An edge-localized mode (ELM) is a plasma instability occurring in the edge region of a tokamak plasma due to periodic relaxations of the edge transport barrier in high-confinement mode. Each ELM burst is associated with expulsion of particles and energy from the confined plasma into the scrape-off layer. This phenomenon was first observed in the ASDEX tokamak in 1981. Diamagnetic effects in the model equations expand the size of the parameter space in which solutions of repeated sawteeth can be recovered compared to a resistive MHD model. An ELM can expel up to 20 percent of the reactor's energy.

Issues

ELM is a major challenge in magnetic fusion research with tokamaks, as these instabilities can:

Prevention and control

A variety of experiments/simulations have attempted to mitigate damage from ELM. Techniques include:

History

In 2003 DIII-D began experimenting with resonant magnetic perturbations to control ELMs. In 2006 an initiative (Project Aster) was started to simulate a full ELM cycle including its onset, the highly non-linear phase, and its decay. However, this did not constitute a “true” ELM cycle, since a true ELM cycle would require modeling the slow growth after the crash, in order to produce a second ELM. As of late 2011, several research facilities had demonstrated active control or suppression of ELMs in tokamak plasmas. For example, the KSTAR tokamak used specific asymmetric three-dimensional magnetic field configurations to achieve this goal. In 2015, results of the first simulation to demonstrate repeated ELM cycling was published. In 2022, researchers began testing the small ELM hypothesis at JET to assess the utility of the technique.