TY - JOUR
T1 - Expanding the role of impurity spectroscopy for investigating the physics of high-Z dissipative divertors
AU - the ASDEX Upgrade Team, the Alcator C-Mod Team, and JET Contributors
AU - Reinke, M. L.
AU - Meigs, A.
AU - Delabie, E.
AU - Mumgaard, R.
AU - Reimold, F.
AU - Potzel, S.
AU - Bernert, M.
AU - Brunner, D.
AU - Canik, J.
AU - Cavedon, M.
AU - Coffey, I.
AU - Edlund, E.
AU - Harrison, J.
AU - LaBombard, B.
AU - Lawson, K.
AU - Lomanowski, B.
AU - Lore, J.
AU - Stamp, M.
AU - Terry, J.
AU - Viezzer, E.
N1 - Publisher Copyright:
© 2017 Elsevier Ltd
PY - 2017/8
Y1 - 2017/8
N2 - New techniques that attempt to more fully exploit spectroscopic diagnostics in the divertor and pedestal region during highly dissipative scenarios are demonstrated using experimental results from recent low-Z seeding experiments on Alcator C-Mod, JET and ASDEX Upgrade. To exhaust power at high parallel heat flux, q∥ > 1 GW/m2, while minimizing erosion, reactors with solid, high-Z plasma facing components (PFCs) are expected to use extrinsic impurity seeding. Due to transport and atomic physics processes which impact impurity ionization balance, so-called ‘non-coronal’ effects, we do not accurately know and have yet to demonstrate the maximum q∥ which can be mitigated in a tokamak. Radiation enhancement for nitrogen is shown to arise primarily from changes in Li- and Be-like charge states on open field lines, but also through transport-driven enhancement of H- and He-like charge states in the pedestal region. Measurements are presented from nitrogen seeded H-mode and L-mode plasmas where emission from N1+ through N6+ are observed. Active charge exchange spectroscopy of partially ionized low-Z impurities in the plasma edge is explored to measure N5+ and N6+ within the confined plasma, while passive UV and visible spectroscopy is used to measure N1+-N4+ in the boundary. Examples from recent JET and Alcator C-Mod experiments which employ nitrogen seeding highlight how improving spectroscopic coverage can be used to gain empirical insight and provide more data to validate boundary simulations.
AB - New techniques that attempt to more fully exploit spectroscopic diagnostics in the divertor and pedestal region during highly dissipative scenarios are demonstrated using experimental results from recent low-Z seeding experiments on Alcator C-Mod, JET and ASDEX Upgrade. To exhaust power at high parallel heat flux, q∥ > 1 GW/m2, while minimizing erosion, reactors with solid, high-Z plasma facing components (PFCs) are expected to use extrinsic impurity seeding. Due to transport and atomic physics processes which impact impurity ionization balance, so-called ‘non-coronal’ effects, we do not accurately know and have yet to demonstrate the maximum q∥ which can be mitigated in a tokamak. Radiation enhancement for nitrogen is shown to arise primarily from changes in Li- and Be-like charge states on open field lines, but also through transport-driven enhancement of H- and He-like charge states in the pedestal region. Measurements are presented from nitrogen seeded H-mode and L-mode plasmas where emission from N1+ through N6+ are observed. Active charge exchange spectroscopy of partially ionized low-Z impurities in the plasma edge is explored to measure N5+ and N6+ within the confined plasma, while passive UV and visible spectroscopy is used to measure N1+-N4+ in the boundary. Examples from recent JET and Alcator C-Mod experiments which employ nitrogen seeding highlight how improving spectroscopic coverage can be used to gain empirical insight and provide more data to validate boundary simulations.
UR - http://www.scopus.com/inward/record.url?scp=85010950567&partnerID=8YFLogxK
U2 - 10.1016/j.nme.2016.12.003
DO - 10.1016/j.nme.2016.12.003
M3 - Article
AN - SCOPUS:85010950567
SN - 2352-1791
VL - 12
SP - 91
EP - 99
JO - Nuclear Materials and Energy
JF - Nuclear Materials and Energy
ER -