TY - JOUR
T1 - Experiments with liquid metal walls
T2 - Status of the lithium tokamak experiment
AU - Kaita, Robert
AU - Berzak, Laura
AU - Boyle, Dennis
AU - Gray, Timothy
AU - Granstedt, Erik
AU - Hammett, Gregory
AU - Jacobson, Craig M.
AU - Jones, Andrew
AU - Kozub, Thomas
AU - Kugel, Henry
AU - Leblanc, Benoit
AU - Logan, Nicholas
AU - Lucia, Matthew
AU - Lundberg, Daniel
AU - Majeski, Richard
AU - Mansfield, Dennis
AU - Menard, Jonathan
AU - Spaleta, Jeffrey
AU - Strickler, Trevor
AU - Timberlake, John
AU - Yoo, Jongsoo
AU - Zakharov, L.
AU - Maingi, Rajesh
AU - Soukhanovskii, Vlad
AU - Tritz, Kevin
AU - Gershman, Sophia
PY - 2010/11
Y1 - 2010/11
N2 - Liquid metal walls have been proposed to address the first wall challenge for fusion reactors. The lithium tokamak experiment (LTX) at the Princeton Plasma Physics Laboratory (PPPL) is the first magnetic confinement device to have liquid metal plasma-facing components (PFC's) that encloses virtually the entire plasma. In the current drive experiment-upgrade (CDX-U), a predecessor to LTX at PPPL, the highest improvement in energy confinement ever observed in ohmically heated tokamak plasmas was achieved with a toroidal liquid lithium limiter. The LTX extends this liquid lithium PFC by using a conducting conformal shell that almost completely surrounds the plasma. By heating the shell, a lithium coating on the plasma-facing side can be kept liquefied. A consequence of the low-recycling conditions from liquid lithium walls is the need for efficient plasma fueling. For this purpose, a molecular cluster injector is being developed. Future plans include the installation of a neutral beam for core plasma fueling, and also ion temperature measurements using charge-exchange recombination spectroscopy (CHERS). Low edge recycling is also predicted to reduce temperature gradients that drive drift wave turbulence. Gyrokinetic simulations are in progress to calculate fluctuation levels and transport for LTX plasmas, and new fluctuation diagnostics are under development to test these predictions.
AB - Liquid metal walls have been proposed to address the first wall challenge for fusion reactors. The lithium tokamak experiment (LTX) at the Princeton Plasma Physics Laboratory (PPPL) is the first magnetic confinement device to have liquid metal plasma-facing components (PFC's) that encloses virtually the entire plasma. In the current drive experiment-upgrade (CDX-U), a predecessor to LTX at PPPL, the highest improvement in energy confinement ever observed in ohmically heated tokamak plasmas was achieved with a toroidal liquid lithium limiter. The LTX extends this liquid lithium PFC by using a conducting conformal shell that almost completely surrounds the plasma. By heating the shell, a lithium coating on the plasma-facing side can be kept liquefied. A consequence of the low-recycling conditions from liquid lithium walls is the need for efficient plasma fueling. For this purpose, a molecular cluster injector is being developed. Future plans include the installation of a neutral beam for core plasma fueling, and also ion temperature measurements using charge-exchange recombination spectroscopy (CHERS). Low edge recycling is also predicted to reduce temperature gradients that drive drift wave turbulence. Gyrokinetic simulations are in progress to calculate fluctuation levels and transport for LTX plasmas, and new fluctuation diagnostics are under development to test these predictions.
KW - Fusion reactor first walls
KW - Lithium plasma-facing components
KW - Low-aspect ratio tokamaks
KW - Low-recycling plasmas
KW - Plasma fueling
UR - https://www.scopus.com/pages/publications/78649457552
UR - https://www.scopus.com/inward/citedby.url?scp=78649457552&partnerID=8YFLogxK
U2 - 10.1016/j.fusengdes.2010.04.005
DO - 10.1016/j.fusengdes.2010.04.005
M3 - Article
AN - SCOPUS:78649457552
SN - 0920-3796
VL - 85
SP - 874
EP - 881
JO - Fusion Engineering and Design
JF - Fusion Engineering and Design
IS - 6
ER -