Grassy-ELM regime with edge resonant magnetic perturbations in fully noninductive plasmas in the DIII-D tokamak

R. Nazikian; C. C. Petty; A. Bortolon; Xi Chen; D. Eldon; T. E. Evans; B. A. Grierson; N. M. Ferraro; S. R. Haskey; M. Knolker; C. Lasnier; N. C. Logan; R. A. Moyer; D. Orlov; T. H. Osborne; C. Paz-Soldan; F. Turco; H. Q. Wang; D. B. Weisberg

doi:10.1088/1741-4326/aad20d

Grassy-ELM regime with edge resonant magnetic perturbations in fully noninductive plasmas in the DIII-D tokamak

R. Nazikian
, C. C. Petty
, A. Bortolon
, Xi Chen
, D. Eldon
, T. E. Evans
, B. A. Grierson
, N. M. Ferraro
, S. R. Haskey
, M. Knolker
, C. Lasnier
, N. C. Logan
, R. A. Moyer
, D. Orlov
, T. H. Osborne
, C. Paz-Soldan
, F. Turco
, H. Q. Wang
, D. B. Weisberg

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

52 Scopus citations

Abstract

Resonant magnetic perturbations (n = 3 RMPs) are used to suppress large amplitude ELMs and mitigate naturally occurring 'grassy'-ELMs in DIII-D plasmas relevant to the ITER steady-state mission. Fully non-inductive discharges in the ITER shape and pedestal collisionality (n^∗ _e ≈ 0.05-0.15) are routinely achieved in DIII-D with RMP suppression of the Type-I ELMs. The residual grassy-ELMs deliver a low peak heat flux to the divertor as low as 1.2× the inter-ELM heat flux in plasmas with sustained high H-factor (H _98y2 ≈ 1.2). The operating window for the RMP grassy-ELM regime is q ₉₅ = 5.3-7.1 and external torque in the range 9-0.7 Nm in the co-Ip direction, which is in the range required for a steady-state tokamak reactor. The RMP grassy-ELM regime is associated with a two-step pedestal, with strong flattening of the density around the zero crossing in the E × B shear. The edge magnetic response of the plasma to the n = 3 RMP is found to be ≈2-3× larger than for comparable ITER baseline plasmas (β _N ≈ 1.8, q ₉₅ ≈ 3.1). The amplification of the RMP is consistent with the weak magnetic perturbation level (δB/B ≈ 1 × 10^-4) required for effective Type-I ELM suppression. Cyclic variations in the pedestal pressure, width, and toroidal rotation are observed in these plasmas, correlated with cyclic variations in the strength and frequency of the grassy-ELMs. Extended MHD analysis and magnetic measurements indicate that these pedestal pulsations are driven by cyclic variations in the resonant field strength at the top of the pedestal. These pedestal pulsations reveal that the grassy-ELMs is correlated with the proximity of the pedestal to the low-n peeling-ballooning mode stability boundary. The use of low amplitude magnetic fields to access grassy-ELM conditions free of Type-I ELMs in high beta poloidal plasmas (β _P ≈ 1.5-2.0) opens the possibility for the further optimization of the steady-state tokamak by use of edge resonant magnetic perturbations.

Original language	English (US)
Article number	106010
Journal	Nuclear Fusion
Volume	58
Issue number	10
DOIs	https://doi.org/10.1088/1741-4326/aad20d
State	Published - Jul 27 2018

All Science Journal Classification (ASJC) codes

Nuclear and High Energy Physics
Condensed Matter Physics

Keywords

ELM
pedestal
RMP

Access to Document

10.1088/1741-4326/aad20d

Cite this

Nazikian, R., Petty, C. C., Bortolon, A., Chen, X., Eldon, D., Evans, T. E., Grierson, B. A., Ferraro, N. M., Haskey, S. R., Knolker, M., Lasnier, C., Logan, N. C., Moyer, R. A., Orlov, D., Osborne, T. H., Paz-Soldan, C., Turco, F., Wang, H. Q., & Weisberg, D. B. (2018). Grassy-ELM regime with edge resonant magnetic perturbations in fully noninductive plasmas in the DIII-D tokamak. Nuclear Fusion, 58(10), Article 106010. https://doi.org/10.1088/1741-4326/aad20d

@article{cb610a3305494f6db7f2670b4615e6bc,

title = "Grassy-ELM regime with edge resonant magnetic perturbations in fully noninductive plasmas in the DIII-D tokamak",

abstract = "Resonant magnetic perturbations (n = 3 RMPs) are used to suppress large amplitude ELMs and mitigate naturally occurring 'grassy'-ELMs in DIII-D plasmas relevant to the ITER steady-state mission. Fully non-inductive discharges in the ITER shape and pedestal collisionality (n∗ e ≈ 0.05-0.15) are routinely achieved in DIII-D with RMP suppression of the Type-I ELMs. The residual grassy-ELMs deliver a low peak heat flux to the divertor as low as 1.2× the inter-ELM heat flux in plasmas with sustained high H-factor (H 98y2 ≈ 1.2). The operating window for the RMP grassy-ELM regime is q 95 = 5.3-7.1 and external torque in the range 9-0.7 Nm in the co-Ip direction, which is in the range required for a steady-state tokamak reactor. The RMP grassy-ELM regime is associated with a two-step pedestal, with strong flattening of the density around the zero crossing in the E × B shear. The edge magnetic response of the plasma to the n = 3 RMP is found to be ≈2-3× larger than for comparable ITER baseline plasmas (β N ≈ 1.8, q 95 ≈ 3.1). The amplification of the RMP is consistent with the weak magnetic perturbation level (δB/B ≈ 1 × 10-4) required for effective Type-I ELM suppression. Cyclic variations in the pedestal pressure, width, and toroidal rotation are observed in these plasmas, correlated with cyclic variations in the strength and frequency of the grassy-ELMs. Extended MHD analysis and magnetic measurements indicate that these pedestal pulsations are driven by cyclic variations in the resonant field strength at the top of the pedestal. These pedestal pulsations reveal that the grassy-ELMs is correlated with the proximity of the pedestal to the low-n peeling-ballooning mode stability boundary. The use of low amplitude magnetic fields to access grassy-ELM conditions free of Type-I ELMs in high beta poloidal plasmas (β P ≈ 1.5-2.0) opens the possibility for the further optimization of the steady-state tokamak by use of edge resonant magnetic perturbations.",

keywords = "ELM, pedestal, RMP",

author = "R. Nazikian and Petty, \{C. C.\} and A. Bortolon and Xi Chen and D. Eldon and Evans, \{T. E.\} and Grierson, \{B. A.\} and Ferraro, \{N. M.\} and Haskey, \{S. R.\} and M. Knolker and C. Lasnier and Logan, \{N. C.\} and Moyer, \{R. A.\} and D. Orlov and Osborne, \{T. H.\} and C. Paz-Soldan and F. Turco and Wang, \{H. Q.\} and Weisberg, \{D. B.\}",

note = "Publisher Copyright: {\textcopyright} 2018 IAEA, Vienna.",

year = "2018",

month = jul,

day = "27",

doi = "10.1088/1741-4326/aad20d",

language = "English (US)",

volume = "58",

journal = "Nuclear Fusion",

issn = "0029-5515",

publisher = "IOP Publishing Ltd.",

number = "10",

}

Nazikian, R, Petty, CC, Bortolon, A, Chen, X, Eldon, D, Evans, TE, Grierson, BA, Ferraro, NM , Haskey, SR, Knolker, M, Lasnier, C, Logan, NC, Moyer, RA, Orlov, D, Osborne, TH, Paz-Soldan, C, Turco, F, Wang, HQ & Weisberg, DB 2018, 'Grassy-ELM regime with edge resonant magnetic perturbations in fully noninductive plasmas in the DIII-D tokamak', Nuclear Fusion, vol. 58, no. 10, 106010. https://doi.org/10.1088/1741-4326/aad20d

TY - JOUR

T1 - Grassy-ELM regime with edge resonant magnetic perturbations in fully noninductive plasmas in the DIII-D tokamak

AU - Nazikian, R.

AU - Petty, C. C.

AU - Bortolon, A.

AU - Chen, Xi

AU - Eldon, D.

AU - Evans, T. E.

AU - Grierson, B. A.

AU - Ferraro, N. M.

AU - Haskey, S. R.

AU - Knolker, M.

AU - Lasnier, C.

AU - Logan, N. C.

AU - Moyer, R. A.

AU - Orlov, D.

AU - Osborne, T. H.

AU - Paz-Soldan, C.

AU - Turco, F.

AU - Wang, H. Q.

AU - Weisberg, D. B.

PY - 2018/7/27

Y1 - 2018/7/27

N2 - Resonant magnetic perturbations (n = 3 RMPs) are used to suppress large amplitude ELMs and mitigate naturally occurring 'grassy'-ELMs in DIII-D plasmas relevant to the ITER steady-state mission. Fully non-inductive discharges in the ITER shape and pedestal collisionality (n∗ e ≈ 0.05-0.15) are routinely achieved in DIII-D with RMP suppression of the Type-I ELMs. The residual grassy-ELMs deliver a low peak heat flux to the divertor as low as 1.2× the inter-ELM heat flux in plasmas with sustained high H-factor (H 98y2 ≈ 1.2). The operating window for the RMP grassy-ELM regime is q 95 = 5.3-7.1 and external torque in the range 9-0.7 Nm in the co-Ip direction, which is in the range required for a steady-state tokamak reactor. The RMP grassy-ELM regime is associated with a two-step pedestal, with strong flattening of the density around the zero crossing in the E × B shear. The edge magnetic response of the plasma to the n = 3 RMP is found to be ≈2-3× larger than for comparable ITER baseline plasmas (β N ≈ 1.8, q 95 ≈ 3.1). The amplification of the RMP is consistent with the weak magnetic perturbation level (δB/B ≈ 1 × 10-4) required for effective Type-I ELM suppression. Cyclic variations in the pedestal pressure, width, and toroidal rotation are observed in these plasmas, correlated with cyclic variations in the strength and frequency of the grassy-ELMs. Extended MHD analysis and magnetic measurements indicate that these pedestal pulsations are driven by cyclic variations in the resonant field strength at the top of the pedestal. These pedestal pulsations reveal that the grassy-ELMs is correlated with the proximity of the pedestal to the low-n peeling-ballooning mode stability boundary. The use of low amplitude magnetic fields to access grassy-ELM conditions free of Type-I ELMs in high beta poloidal plasmas (β P ≈ 1.5-2.0) opens the possibility for the further optimization of the steady-state tokamak by use of edge resonant magnetic perturbations.

AB - Resonant magnetic perturbations (n = 3 RMPs) are used to suppress large amplitude ELMs and mitigate naturally occurring 'grassy'-ELMs in DIII-D plasmas relevant to the ITER steady-state mission. Fully non-inductive discharges in the ITER shape and pedestal collisionality (n∗ e ≈ 0.05-0.15) are routinely achieved in DIII-D with RMP suppression of the Type-I ELMs. The residual grassy-ELMs deliver a low peak heat flux to the divertor as low as 1.2× the inter-ELM heat flux in plasmas with sustained high H-factor (H 98y2 ≈ 1.2). The operating window for the RMP grassy-ELM regime is q 95 = 5.3-7.1 and external torque in the range 9-0.7 Nm in the co-Ip direction, which is in the range required for a steady-state tokamak reactor. The RMP grassy-ELM regime is associated with a two-step pedestal, with strong flattening of the density around the zero crossing in the E × B shear. The edge magnetic response of the plasma to the n = 3 RMP is found to be ≈2-3× larger than for comparable ITER baseline plasmas (β N ≈ 1.8, q 95 ≈ 3.1). The amplification of the RMP is consistent with the weak magnetic perturbation level (δB/B ≈ 1 × 10-4) required for effective Type-I ELM suppression. Cyclic variations in the pedestal pressure, width, and toroidal rotation are observed in these plasmas, correlated with cyclic variations in the strength and frequency of the grassy-ELMs. Extended MHD analysis and magnetic measurements indicate that these pedestal pulsations are driven by cyclic variations in the resonant field strength at the top of the pedestal. These pedestal pulsations reveal that the grassy-ELMs is correlated with the proximity of the pedestal to the low-n peeling-ballooning mode stability boundary. The use of low amplitude magnetic fields to access grassy-ELM conditions free of Type-I ELMs in high beta poloidal plasmas (β P ≈ 1.5-2.0) opens the possibility for the further optimization of the steady-state tokamak by use of edge resonant magnetic perturbations.

KW - ELM

KW - pedestal

KW - RMP

UR - https://www.scopus.com/pages/publications/85052588246

UR - https://www.scopus.com/pages/publications/85052588246#tab=citedBy

U2 - 10.1088/1741-4326/aad20d

DO - 10.1088/1741-4326/aad20d

M3 - Article

AN - SCOPUS:85052588246

SN - 0029-5515

VL - 58

JO - Nuclear Fusion

JF - Nuclear Fusion

IS - 10

M1 - 106010

ER -

Grassy-ELM regime with edge resonant magnetic perturbations in fully noninductive plasmas in the DIII-D tokamak

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