Modelling of lithium erosion and transport in FTU lithium experiments

R. Ding; G. Maddaluno; M. L. Apicella; G. Mazzitelli; V. Pericoli Ridolfini; A. Kirschner; J. L. Chen; J. G. Li; G. N. Luo

doi:10.1016/j.jnucmat.2013.01.146

Modelling of lithium erosion and transport in FTU lithium experiments

R. Ding
, G. Maddaluno
, M. L. Apicella
, G. Mazzitelli
, V. Pericoli Ridolfini
, A. Kirschner
, J. L. Chen
, J. G. Li
, G. N. Luo

School of Electrical Engineering

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

10 Scopus citations

Abstract

The ERO code has been used to simulate lithium erosion, transport and re-deposition from liquid lithium limiter experiments in FTU. Two different operational cases from LLL experiments with different plasma parameters and surface temperature are modelled. According to the effective lithium sputtering yields, for both cases the lithium erosion is mainly due to physical sputtering rather than evaporation. Furthermore, the modelled re-deposition fraction of evaporated lithium is much higher than that of sputtered lithium, which is due to the shorter ionisation mean free path of thermal lithium atoms. Therefore, the evaporation erosion effect can be neglected compared to physical sputtering when the surface temperature is below 450 °C. According to the simulations, most of the lithium impurities exist in the form of Li⁺, and the main plasma contamination by lithium ions is low because most of eroded lithium particles are not transported into the core plasma and stay outside of the LCFS.

Original language	English
Pages (from-to)	S690-S693
Journal	Journal of Nuclear Materials
Volume	438
Issue number	SUPPL
DOIs	https://doi.org/10.1016/j.jnucmat.2013.01.146
State	Published - 2013

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10.1016/j.jnucmat.2013.01.146

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title = "Modelling of lithium erosion and transport in FTU lithium experiments",

abstract = "The ERO code has been used to simulate lithium erosion, transport and re-deposition from liquid lithium limiter experiments in FTU. Two different operational cases from LLL experiments with different plasma parameters and surface temperature are modelled. According to the effective lithium sputtering yields, for both cases the lithium erosion is mainly due to physical sputtering rather than evaporation. Furthermore, the modelled re-deposition fraction of evaporated lithium is much higher than that of sputtered lithium, which is due to the shorter ionisation mean free path of thermal lithium atoms. Therefore, the evaporation erosion effect can be neglected compared to physical sputtering when the surface temperature is below 450 °C. According to the simulations, most of the lithium impurities exist in the form of Li+, and the main plasma contamination by lithium ions is low because most of eroded lithium particles are not transported into the core plasma and stay outside of the LCFS.",

author = "R. Ding and G. Maddaluno and Apicella, \{M. L.\} and G. Mazzitelli and \{Pericoli Ridolfini\}, V. and A. Kirschner and Chen, \{J. L.\} and Li, \{J. G.\} and Luo, \{G. N.\}",

year = "2013",

doi = "10.1016/j.jnucmat.2013.01.146",

language = "英语",

volume = "438",

pages = "S690--S693",

journal = "Journal of Nuclear Materials",

issn = "0022-3115",

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TY - JOUR

T1 - Modelling of lithium erosion and transport in FTU lithium experiments

AU - Ding, R.

AU - Maddaluno, G.

AU - Apicella, M. L.

AU - Mazzitelli, G.

AU - Pericoli Ridolfini, V.

AU - Kirschner, A.

AU - Chen, J. L.

AU - Li, J. G.

AU - Luo, G. N.

PY - 2013

Y1 - 2013

N2 - The ERO code has been used to simulate lithium erosion, transport and re-deposition from liquid lithium limiter experiments in FTU. Two different operational cases from LLL experiments with different plasma parameters and surface temperature are modelled. According to the effective lithium sputtering yields, for both cases the lithium erosion is mainly due to physical sputtering rather than evaporation. Furthermore, the modelled re-deposition fraction of evaporated lithium is much higher than that of sputtered lithium, which is due to the shorter ionisation mean free path of thermal lithium atoms. Therefore, the evaporation erosion effect can be neglected compared to physical sputtering when the surface temperature is below 450 °C. According to the simulations, most of the lithium impurities exist in the form of Li+, and the main plasma contamination by lithium ions is low because most of eroded lithium particles are not transported into the core plasma and stay outside of the LCFS.

AB - The ERO code has been used to simulate lithium erosion, transport and re-deposition from liquid lithium limiter experiments in FTU. Two different operational cases from LLL experiments with different plasma parameters and surface temperature are modelled. According to the effective lithium sputtering yields, for both cases the lithium erosion is mainly due to physical sputtering rather than evaporation. Furthermore, the modelled re-deposition fraction of evaporated lithium is much higher than that of sputtered lithium, which is due to the shorter ionisation mean free path of thermal lithium atoms. Therefore, the evaporation erosion effect can be neglected compared to physical sputtering when the surface temperature is below 450 °C. According to the simulations, most of the lithium impurities exist in the form of Li+, and the main plasma contamination by lithium ions is low because most of eroded lithium particles are not transported into the core plasma and stay outside of the LCFS.

UR - https://www.scopus.com/pages/publications/84885485505

U2 - 10.1016/j.jnucmat.2013.01.146

DO - 10.1016/j.jnucmat.2013.01.146

M3 - 文章

AN - SCOPUS:84885485505

SN - 0022-3115

VL - 438

SP - S690-S693

JO - Journal of Nuclear Materials

JF - Journal of Nuclear Materials

IS - SUPPL

ER -

Modelling of lithium erosion and transport in FTU lithium experiments

Abstract

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