenarios in W7-X and imposes a requirement for turbulence-suppression techniques.

AB - The neoclassical transport optimization of the Wendelstein 7-X stellarator has not resulted in the predicted high energy confinement of gas fueled electron-cyclotron-resonance-heated (ECRH) plasmas as modelled in (Turkin et al 2011 Phys. Plasmas 18 022505) due to high levels of turbulent heat transport observed in the experiments. The electron-turbulent-heat transport appears non-stiff and is of the electron temperature gradient (ETG)/ion temperature gradient (ITG) type (Weir et al 2021 Nucl. Fusion 61 056001). As a result, the electron temperature T e can be varied freely from 1 keV-10 keV within the range of P ECRH = 1-7 MW, with electron density n e values from 0.1-1.5 × 1020 m-3. By contrast, in combination with the broad electron-to-ion energy-exchange heating profile in ECRH plasmas, ion-turbulent-heat transport leads to clamping of the central ion temperature at T i ∼ 1.5 keV ± 0.2 keV. In a dedicated ECRH power scan at a constant density of n e = 7 × 1019 m-3, an apparent 'negative ion temperature profile stiffness' was found in the central plasma for (r/a < 0.5), in which the normalized gradient ∇T i/T i decreases with increasing ion heat flux. The experiment was conducted in helium, which has a higher radiative density limit compared to hydrogen, allowing a broader power scan. This 'negative stiffness' is due to a strong exacerbation of turbulent transport with an increasing ratio of T e/T i in this electron-heated plasma. This finding is consistent with electrostatic microinstabilities, such as ITG-driven turbulence. Theoretical calculations made by both linear and nonlinear gyro-kinetic simulations performed by the GENE code in the W7-X three-dimensional geometry show a strong enhancement of turbulence with an increasing ratio of T e/T i. The exacerbation of turbulence with increasing T e/T i is also found in tokamaks and inherently enhances ion heat transport in electron-heated plasmas. This finding strongly affects the prospects of future high-performance gas-fueled ECRH scenarios in W7-X and imposes a requirement for turbulence-suppression techniques.

KW - electron heated plasmas

KW - ion heat transport

KW - ion temperature clamping Electron cyclotron heating

KW - neoclassically optimised stellarator

KW - power balance

KW - profile stiffness

KW - turbulent transport

UR - https://www.scopus.com/pages/publications/85112652782

UR - https://www.scopus.com/pages/publications/85112652782#tab=citedBy

U2 - 10.1088/1741-4326/ac1653

DO - 10.1088/1741-4326/ac1653

M3 - Article

AN - SCOPUS:85112652782

SN - 0029-5515

VL - 61

JO - Nuclear Fusion

JF - Nuclear Fusion

IS - 11

M1 - 116072

ER -

Ion temperature clamping in Wendelstein 7-X electron cyclotron heated plasmas

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