Improved liquid lithium surfaces in the Lithium Tokamak Experiment-β

D. P. Boyle; A. Maan; R. Majeski; E. Ostrowski; S. Abe; S. Banerjee; W. Capecchi; D. B. Elliott; C. Hansen; E. Jung; P. E. Hughes; S. Kubota; M. Lampert; R. Maingi; A. G. McLean; J. E. Menard; J. J. Morales; V. A. Soukhanovskii

doi:10.1016/j.nme.2025.101949

Improved liquid lithium surfaces in the Lithium Tokamak Experiment-β

D. P. Boyle, A. Maan, R. Majeski, E. Ostrowski, S. Abe, S. Banerjee, W. Capecchi, D. B. Elliott, C. Hansen, E. Jung, P. E. Hughes, S. Kubota, M. Lampert, R. Maingi, A. G. McLean, J. E. Menard, J. J. Morales, V. A. Soukhanovskii

Diagnostics and Control

Research output: Contribution to journal › Article › peer-review

Abstract

Advances in vacuum, surface, and lithium conditioning techniques throughout five years of continuous operations in LTX-β have produced mirror-like liquid lithium surfaces and demonstrated the feasibility of high-performance tokamak discharges fully surrounded by liquid metal without significant operational problems. Improvements in conditioning techniques and procedures, including many weeks of baking and accumulation of 70 g of Li, led to reduced residual gasses and clean Li surfaces − all while still maintaining enough operational flexibility for multiple in-vacuum diagnostic upgrades and calibrations. Coatings had a visibly clean appearance, with reflective liquid metal demonstrating good wetting and surface adhesion with films that were now macroscopically thick. Solidified Li showed large crystal grains, while surface science measurements observed reduced impurities in the lithium. Steadily improved plasma performance was achieved with liquid lithium, with discharges able to match solid Li in terms of evolution of I_p and n_e, including rapid density pumping indicating low recycling. There were indications of moderately increased Li impurity influx, though few significant disturbances by the large liquid surfaces on tokamak operations over hundreds of discharges. Liquid metal plasma facing components are a potential solution to the extreme heat and particle fluxes that could cause unacceptable damage to solid materials, while liquid lithium also has the potential for greatly increased confinement in the low-recycling regime. While many liquid metal approaches are possible, and numerous experiments have been conducted in test stands and small modules in fusion devices, LTX-β is the only tokamak operated while fully surrounded by liquid metal.

Original language	English
Article number	101949
Journal	Nuclear Materials and Energy
Volume	43
DOIs	https://doi.org/10.1016/j.nme.2025.101949
State	Published - Jun 2025

Funding

This work was supported by US Department of Energy contracts DE-AC02-09CH11466 , DE-SC0019308 , DE-SC0019006 , DE-AC05-00OR22725 , DE-SC0024898 , DE-SC0023481 , and DE-AC52-07NA27344 . The United States Government retains a non-exclusive, paid-up, irrevocable, world-wide license to publish or reproduce the published form of this manuscript, or allow others to do so, for United States Government purposes.

Keywords

Liquid lithium
Liquid metals
Low-recycling
Plasma facing components
Tokamaks
Wall conditioning

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10.1016/j.nme.2025.101949

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Boyle, D. P., Maan, A., Majeski, R., Ostrowski, E., Abe, S., Banerjee, S., Capecchi, W., Elliott, D. B., Hansen, C., Jung, E., Hughes, P. E., Kubota, S., Lampert, M., Maingi, R., McLean, A. G., Menard, J. E., Morales, J. J., & Soukhanovskii, V. A. (2025). Improved liquid lithium surfaces in the Lithium Tokamak Experiment-β. Nuclear Materials and Energy, 43, Article 101949. https://doi.org/10.1016/j.nme.2025.101949

@article{2add018d8bf74f03a2daea88c0e81d53,

title = "Improved liquid lithium surfaces in the Lithium Tokamak Experiment-β",

abstract = "Advances in vacuum, surface, and lithium conditioning techniques throughout five years of continuous operations in LTX-β have produced mirror-like liquid lithium surfaces and demonstrated the feasibility of high-performance tokamak discharges fully surrounded by liquid metal without significant operational problems. Improvements in conditioning techniques and procedures, including many weeks of baking and accumulation of 70 g of Li, led to reduced residual gasses and clean Li surfaces − all while still maintaining enough operational flexibility for multiple in-vacuum diagnostic upgrades and calibrations. Coatings had a visibly clean appearance, with reflective liquid metal demonstrating good wetting and surface adhesion with films that were now macroscopically thick. Solidified Li showed large crystal grains, while surface science measurements observed reduced impurities in the lithium. Steadily improved plasma performance was achieved with liquid lithium, with discharges able to match solid Li in terms of evolution of Ip and ne, including rapid density pumping indicating low recycling. There were indications of moderately increased Li impurity influx, though few significant disturbances by the large liquid surfaces on tokamak operations over hundreds of discharges. Liquid metal plasma facing components are a potential solution to the extreme heat and particle fluxes that could cause unacceptable damage to solid materials, while liquid lithium also has the potential for greatly increased confinement in the low-recycling regime. While many liquid metal approaches are possible, and numerous experiments have been conducted in test stands and small modules in fusion devices, LTX-β is the only tokamak operated while fully surrounded by liquid metal.",

keywords = "Liquid lithium, Liquid metals, Low-recycling, Plasma facing components, Tokamaks, Wall conditioning",

author = "Boyle, \{D. P.\} and A. Maan and R. Majeski and E. Ostrowski and S. Abe and S. Banerjee and W. Capecchi and Elliott, \{D. B.\} and C. Hansen and E. Jung and Hughes, \{P. E.\} and S. Kubota and M. Lampert and R. Maingi and McLean, \{A. G.\} and Menard, \{J. E.\} and Morales, \{J. J.\} and Soukhanovskii, \{V. A.\}",

note = "Publisher Copyright: {\textcopyright} 2025 The Author(s)",

year = "2025",

month = jun,

doi = "10.1016/j.nme.2025.101949",

language = "English",

volume = "43",

journal = "Nuclear Materials and Energy",

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Boyle, DP, Maan, A, Majeski, R, Ostrowski, E, Abe, S, Banerjee, S, Capecchi, W, Elliott, DB, Hansen, C, Jung, E, Hughes, PE, Kubota, S, Lampert, M, Maingi, R, McLean, AG, Menard, JE, Morales, JJ & Soukhanovskii, VA 2025, 'Improved liquid lithium surfaces in the Lithium Tokamak Experiment-β', Nuclear Materials and Energy, vol. 43, 101949. https://doi.org/10.1016/j.nme.2025.101949

TY - JOUR

T1 - Improved liquid lithium surfaces in the Lithium Tokamak Experiment-β

AU - Boyle, D. P.

AU - Maan, A.

AU - Majeski, R.

AU - Ostrowski, E.

AU - Abe, S.

AU - Banerjee, S.

AU - Capecchi, W.

AU - Elliott, D. B.

AU - Hansen, C.

AU - Jung, E.

AU - Hughes, P. E.

AU - Kubota, S.

AU - Lampert, M.

AU - Maingi, R.

AU - McLean, A. G.

AU - Menard, J. E.

AU - Morales, J. J.

AU - Soukhanovskii, V. A.

PY - 2025/6

Y1 - 2025/6

N2 - Advances in vacuum, surface, and lithium conditioning techniques throughout five years of continuous operations in LTX-β have produced mirror-like liquid lithium surfaces and demonstrated the feasibility of high-performance tokamak discharges fully surrounded by liquid metal without significant operational problems. Improvements in conditioning techniques and procedures, including many weeks of baking and accumulation of 70 g of Li, led to reduced residual gasses and clean Li surfaces − all while still maintaining enough operational flexibility for multiple in-vacuum diagnostic upgrades and calibrations. Coatings had a visibly clean appearance, with reflective liquid metal demonstrating good wetting and surface adhesion with films that were now macroscopically thick. Solidified Li showed large crystal grains, while surface science measurements observed reduced impurities in the lithium. Steadily improved plasma performance was achieved with liquid lithium, with discharges able to match solid Li in terms of evolution of Ip and ne, including rapid density pumping indicating low recycling. There were indications of moderately increased Li impurity influx, though few significant disturbances by the large liquid surfaces on tokamak operations over hundreds of discharges. Liquid metal plasma facing components are a potential solution to the extreme heat and particle fluxes that could cause unacceptable damage to solid materials, while liquid lithium also has the potential for greatly increased confinement in the low-recycling regime. While many liquid metal approaches are possible, and numerous experiments have been conducted in test stands and small modules in fusion devices, LTX-β is the only tokamak operated while fully surrounded by liquid metal.

AB - Advances in vacuum, surface, and lithium conditioning techniques throughout five years of continuous operations in LTX-β have produced mirror-like liquid lithium surfaces and demonstrated the feasibility of high-performance tokamak discharges fully surrounded by liquid metal without significant operational problems. Improvements in conditioning techniques and procedures, including many weeks of baking and accumulation of 70 g of Li, led to reduced residual gasses and clean Li surfaces − all while still maintaining enough operational flexibility for multiple in-vacuum diagnostic upgrades and calibrations. Coatings had a visibly clean appearance, with reflective liquid metal demonstrating good wetting and surface adhesion with films that were now macroscopically thick. Solidified Li showed large crystal grains, while surface science measurements observed reduced impurities in the lithium. Steadily improved plasma performance was achieved with liquid lithium, with discharges able to match solid Li in terms of evolution of Ip and ne, including rapid density pumping indicating low recycling. There were indications of moderately increased Li impurity influx, though few significant disturbances by the large liquid surfaces on tokamak operations over hundreds of discharges. Liquid metal plasma facing components are a potential solution to the extreme heat and particle fluxes that could cause unacceptable damage to solid materials, while liquid lithium also has the potential for greatly increased confinement in the low-recycling regime. While many liquid metal approaches are possible, and numerous experiments have been conducted in test stands and small modules in fusion devices, LTX-β is the only tokamak operated while fully surrounded by liquid metal.

KW - Liquid lithium

KW - Liquid metals

KW - Low-recycling

KW - Plasma facing components

KW - Tokamaks

KW - Wall conditioning

UR - https://www.scopus.com/pages/publications/105005085472

U2 - 10.1016/j.nme.2025.101949

DO - 10.1016/j.nme.2025.101949

M3 - Article

AN - SCOPUS:105005085472

SN - 2352-1791

VL - 43

JO - Nuclear Materials and Energy

JF - Nuclear Materials and Energy

M1 - 101949

ER -

Improved liquid lithium surfaces in the Lithium Tokamak Experiment-β

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