[摘要] An improved energy confinement regime, I-mode, is studied in Alcator C-Mod, a compact high-field divertor tokamak using ion cyclotron range of frequencies (ICRFs) auxiliary heating. I-mode features an edge energy transport barrier without an accompanying particle barrier, leading to several performance benefits. H-mode energy confinement is obtained without core impurity accumulation, resulting in reduced impurity radiation with a high- Zmetal wall and ICRF heating. I-mode has a stationary temperature pedestal with edge localized modes typically absent, while plasma density is controlled using divertor cryopumping. I-mode is a confinement regime that appears distinct from both L-mode and H-mode, combining the most favourable elements of both. The I-mode regime is investigated predominately with ion ∇ Bdrift away from the active X-point. The transition from L-mode to I-mode is primarily identified by the formation of a high temperature edge pedestal, while the edge density profile remains nearly identical to L-mode. Laser blowoff injection shows that I-mode core impurity confinement times are nearly identical with those in L-mode, despite the enhanced energy confinement. In addition, a weakly coherent edge MHD mode is apparent at high frequency ∼100–300 kHz which appears to increase particle transport in the edge. The I-mode regime has been obtained over a wide parameter space ( B _T = 3–6 T,I _p = 0.7–1.3 MA,q ₉₅ = 2.5–5). In general, the I-mode exhibits the strongest edge temperature pedestal ( T _ped) and normalized energy confinement ( H ₉₈ > 1) at lowq ₉₅ (<3.5) and high heating power ( P _heat > 4 MW). I-mode significantly expands the operational space of edge localized mode (ELM)-free, stationary pedestals in C-Mod toT _ped ∼ 1 keV and low collisionality, as compared with EDA H-mode withT _ped < 0.6 keV,. The I-mode global energy confinement has a relatively weak degradation with heating power; leading to increasingH ₉₈ with heating power.