Injected mass deposition thresholds for lithium granule instigated triggering of edge localized modes on EAST

R. Lunsford; Z. Sun; R. Maingi; J. S. Hu; D. Mansfield; W. Xu; G. Z. Zuo; A. Diallo; T. Osborne; K. Tritz; J. Canik; M. Huang; X. C. Meng; X. Z. Gong; B. N. Wan; J. G. Li

doi:10.1088/1741-4326/aaa2ac

Injected mass deposition thresholds for lithium granule instigated triggering of edge localized modes on EAST

R. Lunsford, Z. Sun, R. Maingi, J. S. Hu, D. Mansfield, W. Xu, G. Z. Zuo, A. Diallo, T. Osborne, K. Tritz, J. Canik, M. Huang, X. C. Meng, X. Z. Gong, B. N. Wan, J. G. Li

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

33 Scopus citations

Abstract

The ability of an injected lithium granule to promptly trigger an edge localized mode (ELM) has been established in multiple experiments. By horizontally injecting granules ranging in diameter from 200 microns to 1 mm in diameter into the low field side of EAST H-mode discharges we have determined that granules with diameter >600 microns are successful in triggering ELMs more than 95% of the time. It was also demonstrated that below 600 microns the triggering efficiency decreased roughly with granule size. Granules were radially injected from the outer midplane with velocities ∼80 m s^-1 into EAST upper single null discharges with an ITER like tungsten monoblock divertor. These granules were individually tracked throughout their injection cycle in order to determine their efficacy at triggering an ELM. For those granules of sufficient size, ELM triggering was a prompt response to granule injection. By simulating the granule injection with an experimentally benchmarked neutral gas shielding (NGS) model, the ablatant mass deposition required to promptly trigger an ELM is calculated and the fractional mass deposition is determined.

Original language	English (US)
Article number	036007
Journal	Nuclear Fusion
Volume	58
Issue number	3
DOIs	https://doi.org/10.1088/1741-4326/aaa2ac
State	Published - Jan 16 2018

All Science Journal Classification (ASJC) codes

Nuclear and High Energy Physics
Condensed Matter Physics

Keywords

EAST
ELM triggering
Granule injection
lithium

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10.1088/1741-4326/aaa2ac

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Lunsford, R., Sun, Z., Maingi, R., Hu, J. S., Mansfield, D., Xu, W., Zuo, G. Z., Diallo, A., Osborne, T., Tritz, K., Canik, J., Huang, M., Meng, X. C., Gong, X. Z., Wan, B. N., & Li, J. G. (2018). Injected mass deposition thresholds for lithium granule instigated triggering of edge localized modes on EAST. Nuclear Fusion, 58(3), Article 036007. https://doi.org/10.1088/1741-4326/aaa2ac

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title = "Injected mass deposition thresholds for lithium granule instigated triggering of edge localized modes on EAST",

abstract = "The ability of an injected lithium granule to promptly trigger an edge localized mode (ELM) has been established in multiple experiments. By horizontally injecting granules ranging in diameter from 200 microns to 1 mm in diameter into the low field side of EAST H-mode discharges we have determined that granules with diameter >600 microns are successful in triggering ELMs more than 95\% of the time. It was also demonstrated that below 600 microns the triggering efficiency decreased roughly with granule size. Granules were radially injected from the outer midplane with velocities ∼80 m s-1 into EAST upper single null discharges with an ITER like tungsten monoblock divertor. These granules were individually tracked throughout their injection cycle in order to determine their efficacy at triggering an ELM. For those granules of sufficient size, ELM triggering was a prompt response to granule injection. By simulating the granule injection with an experimentally benchmarked neutral gas shielding (NGS) model, the ablatant mass deposition required to promptly trigger an ELM is calculated and the fractional mass deposition is determined.",

keywords = "EAST, ELM triggering, Granule injection, lithium",

author = "R. Lunsford and Z. Sun and R. Maingi and Hu, \{J. S.\} and D. Mansfield and W. Xu and Zuo, \{G. Z.\} and A. Diallo and T. Osborne and K. Tritz and J. Canik and M. Huang and Meng, \{X. C.\} and Gong, \{X. Z.\} and Wan, \{B. N.\} and Li, \{J. G.\}",

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year = "2018",

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doi = "10.1088/1741-4326/aaa2ac",

language = "English (US)",

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AU - Lunsford, R.

AU - Sun, Z.

AU - Maingi, R.

AU - Hu, J. S.

AU - Mansfield, D.

AU - Xu, W.

AU - Zuo, G. Z.

AU - Diallo, A.

AU - Osborne, T.

AU - Tritz, K.

AU - Canik, J.

AU - Huang, M.

AU - Meng, X. C.

AU - Gong, X. Z.

AU - Wan, B. N.

AU - Li, J. G.

PY - 2018/1/16

Y1 - 2018/1/16

N2 - The ability of an injected lithium granule to promptly trigger an edge localized mode (ELM) has been established in multiple experiments. By horizontally injecting granules ranging in diameter from 200 microns to 1 mm in diameter into the low field side of EAST H-mode discharges we have determined that granules with diameter >600 microns are successful in triggering ELMs more than 95% of the time. It was also demonstrated that below 600 microns the triggering efficiency decreased roughly with granule size. Granules were radially injected from the outer midplane with velocities ∼80 m s-1 into EAST upper single null discharges with an ITER like tungsten monoblock divertor. These granules were individually tracked throughout their injection cycle in order to determine their efficacy at triggering an ELM. For those granules of sufficient size, ELM triggering was a prompt response to granule injection. By simulating the granule injection with an experimentally benchmarked neutral gas shielding (NGS) model, the ablatant mass deposition required to promptly trigger an ELM is calculated and the fractional mass deposition is determined.

AB - The ability of an injected lithium granule to promptly trigger an edge localized mode (ELM) has been established in multiple experiments. By horizontally injecting granules ranging in diameter from 200 microns to 1 mm in diameter into the low field side of EAST H-mode discharges we have determined that granules with diameter >600 microns are successful in triggering ELMs more than 95% of the time. It was also demonstrated that below 600 microns the triggering efficiency decreased roughly with granule size. Granules were radially injected from the outer midplane with velocities ∼80 m s-1 into EAST upper single null discharges with an ITER like tungsten monoblock divertor. These granules were individually tracked throughout their injection cycle in order to determine their efficacy at triggering an ELM. For those granules of sufficient size, ELM triggering was a prompt response to granule injection. By simulating the granule injection with an experimentally benchmarked neutral gas shielding (NGS) model, the ablatant mass deposition required to promptly trigger an ELM is calculated and the fractional mass deposition is determined.

KW - EAST

KW - ELM triggering

KW - Granule injection

KW - lithium

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SN - 0029-5515

VL - 58

JO - Nuclear Fusion

JF - Nuclear Fusion

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ER -

Injected mass deposition thresholds for lithium granule instigated triggering of edge localized modes on EAST

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