Regimes of ignited operation

Abstract

Regimes of ignited operation are explored in terms of a general four-dimensional requirement on nτ_e, nτ_i, T_i and T_e. The conditions under which ignited operation occurs with T_e > T_i and T_i > T_e are found. The amount of electron-ion de-coupling and the required value of nτ_e at ignition are determined as functions of the ion temperature and the ratio of the electron energy confinement time to the ion energy confinement time. Effects of anomalous transfer of alpha-particle energy to the ions are considered. Thermal-stability characteristics are determined in the context of the four-dimensional ignition requirement. An empirical scaling law for the electron energy confinement time and the neoclassical transport description of the ion energy confinement time are used to project specific features of ignited operation in recent next-step tokamak reactor designs. It is found that the ignition requirement on nτ_e can be significantly reduced by operating in the T_i > T_e regime at high ion temperatures. This reduction in nτ_e leads to a considerable reduction in the neutral beam energy required for adequate penetration in a full-density start-up scenario. The ion temperature dependence of characteristic thermal runaway times has also been determined for the next-step reactor designs. The thermal runaway times are very short (on the order of τ_e) until ion temperatures approaching 50 keV are reached.