Lithium wall conditioning techniques in ADITYA-U tokamak for impurity and fuel control

K. A. Jadeja; J. Ghosh; Nandini Yadava; K. M. Patel; Kiran Patel; R. L. Tanna; R. Manchanda; M. B. Chowdhuri; J. V. Raval; U. C. Nagora; B. G. Arambhadiya; Tanmay Macwan; K. Singh; S. Dolui; Minsha Shah; Sharvil Patel; N. Ramaiya; Kajal Shah; B. K. Shukla; Suman Aich; Rohit Kumar; V. K. Panchal; Manoj Kumar; P. K. Atrey; S. K. Pathak; Rachana Rajpal; Kumudni Assudani; M. V. Gopalakrishna; Devilal Kumawat; M. N. Makwana; K. S. Shah; Shivam Gupta; C. N. Gupta; V. Balakrishnan; P. K. Chattopadhyay; B. R. Kataria

doi:10.1088/1741-4326/ac35a0

Lithium wall conditioning techniques in ADITYA-U tokamak for impurity and fuel control

K. A. Jadeja, J. Ghosh, Nandini Yadava, K. M. Patel, Kiran Patel, R. L. Tanna, R. Manchanda, M. B. Chowdhuri, J. V. Raval, U. C. Nagora, B. G. Arambhadiya, Tanmay Macwan, K. Singh, S. Dolui, Minsha Shah, Sharvil Patel, N. Ramaiya, Kajal Shah, B. K. Shukla, Suman AichRohit Kumar, V. K. Panchal, Manoj Kumar, P. K. Atrey, S. K. Pathak, Rachana Rajpal, Kumudni Assudani, M. V. Gopalakrishna, Devilal Kumawat, M. N. Makwana, K. S. Shah, Shivam Gupta, C. N. Gupta, V. Balakrishnan, P. K. Chattopadhyay, B. R. Kataria

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

9 Scopus citations

Abstract

In fusion devices, various techniques are employed for coating the plasma facing components (PFCs) including the vessel wall with low-Z material like lithium, boron, and silicon in order to enhance the plasma parameters and control. In ADITYA-Upgrade tokamak, different techniques of lithium wall conditioning are developed and implemented to obtain uniform and sustainable coating of Li on PFCs and the vessel wall. In this paper, two techniques used to generate Li from the source are reported. In one of the technique, a heated (fixed temperature of ~120 °C) Li-rod is placed inside the hydrogen glow discharge cleaning (H-GDC) plasma and the sputtered Li by hydrogen (H) ions and atoms coats the wall and periphery. In the second technique, the Li is vapourized using a high-temperature Li-evaporator and released into the H-GDC plasma for uniform coating of Li on the PFCs and vessel. Significantly enhanced plasma parameters are obtained after Li coating by both techniques, with the evaporated Li performed better than the Li rod case. With the Li coating obtained with evaporated Li at 600 °C (550 mg Li) with H-GDC, the Li wall conditioning has been observed to be sustaining for in a larger number of plasma discharges in comparison to non-H-GDC assisted Li deposition. As the melting temperature of lithium hydride (LiH) is much higher (688.7 °C) than that of lithium (180.5 °C), this enhance the longer Li-coating lifetime relatively due to the formation of Li-H molecules on the vessel wall and PFCs. In ADITYA-U the carbon impurity and hydrogen recycling, due to relatively high surface area of graphite PFCs as well as their proximity to the plasma, limits the plasma performance and effective controls. Hence, H-GDC, H-GDC with Li-rod sputtering or Li evaporation, helium-GDC, argon-hydrogen mixtures-GDC in particular sequence are carried out to obtain better plasma discharges. The Li coating techniques and their effect on tokamak plasma discharges of ADITYA-U are discussed in this paper.

Original language	English (US)
Article number	016003
Journal	Nuclear Fusion
Volume	62
Issue number	1
DOIs	https://doi.org/10.1088/1741-4326/ac35a0
State	Published - Jan 2022
Externally published	Yes

All Science Journal Classification (ASJC) codes

Nuclear and High Energy Physics
Condensed Matter Physics

Keywords

lithium wall conditioning
plasma facing components
tokamak

Access to Document

10.1088/1741-4326/ac35a0

Cite this

Jadeja, K. A., Ghosh, J., Yadava, N., Patel, K. M., Patel, K., Tanna, R. L., Manchanda, R., Chowdhuri, M. B., Raval, J. V., Nagora, U. C., Arambhadiya, B. G., Macwan, T., Singh, K., Dolui, S., Shah, M., Patel, S., Ramaiya, N., Shah, K., Shukla, B. K., ... Kataria, B. R. (2022). Lithium wall conditioning techniques in ADITYA-U tokamak for impurity and fuel control. Nuclear Fusion, 62(1), Article 016003. https://doi.org/10.1088/1741-4326/ac35a0

@article{e83e903ebae44238ba7db7af442118c5,

title = "Lithium wall conditioning techniques in ADITYA-U tokamak for impurity and fuel control",

abstract = "In fusion devices, various techniques are employed for coating the plasma facing components (PFCs) including the vessel wall with low-Z material like lithium, boron, and silicon in order to enhance the plasma parameters and control. In ADITYA-Upgrade tokamak, different techniques of lithium wall conditioning are developed and implemented to obtain uniform and sustainable coating of Li on PFCs and the vessel wall. In this paper, two techniques used to generate Li from the source are reported. In one of the technique, a heated (fixed temperature of \textasciitilde{}120 °C) Li-rod is placed inside the hydrogen glow discharge cleaning (H-GDC) plasma and the sputtered Li by hydrogen (H) ions and atoms coats the wall and periphery. In the second technique, the Li is vapourized using a high-temperature Li-evaporator and released into the H-GDC plasma for uniform coating of Li on the PFCs and vessel. Significantly enhanced plasma parameters are obtained after Li coating by both techniques, with the evaporated Li performed better than the Li rod case. With the Li coating obtained with evaporated Li at 600 °C (550 mg Li) with H-GDC, the Li wall conditioning has been observed to be sustaining for in a larger number of plasma discharges in comparison to non-H-GDC assisted Li deposition. As the melting temperature of lithium hydride (LiH) is much higher (688.7 °C) than that of lithium (180.5 °C), this enhance the longer Li-coating lifetime relatively due to the formation of Li-H molecules on the vessel wall and PFCs. In ADITYA-U the carbon impurity and hydrogen recycling, due to relatively high surface area of graphite PFCs as well as their proximity to the plasma, limits the plasma performance and effective controls. Hence, H-GDC, H-GDC with Li-rod sputtering or Li evaporation, helium-GDC, argon-hydrogen mixtures-GDC in particular sequence are carried out to obtain better plasma discharges. The Li coating techniques and their effect on tokamak plasma discharges of ADITYA-U are discussed in this paper.",

keywords = "lithium wall conditioning, plasma facing components, tokamak",

author = "Jadeja, \{K. A.\} and J. Ghosh and Nandini Yadava and Patel, \{K. M.\} and Kiran Patel and Tanna, \{R. L.\} and R. Manchanda and Chowdhuri, \{M. B.\} and Raval, \{J. V.\} and Nagora, \{U. C.\} and Arambhadiya, \{B. G.\} and Tanmay Macwan and K. Singh and S. Dolui and Minsha Shah and Sharvil Patel and N. Ramaiya and Kajal Shah and Shukla, \{B. K.\} and Suman Aich and Rohit Kumar and Panchal, \{V. K.\} and Manoj Kumar and Atrey, \{P. K.\} and Pathak, \{S. K.\} and Rachana Rajpal and Kumudni Assudani and Gopalakrishna, \{M. V.\} and Devilal Kumawat and Makwana, \{M. N.\} and Shah, \{K. S.\} and Shivam Gupta and Gupta, \{C. N.\} and V. Balakrishnan and Chattopadhyay, \{P. K.\} and Kataria, \{B. R.\}",

note = "Publisher Copyright: {\textcopyright} 2021 IAEA, Vienna.",

year = "2022",

month = jan,

doi = "10.1088/1741-4326/ac35a0",

language = "English (US)",

volume = "62",

journal = "Nuclear Fusion",

issn = "0029-5515",

publisher = "IOP Publishing Ltd.",

number = "1",

}

Jadeja, KA, Ghosh, J, Yadava, N, Patel, KM, Patel, K, Tanna, RL, Manchanda, R, Chowdhuri, MB, Raval, JV, Nagora, UC, Arambhadiya, BG, Macwan, T, Singh, K, Dolui, S, Shah, M, Patel, S, Ramaiya, N, Shah, K, Shukla, BK, Aich, S, Kumar, R, Panchal, VK, Kumar, M, Atrey, PK, Pathak, SK, Rajpal, R, Assudani, K, Gopalakrishna, MV, Kumawat, D, Makwana, MN, Shah, KS, Gupta, S, Gupta, CN, Balakrishnan, V, Chattopadhyay, PK & Kataria, BR 2022, 'Lithium wall conditioning techniques in ADITYA-U tokamak for impurity and fuel control', Nuclear Fusion, vol. 62, no. 1, 016003. https://doi.org/10.1088/1741-4326/ac35a0

TY - JOUR

T1 - Lithium wall conditioning techniques in ADITYA-U tokamak for impurity and fuel control

AU - Jadeja, K. A.

AU - Ghosh, J.

AU - Yadava, Nandini

AU - Patel, K. M.

AU - Patel, Kiran

AU - Tanna, R. L.

AU - Manchanda, R.

AU - Chowdhuri, M. B.

AU - Raval, J. V.

AU - Nagora, U. C.

AU - Arambhadiya, B. G.

AU - Macwan, Tanmay

AU - Singh, K.

AU - Dolui, S.

AU - Shah, Minsha

AU - Patel, Sharvil

AU - Ramaiya, N.

AU - Shah, Kajal

AU - Shukla, B. K.

AU - Aich, Suman

AU - Kumar, Rohit

AU - Panchal, V. K.

AU - Kumar, Manoj

AU - Atrey, P. K.

AU - Pathak, S. K.

AU - Rajpal, Rachana

AU - Assudani, Kumudni

AU - Gopalakrishna, M. V.

AU - Kumawat, Devilal

AU - Makwana, M. N.

AU - Shah, K. S.

AU - Gupta, Shivam

AU - Gupta, C. N.

AU - Balakrishnan, V.

AU - Chattopadhyay, P. K.

AU - Kataria, B. R.

PY - 2022/1

Y1 - 2022/1

N2 - In fusion devices, various techniques are employed for coating the plasma facing components (PFCs) including the vessel wall with low-Z material like lithium, boron, and silicon in order to enhance the plasma parameters and control. In ADITYA-Upgrade tokamak, different techniques of lithium wall conditioning are developed and implemented to obtain uniform and sustainable coating of Li on PFCs and the vessel wall. In this paper, two techniques used to generate Li from the source are reported. In one of the technique, a heated (fixed temperature of ~120 °C) Li-rod is placed inside the hydrogen glow discharge cleaning (H-GDC) plasma and the sputtered Li by hydrogen (H) ions and atoms coats the wall and periphery. In the second technique, the Li is vapourized using a high-temperature Li-evaporator and released into the H-GDC plasma for uniform coating of Li on the PFCs and vessel. Significantly enhanced plasma parameters are obtained after Li coating by both techniques, with the evaporated Li performed better than the Li rod case. With the Li coating obtained with evaporated Li at 600 °C (550 mg Li) with H-GDC, the Li wall conditioning has been observed to be sustaining for in a larger number of plasma discharges in comparison to non-H-GDC assisted Li deposition. As the melting temperature of lithium hydride (LiH) is much higher (688.7 °C) than that of lithium (180.5 °C), this enhance the longer Li-coating lifetime relatively due to the formation of Li-H molecules on the vessel wall and PFCs. In ADITYA-U the carbon impurity and hydrogen recycling, due to relatively high surface area of graphite PFCs as well as their proximity to the plasma, limits the plasma performance and effective controls. Hence, H-GDC, H-GDC with Li-rod sputtering or Li evaporation, helium-GDC, argon-hydrogen mixtures-GDC in particular sequence are carried out to obtain better plasma discharges. The Li coating techniques and their effect on tokamak plasma discharges of ADITYA-U are discussed in this paper.

AB - In fusion devices, various techniques are employed for coating the plasma facing components (PFCs) including the vessel wall with low-Z material like lithium, boron, and silicon in order to enhance the plasma parameters and control. In ADITYA-Upgrade tokamak, different techniques of lithium wall conditioning are developed and implemented to obtain uniform and sustainable coating of Li on PFCs and the vessel wall. In this paper, two techniques used to generate Li from the source are reported. In one of the technique, a heated (fixed temperature of ~120 °C) Li-rod is placed inside the hydrogen glow discharge cleaning (H-GDC) plasma and the sputtered Li by hydrogen (H) ions and atoms coats the wall and periphery. In the second technique, the Li is vapourized using a high-temperature Li-evaporator and released into the H-GDC plasma for uniform coating of Li on the PFCs and vessel. Significantly enhanced plasma parameters are obtained after Li coating by both techniques, with the evaporated Li performed better than the Li rod case. With the Li coating obtained with evaporated Li at 600 °C (550 mg Li) with H-GDC, the Li wall conditioning has been observed to be sustaining for in a larger number of plasma discharges in comparison to non-H-GDC assisted Li deposition. As the melting temperature of lithium hydride (LiH) is much higher (688.7 °C) than that of lithium (180.5 °C), this enhance the longer Li-coating lifetime relatively due to the formation of Li-H molecules on the vessel wall and PFCs. In ADITYA-U the carbon impurity and hydrogen recycling, due to relatively high surface area of graphite PFCs as well as their proximity to the plasma, limits the plasma performance and effective controls. Hence, H-GDC, H-GDC with Li-rod sputtering or Li evaporation, helium-GDC, argon-hydrogen mixtures-GDC in particular sequence are carried out to obtain better plasma discharges. The Li coating techniques and their effect on tokamak plasma discharges of ADITYA-U are discussed in this paper.

KW - lithium wall conditioning

KW - plasma facing components

KW - tokamak

UR - https://www.scopus.com/pages/publications/85122642222

UR - https://www.scopus.com/inward/citedby.url?scp=85122642222&partnerID=8YFLogxK

U2 - 10.1088/1741-4326/ac35a0

DO - 10.1088/1741-4326/ac35a0

M3 - Article

AN - SCOPUS:85122642222

SN - 0029-5515

VL - 62

JO - Nuclear Fusion

JF - Nuclear Fusion

IS - 1

M1 - 016003

ER -

Lithium wall conditioning techniques in ADITYA-U tokamak for impurity and fuel control

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