DSOL ITPA meetingW.Fundamenski Avila, Spain, 7-10/01/08 H-phase in ITER: what can be learned about divertor and SOL behaviour in the D and D-T phases W. Fundamenski (UKAEA, EFDA-JET)
DSOL ITPA meetingW.Fundamenski Avila, Spain, 7-10/01/08 Coupled system of ions, electrons, neutrals and fields Kinetic equation for electrons, ions, impurities and neutrals Accelaration due to both internal and external fields Coulomb collisions for charged species, described by the Fokker- Planck operator, neutral collisions by the Boltzmann operator Maxwell’s equations for internal fields Closure only via 0 th and 1 st Suggests the moment approach Complex system of i, e, n and
DSOL ITPA meetingW.Fundamenski Avila, Spain, 7-10/01/08 –fully ionised plasma physics (dimensionless parameters), scaling with ion mass All electron quantities independent of A, e.g. e e v Te e A 0 const Ion quanties typically scale as a square root (or its inverse) of the ion mass, e.g. * 1/ * 1/v Ti 1/v A 1/ ||i e A 1/2, i A 0 const The combination of these include the range of derived quantities, including plasma- neutral interactions (cross-sections) D and H are chemically identical (to fairly high accuracy), hence electron impact reactions are quite similar (ionisation, excitation, etc). In contrast, ion impact reactions can differ substantially, eg. CX, elastic scattering. –plasma-surface interactions (erosion yields) Physical sputtering of C, Be, W,… depends on ion mass Chemical sputtering of C comparable for H and D –SOL plasma transport Parallel convection at roughly the plasma sound speed, c s v Ti A -1/2 Parallel conduction, ||i A -1/2 Ion mass in edge/SOL plasma physics
DSOL ITPA meetingW.Fundamenski Avila, Spain, 7-10/01/08 plasma neutrals fields (photons) surface Tokamak core is largely a classical, fully ionised plasma (relativistic corrections for runaway electrons, quantum corrections for impurities) Tokamak edge involves quantum effects due to interaction of ions-electrons, photons, atoms-molecules and solid surface (eg. ionisation-recombination, excitation- emission, charge exchange, surface chemistry,…) The relative importance of quantum effects complicates a general theory of a tokamak edge plasma, which is typically described by severely truncated forms Interactions in the tokamak edge
DSOL ITPA meetingW.Fundamenski Avila, Spain, 7-10/01/08 1) e + H 2 H e 2) e + H 2 2H 0 + e 3) e + H 2 H 0 + H + + 2e 4) e + H 2 + 2H 0 5) e + H 2 + H 0 + H + + 2e 6) e + H 0 H + + 2e 7) H 0 + H + H + + H 0 In practice, quantum effects included via interaction cross-sections Selected plasma-neutral cross-sections
DSOL ITPA meetingW.Fundamenski Avila, Spain, 7-10/01/08 –Due to the complexity of the above scalings, a simple ‘wind-tunnel’ similarity experiment not possible within a single machine i.e. not possible to directly extrapolate from the H-phase to the D-phase of ITER based on a simple dimensionless scaling –However, all of the above scalings can be (are) included in edge transport codes, multi-fluid plasma/MC neutrals codes, eg. SOLPS (B2/EIRENE), … local or global turbulence codes, e.g. ESEL, GEM, XG2, etc. plasma filament transport, –Therefore, from the DSOL perspective, the validation of these codes should be the primary task of the H-phase in ITER, For instance, consider divertor plasma detachment (discussed on Monday) –Once validated, the extrapolation to ITER D phase becomes more credible from the ITER H-phase, then from, say, the JET D phase, e.g. *, div.closure, etc. –To facilitate this extrapolation in the ion mass, it is desirable to perform reference (matched) H vs D experiments in existing tokamaks, The focus should be on Ohmic and L-mode edge/SOL conditions, in order to empirically infer (whenever possible) isotopic scalings of unknown plasma parameters This should be supplemented by detailed modelling effort Extrapolation to ITER D-phase