59th Annual Meeting of the APS Division of Plasma Physics
Volume 62, Number 12
Monday–Friday, October 23–27, 2017;
Milwaukee, Wisconsin
Session XR1: Review: The Science and Technology Case for High-Field Fusion
8:00 AM–9:00 AM,
Friday, October 27, 2017
Room: Ballroom C
Chair: Earl Scime, West Virginia University
Abstract ID: BAPS.2017.DPP.XR1.1
Abstract: XR1.00001 : The Science and Technology Case for High-Field Fusion.
8:00 AM–9:00 AM
Preview Abstract
Author:
D. Whyte
(MIT Plasma Science and Fusion Center)
This review will focus on the origin, development and new opportunities of a
strategy for fusion energy based on the \textit{high-field approach}. In this approach confinement
devices are designed at the maximum possible value of vacuum magnetic field
strength, B. The integrated electrical, mechanical and cooling engineering
challenges of high-field on coil (B$_{\mathrm{coil}})$, large-bore
electromagnets are examined for both copper and superconductor materials.
These engineering challenges are confronted because of the profound science
advantages provided by high-B, which are derived and reviewed: high fusion
power density, \textasciitilde B$^{\mathrm{4}}$, in compact devices,
thermonuclear plasmas with significant stability margin, and, in tokamaks,
access to higher plasma density. Two distinct high-field strategies emerged
in the 1980's. The first was compact, cryogenically-cooled copper devices
(BPX, IGNITOR, FIRE) with B$_{\mathrm{coil}}$\textgreater 20 T, while the
second was a large-volume, Nb$_{\mathrm{3}}$Sn superconductor device with
B$_{\mathrm{coil}}$ \textless 12 T; with the second path exclusively chosen
ca. 2000 with the ITER construction decision. The reasoning, advantages and
challenges of that decision are discussed. Yet since that decision, a new
opportunity has arisen: compact, Rare Earth Barium Copper Oxide (REBCO)
superconductor-based devices with B$_{\mathrm{coil}}$ \textgreater 20 T; a
strategy that essentially combines the best components of the two previous
strategies. Recent activities examining the technology and science
implications of this new strategy are reviewed. On the technology side,
REBCO superconductors have now been used to produce
B$_{\mathrm{coil}}$\textgreater 40 T in small-bore electromagnets, enabled
by rapid progress in manufactured REBCO conductor quality, coil modularity
and flexible operating temperature range. Specific tokamak designs, over a
range of aspect ratios, have been developed to take scientific advantage of
these features in various ways, and will be described.
To cite this abstract, use the following reference: http://meetings.aps.org/link/BAPS.2017.DPP.XR1.1