Status and Plans for the National Spherical Torus Experimental Research Facility

Masayuki Ono; M. G. Bell; R. E. Bell; S. Bernabei; J. M. Bialek; T. Bigelow; M. Bitter; T. M. Biewer; W. Blanchard; J. Boedo; C. Bush; J. Chrzanowski; D. S. Darrow; L Dudek; R. Feder; J. R. Ferron; J. Foley; E. D. Fredrickson; D. A. Gates; G. Gettelfinger; T. Gibney; R. Harvey; R. Hatcher; W. Heidbrink; T. R. Jarboe; D. W. Johnson; M. Kalish; R. Kaita; S. M. Kaye; C. Kessel; S. Kubota; H. W. Kugel; G. Labik; B. P. LeBlanc; K. C. Lee; F. M. Levinton; J. Lowrance; R. Maingi; J. Manickam; R. Maqueda; R. Marsala; D. Mastravito; E. Mazzucato; S. S. Medley; J. Menard; D. Mueller; T. Munsat; B. A. Nelson; C. Neumeyer; N. Nishino; H. K. Park; S. F. Paul; T. Peebles; E. Perry; Y.-K. M. Peng; C. K. Phillips; R. Pinsker; S. Ramakrishnan; R. Raman; P. Roney; A. L. Roquemore; P. M. Ryan; S. A. Sabbagh; H. Schneider; C. H. Skinner; D. R. Smith; A. C. Sontag; V. Soukhanovskii; T. Stevenson; D. Stotler; B. C. Stratton; D. Stutman; D. W. Swain; E. Synakowski; Y. Takase; G. Taylor; K. L. Tritz; A. Von Halle; J. Wilgen; M. Williams; J. R. Wilson; I. Zatz; W. Zhu; S. J. Zweben; R. Akers; P. Beiersdorfer; P. T. Bonoli; C. Bourdelle; M. D. Carter; C. S. Chang; W. Choe; W. Davis; S. J. Diem; C. Domier; R. Ellis; P. C. Efthimion; A. Field; M. Finkenthal; E. Fredd; G. Y. Fu; A. Glasser; R. J. Goldston; L. R. Grisham; N. Gorelenkov; L. Guazzotto; R. J. Hawryluk; P. Heitzenroeder; K. W. Hill; W. Houlberg; J. C. Hosea; D. Humphreys; C. Jun; J. H. Kim; S. Krasheninnikov; L. L. Lao; S. G. Lee; J. Lawson; N. C. Luhmann; T. K. Mau; M. M. Menon; O. Mitarai; M. Nagata; G. Oliaro; D. Pacella; R. Parsells; A. Pigarov; G. D. Porter; A. K. Ram; D. Rasmussen; M. Redi; G. Rewoldt; J. Robinson; E. Ruskov; J. Schmidt; I. Semenov; K. Shaing; K. Shinohara; M. Schaffer; P. Sichta; X. Tang; J. Timberlake; M. Wade; W. R. Wampler; Z. Wang; R. Woolley; G. A. Wurden; X. Xu

doi:10.1541/ieejfms.125.868

Special Issue Paper

Status and Plans for the National Spherical Torus Experimental Research Facility

Masayuki Ono, M. G. Bell, R. E. Bell, S. Bernabei, J. M. Bialek, T. Bigelow, M. Bitter, T. M. Biewer, W. Blanchard, J. Boedo, C. Bush, J. Chrzanowski, D. S. Darrow, L Dudek, R. Feder, J. R. Ferron, J. Foley, E. D. Fredrickson, D. A. Gates, G. Gettelfinger, T. Gibney, R. Harvey, R. Hatcher, W. Heidbrink, T. R. Jarboe, D. W. Johnson, M. Kalish, R. Kaita, S. M. Kaye, C. Kessel, S. Kubota, H. W. Kugel, G. Labik, B. P. LeBlanc, K. C. Lee, F. M. Levinton, J. Lowrance, R. Maingi, J. Manickam, R. Maqueda, R. Marsala, D. Mastravito, E. Mazzucato, S. S. Medley, J. Menard, D. Mueller, T. Munsat, B. A. Nelson, C. Neumeyer, N. Nishino, H. K. Park, S. F. Paul, T. Peebles, E. Perry, Y.-K. M. Peng, C. K. Phillips, R. Pinsker, S. Ramakrishnan, R. Raman, P. Roney, A. L. Roquemore, P. M. Ryan, S. A. Sabbagh, H. Schneider, C. H. Skinner, D. R. Smith, A. C. Sontag, V. Soukhanovskii, T. Stevenson, D. Stotler, B. C. Stratton, D. Stutman, D. W. Swain, E. Synakowski, Y. Takase, G. Taylor, K. L. Tritz, A. Von Halle, J. Wilgen, M. Williams, J. R. Wilson, I. Zatz, W. Zhu, S. J. Zweben, R. Akers, P. Beiersdorfer, P. T. Bonoli, C. Bourdelle, M. D. Carter, C. S. Chang, W. Choe, W. Davis, S. J. Diem, C. Domier, R. Ellis, P. C. Efthimion, A. Field, M. Finkenthal, E. Fredd, G. Y. Fu, A. Glasser, R. J. Goldston, L. R. Grisham, N. Gorelenkov, L. Guazzotto, R. J. Hawryluk, P. Heitzenroeder, K. W. Hill, W. Houlberg, J. C. Hosea, D. Humphreys, C. Jun, J. H. Kim, S. Krasheninnikov, L. L. Lao, S. G. Lee, J. Lawson, N. C. Luhmann, T. K. Mau, M. M. Menon, O. Mitarai, M. Nagata, G. Oliaro, D. Pacella, R. Parsells, A. Pigarov, G. D. Porter, A. K. Ram, D. Rasmussen, M. Redi, G. Rewoldt, J. Robinson, E. Ruskov, J. Schmidt, I. Semenov, K. Shaing, K. Shinohara, M. Schaffer, P. Sichta, X. Tang, J. Timberlake, M. Wade, W. R. Wampler, Z. Wang, R. Woolley, G. A. Wurden, X. Xu

Author information

Masayuki Ono
Princeton University
M. G. Bell
Princeton University
R. E. Bell
Princeton University
S. Bernabei
Princeton University
J. M. Bialek
Columbia University
T. Bigelow
Oak Ridge National Laboratory
M. Bitter
Princeton University
T. M. Biewer
Massachusetts Institute of Technology
W. Blanchard
Princeton University
J. Boedo
University of California
C. Bush
Oak Ridge National Laboratory
J. Chrzanowski
Princeton University
D. S. Darrow
Princeton University
L Dudek
Princeton University
R. Feder
Princeton University
J. R. Ferron
General Atomics
J. Foley
Nova Photonics
E. D. Fredrickson
Princeton University
D. A. Gates
Princeton University
G. Gettelfinger
Princeton University
T. Gibney
Princeton University
R. Harvey
Compx
R. Hatcher
Princeton University
W. Heidbrink
University of California
T. R. Jarboe
University of Washington
D. W. Johnson
Princeton University
M. Kalish
Princeton University
R. Kaita
Princeton University
S. M. Kaye
Princeton University
C. Kessel
Princeton University
S. Kubota
University of California
H. W. Kugel
Princeton University
G. Labik
Princeton University
B. P. LeBlanc
Princeton University
K. C. Lee
University of California
F. M. Levinton
Nova Photonics
J. Lowrance
Princeton Scientific Instruments
R. Maingi
Oak Ridge National Laboratory
J. Manickam
Princeton University
R. Maqueda
Nova Photonics
R. Marsala
Princeton University
D. Mastravito
Princeton University
E. Mazzucato
Princeton University
S. S. Medley
Princeton University
J. Menard
Princeton University
D. Mueller
Princeton University
T. Munsat
University of Colorado
B. A. Nelson
University of Washington
C. Neumeyer
Princeton University
N. Nishino
Hiroshima University
H. K. Park
Princeton University
S. F. Paul
Princeton University
T. Peebles
University of California
E. Perry
Princeton University
Y.-K. M. Peng
Oak Ridge National Laboratory
C. K. Phillips
Princeton University
R. Pinsker
General Atomics
S. Ramakrishnan
Princeton University
R. Raman
University of Washington
P. Roney
Princeton University
A. L. Roquemore
Princeton University
P. M. Ryan
Oak Ridge National Laboratory
S. A. Sabbagh
Columbia University
H. Schneider
Princeton University
C. H. Skinner
Princeton University
D. R. Smith
Princeton University
A. C. Sontag
Columbia University
V. Soukhanovskii
Lawrence Livermore National Laboratory
T. Stevenson
Princeton University
D. Stotler
Princeton University
B. C. Stratton
Princeton University
D. Stutman
Johns Hopkins University
D. W. Swain
Oak Ridge National Laboratory
E. Synakowski
Princeton University
Y. Takase
University of Tokyo
G. Taylor
Princeton University
K. L. Tritz
Johns Hopkins University
A. Von Halle
Princeton University
J. Wilgen
Oak Ridge National Laboratory
M. Williams
Princeton University
J. R. Wilson
Princeton University
I. Zatz
Princeton University
W. Zhu
Columbia University
S. J. Zweben
Princeton University
R. Akers
Euratom-UKAEA Fusion Association
P. Beiersdorfer
Lawrence Livermore National Laboratory
P. T. Bonoli
Massachusetts Institute of Technology
C. Bourdelle
CEA Cadarache
M. D. Carter
Oak Ridge National Laboratory
C. S. Chang
New York University
W. Choe
Korea Advanced Institut of Science and Technology
W. Davis
Princeton University
S. J. Diem
Princeton University
C. Domier
Princeton Scientific Instruments
R. Ellis
Princeton University
P. C. Efthimion
Princeton University
A. Field
Euratom-UKAEA Fusion Association
M. Finkenthal
Johns Hopkins University
E. Fredd
Princeton University
G. Y. Fu
Princeton University
A. Glasser
Los Alamos National Laboratory
R. J. Goldston
Princeton University
L. R. Grisham
Princeton University
N. Gorelenkov
Princeton University
L. Guazzotto
Universityh of Rochester
R. J. Hawryluk
Princeton University
P. Heitzenroeder
Princeton University
K. W. Hill
Princeton University
W. Houlberg
Oak Ridge National Laboratory
J. C. Hosea
Princeton University
D. Humphreys
General Atomics
C. Jun
Princeton University
J. H. Kim
Korea Advanced Institut of Science and Technology
S. Krasheninnikov
University of California
L. L. Lao
General Atomics
S. G. Lee
Korea Basic Science Institute
J. Lawson
Princeton University
N. C. Luhmann
Princeton Scientific Instruments
T. K. Mau
University of California
M. M. Menon
Oak Ridge National Laboratory
O. Mitarai
Kyushu Tokai University
M. Nagata
Himeji Institute of Technology
G. Oliaro
Princeton University
D. Pacella
ENEA
R. Parsells
Princeton University
A. Pigarov
University of California
G. D. Porter
Lawrence Livermore National Laboratory
A. K. Ram
Massachusetts Institute of Technology
D. Rasmussen
Oak Ridge National Laboratory
M. Redi
Princeton University
G. Rewoldt
Princeton University
J. Robinson
Princeton University
E. Ruskov
University of California
J. Schmidt
Princeton University
I. Semenov
Kurcahtov Institute
K. Shaing
University of Wisconsin
K. Shinohara
JAERI
M. Schaffer
General Atomics
P. Sichta
Princeton University
X. Tang
Los Alamos National Laboratory
J. Timberlake
Princeton University
M. Wade
Oak Ridge National Laboratory
W. R. Wampler
Sandia National Laboratories
Z. Wang
Los Alamos National Laboratory
R. Woolley
Princeton University
G. A. Wurden
Los Alamos National Laboratory
X. Xu
Lawrence Livermore National Laboratory

Keywords: magnetic fusion, NSTX, spherical torus

JOURNAL FREE ACCESS

2005 Volume 125 Issue 11 Pages 868-880

DOI https://doi.org/10.1541/ieejfms.125.868

Details

Abstract

An overview of the research capabilities and the future plans on the MA-class National Spherical Torus Experiment (NSTX) at Princeton is presented. NSTX research is exploring the scientific benefits of modifying the field line structure from that in more conventional aspect ratio devices, such as the tokamak. The relevant scientific issues pursued on NSTX include energy confinement, MHD stability at high β, non-inductive sustainment, solenoid-free start-up, and power and particle handling. In support of the NSTX research goal, research tools are being developed by the NSTX team. In the context of the fusion energy development path being formulated in the US, an ST-based Component Test Facility (CTF) and, ultimately a high β Demo device based on the ST, are being considered. For these, it is essential to develop high performance (high β and high confinement), steady-state (non-inductively driven) ST operational scenarios and an efficient solenoid-free start-up concept. We will also briefly describe the Next-Step-ST (NSST) device being designed to address these issues in fusion-relevant plasma conditions.

Corresponding author

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