An improved understanding of the roles of atomic processes and power balance in target ion current loss during detachment

The physics leading to the decrease of the divertor ion current ($I_t$), or 'roll-over' during detachment for divertor power exhaust in tokamaks is experimentally explored on the TCV tokamak through characterization of the location, magnitude and role of the various divertor ion sinks and sources including a complete measure of particle and power balance. These first measurements of the profiles of divertor ionisation and hydrogenic radiation along the divertor leg are enabled through novel spectroscopic techniques which are introduced. Over a range in TCV plasma conditions (plasma current, impurity-seeding, density) the $I_t$ roll-over is caused by a drop in the divertor ion source; recombination remains either small or negligible until later in the detachment process. In agreement with simple analytical predictions, this ion source reduction is driven by a reduction in the power available for ionization, Precl, sometimes characterised as 'power starvation'. The concurrent increase in the energy required per ionisation, $E_{ion}$, further reduces the number of ionizations. The measured divertor profile evolution through detachment of the various ion sources/sinks as well as power losses and charge exchange are quantitatively reproduced through full 2D SOLPS modelling of a ramp of core plasma density through the detachment process. The detachment threshold is found experimentally (in agreement with analytic model predictions) to be $\sim P_{recl}/I_t E_{ion} \sim 2$, which corresponds to the target electron temperature, $T_t \propto E_{ion}/{\gamma}$ where ${\gamma}$ is the sheath transmission coefficient. The loss in target pressure, required for target ion current loss, is driven not by just volumetric momentum loss as typically assumed but also due to a drop of upstream pressure.