Overview of results from the 2023 DIII-D negative triangularity campaign

K. E. Thome; M. E. Austin; A. Hyatt; A. Marinoni; A. O. Nelson; C. Paz-Soldan; F. Scotti; W. Boyes; L. Casali; C. Chrystal; S. Ding; X. D. Du; D. Eldon; D. Ernst; R. Hong; G. R. McKee; S. Mordijck; O. Sauter; L. Schmitz; J. L. Barr; M. G. Burke; S. Coda; T. B. Cote; M. E. Fenstermacher; A. Garofalo; F. O. Khabanov; G. J. Kramer; C. J. Lasnier; N. C. Logan; P. Lunia; A. G. McLean; M. Okabayashi; D. Shiraki; S. Stewart; Y. Takemura; D. D. Truong; T. Osborne; M. A. Van Zeeland; B. S. Victor; H. Q. Wang; J. G. Watkins; W. P. Wehner; A. S. Welander; T. M. Wilks; J. Yang; G. Yu; L. Zeng

doi:10.1088/1361-6587/ad6f40

Overview of results from the 2023 DIII-D negative triangularity campaign

K. E. Thome
, M. E. Austin
, A. Hyatt
, A. Marinoni
, A. O. Nelson
, C. Paz-Soldan
, F. Scotti
, W. Boyes
, L. Casali
, C. Chrystal
, S. Ding
, X. D. Du
, D. Eldon
, D. Ernst
, R. Hong
, G. R. McKee
, S. Mordijck
, O. Sauter
, L. Schmitz
, J. L. Barr

M. G. Burke, S. Coda, T. B. Cote, M. E. Fenstermacher, A. Garofalo, F. O. Khabanov, G. J. Kramer, C. J. Lasnier, N. C. Logan, P. Lunia, A. G. McLean, M. Okabayashi, D. Shiraki, S. Stewart, Y. Takemura, D. D. Truong, T. Osborne, M. A. Van Zeeland, B. S. Victor, H. Q. Wang, J. G. Watkins, W. P. Wehner, A. S. Welander, T. M. Wilks, J. Yang, G. Yu, L. Zeng

Research output: Contribution to journal › Review article › peer-review

21 Scopus citations

Abstract

Negative triangularity (NT) is a potentially transformative configuration for tokamak-based fusion energy with its high-performance core, edge localized mode (ELM)-free edge, and low-field-side divertors that could readily scale to an integrated reactor solution. Previous NT work on the TCV and DIII-D tokamaks motivated the installation of graphite-tile armor on the low-field-side lower outer wall of DIII-D. A dedicated multiple-week experimental campaign was conducted to qualify the NT scenario for future reactors. During the DIII-D NT campaign, high confinement ( H 98 y , 2 ≳ 1), high current ( q 95 < 3), and high normalized pressure plasmas ( β N > 2.5) were simultaneously attained in strongly NT-shaped discharges with average triangularity δ avg = −0.5 that were stably controlled. Experiments covered a wide range of DIII-D operational space (plasma current, toroidal field, electron density and pressure) and did not trigger an ELM in a single discharge as long as sufficiently strong NT was maintained; in contrast, to other high-performance ELM-suppression scenarios that have narrower operating windows. These strong NT plasmas had a lower outer divertor X-point shape and maintained a non-ELMing edge with an electron temperature pedestal, exceeding that of typical L-mode plasmas. Also, the following was achieved during the campaign: high normalized density ( n e / n GW of at least 1.7), particle confinement comparable to energy confinement with Z eff ∼ 2 , a detached divertor without impurity seeding, and a mantle radiation scenario using extrinsic impurities. These results are promising for a NT fusion pilot plant but further questions on confinement extrapolation and core-edge integration remain, which motivate future NT studies on DIII-D and beyond.

Original language	English (US)
Article number	105018
Journal	Plasma Physics and Controlled Fusion
Volume	66
Issue number	10
DOIs	https://doi.org/10.1088/1361-6587/ad6f40
State	Published - Oct 1 2024

All Science Journal Classification (ASJC) codes

Nuclear Energy and Engineering
Condensed Matter Physics

Keywords

NT edge
confinement
negative triangularity

Access to Document

10.1088/1361-6587/ad6f40

Cite this

Thome, K. E., Austin, M. E., Hyatt, A., Marinoni, A., Nelson, A. O., Paz-Soldan, C., Scotti, F., Boyes, W., Casali, L., Chrystal, C., Ding, S., Du, X. D., Eldon, D., Ernst, D., Hong, R., McKee, G. R., Mordijck, S., Sauter, O., Schmitz, L., ... Zeng, L. (2024). Overview of results from the 2023 DIII-D negative triangularity campaign. Plasma Physics and Controlled Fusion, 66(10), Article 105018. https://doi.org/10.1088/1361-6587/ad6f40

@article{6066e415a235495b886ecfaea67158c9,

title = "Overview of results from the 2023 DIII-D negative triangularity campaign",

abstract = "Negative triangularity (NT) is a potentially transformative configuration for tokamak-based fusion energy with its high-performance core, edge localized mode (ELM)-free edge, and low-field-side divertors that could readily scale to an integrated reactor solution. Previous NT work on the TCV and DIII-D tokamaks motivated the installation of graphite-tile armor on the low-field-side lower outer wall of DIII-D. A dedicated multiple-week experimental campaign was conducted to qualify the NT scenario for future reactors. During the DIII-D NT campaign, high confinement ( H 98 y , 2 ≳ 1), high current ( q 95 < 3), and high normalized pressure plasmas ( β N > 2.5) were simultaneously attained in strongly NT-shaped discharges with average triangularity δ avg = −0.5 that were stably controlled. Experiments covered a wide range of DIII-D operational space (plasma current, toroidal field, electron density and pressure) and did not trigger an ELM in a single discharge as long as sufficiently strong NT was maintained; in contrast, to other high-performance ELM-suppression scenarios that have narrower operating windows. These strong NT plasmas had a lower outer divertor X-point shape and maintained a non-ELMing edge with an electron temperature pedestal, exceeding that of typical L-mode plasmas. Also, the following was achieved during the campaign: high normalized density ( n e / n GW of at least 1.7), particle confinement comparable to energy confinement with Z eff ∼ 2 , a detached divertor without impurity seeding, and a mantle radiation scenario using extrinsic impurities. These results are promising for a NT fusion pilot plant but further questions on confinement extrapolation and core-edge integration remain, which motivate future NT studies on DIII-D and beyond.",

keywords = "NT edge, confinement, negative triangularity",

author = "Thome, \{K. E.\} and Austin, \{M. E.\} and A. Hyatt and A. Marinoni and Nelson, \{A. O.\} and C. Paz-Soldan and F. Scotti and W. Boyes and L. Casali and C. Chrystal and S. Ding and Du, \{X. D.\} and D. Eldon and D. Ernst and R. Hong and McKee, \{G. R.\} and S. Mordijck and O. Sauter and L. Schmitz and Barr, \{J. L.\} and Burke, \{M. G.\} and S. Coda and Cote, \{T. B.\} and Fenstermacher, \{M. E.\} and A. Garofalo and Khabanov, \{F. O.\} and Kramer, \{G. J.\} and Lasnier, \{C. J.\} and Logan, \{N. C.\} and P. Lunia and McLean, \{A. G.\} and M. Okabayashi and D. Shiraki and S. Stewart and Y. Takemura and Truong, \{D. D.\} and T. Osborne and \{Van Zeeland\}, \{M. A.\} and Victor, \{B. S.\} and Wang, \{H. Q.\} and Watkins, \{J. G.\} and Wehner, \{W. P.\} and Welander, \{A. S.\} and Wilks, \{T. M.\} and J. Yang and G. Yu and L. Zeng",

note = "Publisher Copyright: {\textcopyright} 2024 The Author(s). Published by IOP Publishing Ltd.",

year = "2024",

month = oct,

day = "1",

doi = "10.1088/1361-6587/ad6f40",

language = "English (US)",

volume = "66",

journal = "Plasma Physics and Controlled Fusion",

issn = "0741-3335",

publisher = "IOP Publishing Ltd.",

number = "10",

}

Thome, KE, Austin, ME, Hyatt, A, Marinoni, A, Nelson, AO, Paz-Soldan, C, Scotti, F, Boyes, W, Casali, L, Chrystal, C, Ding, S, Du, XD, Eldon, D, Ernst, D, Hong, R, McKee, GR, Mordijck, S, Sauter, O, Schmitz, L, Barr, JL, Burke, MG, Coda, S, Cote, TB, Fenstermacher, ME, Garofalo, A, Khabanov, FO, Kramer, GJ, Lasnier, CJ, Logan, NC, Lunia, P, McLean, AG, Okabayashi, M, Shiraki, D, Stewart, S, Takemura, Y, Truong, DD, Osborne, T, Van Zeeland, MA, Victor, BS, Wang, HQ, Watkins, JG, Wehner, WP, Welander, AS, Wilks, TM, Yang, J, Yu, G & Zeng, L 2024, 'Overview of results from the 2023 DIII-D negative triangularity campaign', Plasma Physics and Controlled Fusion, vol. 66, no. 10, 105018. https://doi.org/10.1088/1361-6587/ad6f40

TY - JOUR

T1 - Overview of results from the 2023 DIII-D negative triangularity campaign

AU - Thome, K. E.

AU - Austin, M. E.

AU - Hyatt, A.

AU - Marinoni, A.

AU - Nelson, A. O.

AU - Paz-Soldan, C.

AU - Scotti, F.

AU - Boyes, W.

AU - Casali, L.

AU - Chrystal, C.

AU - Ding, S.

AU - Du, X. D.

AU - Eldon, D.

AU - Ernst, D.

AU - Hong, R.

AU - McKee, G. R.

AU - Mordijck, S.

AU - Sauter, O.

AU - Schmitz, L.

AU - Barr, J. L.

AU - Burke, M. G.

AU - Coda, S.

AU - Cote, T. B.

AU - Fenstermacher, M. E.

AU - Garofalo, A.

AU - Khabanov, F. O.

AU - Kramer, G. J.

AU - Lasnier, C. J.

AU - Logan, N. C.

AU - Lunia, P.

AU - McLean, A. G.

AU - Okabayashi, M.

AU - Shiraki, D.

AU - Stewart, S.

AU - Takemura, Y.

AU - Truong, D. D.

AU - Osborne, T.

AU - Van Zeeland, M. A.

AU - Victor, B. S.

AU - Wang, H. Q.

AU - Watkins, J. G.

AU - Wehner, W. P.

AU - Welander, A. S.

AU - Wilks, T. M.

AU - Yang, J.

AU - Yu, G.

AU - Zeng, L.

PY - 2024/10/1

Y1 - 2024/10/1

N2 - Negative triangularity (NT) is a potentially transformative configuration for tokamak-based fusion energy with its high-performance core, edge localized mode (ELM)-free edge, and low-field-side divertors that could readily scale to an integrated reactor solution. Previous NT work on the TCV and DIII-D tokamaks motivated the installation of graphite-tile armor on the low-field-side lower outer wall of DIII-D. A dedicated multiple-week experimental campaign was conducted to qualify the NT scenario for future reactors. During the DIII-D NT campaign, high confinement ( H 98 y , 2 ≳ 1), high current ( q 95 < 3), and high normalized pressure plasmas ( β N > 2.5) were simultaneously attained in strongly NT-shaped discharges with average triangularity δ avg = −0.5 that were stably controlled. Experiments covered a wide range of DIII-D operational space (plasma current, toroidal field, electron density and pressure) and did not trigger an ELM in a single discharge as long as sufficiently strong NT was maintained; in contrast, to other high-performance ELM-suppression scenarios that have narrower operating windows. These strong NT plasmas had a lower outer divertor X-point shape and maintained a non-ELMing edge with an electron temperature pedestal, exceeding that of typical L-mode plasmas. Also, the following was achieved during the campaign: high normalized density ( n e / n GW of at least 1.7), particle confinement comparable to energy confinement with Z eff ∼ 2 , a detached divertor without impurity seeding, and a mantle radiation scenario using extrinsic impurities. These results are promising for a NT fusion pilot plant but further questions on confinement extrapolation and core-edge integration remain, which motivate future NT studies on DIII-D and beyond.

AB - Negative triangularity (NT) is a potentially transformative configuration for tokamak-based fusion energy with its high-performance core, edge localized mode (ELM)-free edge, and low-field-side divertors that could readily scale to an integrated reactor solution. Previous NT work on the TCV and DIII-D tokamaks motivated the installation of graphite-tile armor on the low-field-side lower outer wall of DIII-D. A dedicated multiple-week experimental campaign was conducted to qualify the NT scenario for future reactors. During the DIII-D NT campaign, high confinement ( H 98 y , 2 ≳ 1), high current ( q 95 < 3), and high normalized pressure plasmas ( β N > 2.5) were simultaneously attained in strongly NT-shaped discharges with average triangularity δ avg = −0.5 that were stably controlled. Experiments covered a wide range of DIII-D operational space (plasma current, toroidal field, electron density and pressure) and did not trigger an ELM in a single discharge as long as sufficiently strong NT was maintained; in contrast, to other high-performance ELM-suppression scenarios that have narrower operating windows. These strong NT plasmas had a lower outer divertor X-point shape and maintained a non-ELMing edge with an electron temperature pedestal, exceeding that of typical L-mode plasmas. Also, the following was achieved during the campaign: high normalized density ( n e / n GW of at least 1.7), particle confinement comparable to energy confinement with Z eff ∼ 2 , a detached divertor without impurity seeding, and a mantle radiation scenario using extrinsic impurities. These results are promising for a NT fusion pilot plant but further questions on confinement extrapolation and core-edge integration remain, which motivate future NT studies on DIII-D and beyond.

KW - NT edge

KW - confinement

KW - negative triangularity

UR - https://www.scopus.com/pages/publications/85204101032

UR - https://www.scopus.com/pages/publications/85204101032#tab=citedBy

U2 - 10.1088/1361-6587/ad6f40

DO - 10.1088/1361-6587/ad6f40

M3 - Review article

AN - SCOPUS:85204101032

SN - 0741-3335

VL - 66

JO - Plasma Physics and Controlled Fusion

JF - Plasma Physics and Controlled Fusion

IS - 10

M1 - 105018

ER -

Overview of results from the 2023 DIII-D negative triangularity campaign

Abstract

All Science Journal Classification (ASJC) codes

Keywords

Access to Document

Other files and links

Fingerprint

Cite this