English

Radiative pulsed L-mode operation in ARC-class reactors

Plasma Physics 2025-10-23 v2

Abstract

A new ARC-class, highly-radiative, pulsed, L-mode, burning plasma scenario is developed and evaluated as a candidate for future tokamak reactors. Pulsed inductive operation alleviates the stringent current drive requirements of steady-state reactors, and operation in L-mode affords ELM-free access to 90%\sim90\% core radiation fractions, significantly reducing the divertor power handling requirements. In this configuration the fusion power density can be maximized despite L-mode confinement by utilizing high-field to increase plasma densities and current. This allows us to obtain high gain in robust scenarios in compact devices with Pfus>1000P_\mathrm{fus} > 1000\,MW despite low confinement. We demonstrate the feasibility of such scenarios here; first by showing that they avoid violating 0-D tokamak limits, and then by performing self-consistent integrated simulations of flattop operation including neoclassical and turbulent transport, magnetic equilibrium, and RF current drive models. Finally we examine the potential effect of introducing negative triangularity with a 0-D model. Our results show high-field radiative pulsed L-mode scenarios are a promising alternative to the typical steady state advanced tokamak scenarios which have dominated tokamak reactor development.

Keywords

Cite

@article{arxiv.2207.08726,
  title  = {Radiative pulsed L-mode operation in ARC-class reactors},
  author = {S. J. Frank and C. J. Perks and A. O. Nelson and T. Qian and S. Jin and A. J. Cavallaro and A. Rutkowski and A. H. Reiman and J. P. Freidberg and P. Rodriguez-Fernandez and D. G. Whyte},
  journal= {arXiv preprint arXiv:2207.08726},
  year   = {2025}
}
R2 v1 2026-06-25T01:01:15.368Z