Long pulse EBW start-up experiments in MAST

V. F. Shevchenko; Y. F. Baranov; T. Bigelow; J. B. Caughman; S. Diem; C. Dukes; P. Finburg; J. Hawes; C. Gurl; J. Griffiths; J. Mailloux; M. Peng; A. N. Saveliev; Y. Takase; H. Tanaka; G. Taylor

doi:10.1051/epjconf/20158702007

Long pulse EBW start-up experiments in MAST

V. F. Shevchenko, Y. F. Baranov, T. Bigelow, J. B. Caughman, S. Diem, C. Dukes, P. Finburg, J. Hawes, C. Gurl, J. Griffiths, J. Mailloux, M. Peng, A. N. Saveliev, Y. Takase, H. Tanaka, G. Taylor

Fusion Technology

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20 Scopus citations

Abstract

Start-up technique reported here relies on a double mode conversion (MC) for electron Bernstein wave (EBW) excitation. It consists of MC of the ordinary (O) mode, entering the plasma from the low field side of the tokamak, into the extraordinary (X) mode at a mirror-polarizer located at the high field side. The X mode propagates back to the plasma, passes through electron cyclotron resonance (ECR) and experiences a subsequent X to EBW MC near the upper hybrid resonance (UHR). Finally the excited EBW mode is totally absorbed at the Doppler shifted ECR. The absorption of EBW remains high even in cold rarefied plasmas. Furthermore, EBW can generate significant plasma current giving the prospect of a fully solenoid-free plasma start-up. First experiments using this scheme were carried out on MAST [1]. Plasma currents up to 33 kA have been achieved using 28 GHz 100kW 90ms RF pulses. Recently experimental results were extended to longer RF pulses showing further increase of plasma currents generated by RF power alone. A record current of 73kA has been achieved with 450ms RF pulse of similar power. The current drive enhancement was mainly achieved due to RF pulse extension and further optimisation of the start-up scenario.

Original language	English
Article number	02007
Journal	EPJ Web of Conferences
Volume	87
DOIs	https://doi.org/10.1051/epjconf/20158702007
State	Published - Mar 12 2015
Event	18th Joint Workshop on Electron Cyclotron Emission and Electron Cyclotron Resonance Heating, EC 2014 - Nara, Japan Duration: Apr 22 2014 → Apr 25 2014

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title = "Long pulse EBW start-up experiments in MAST",

abstract = "Start-up technique reported here relies on a double mode conversion (MC) for electron Bernstein wave (EBW) excitation. It consists of MC of the ordinary (O) mode, entering the plasma from the low field side of the tokamak, into the extraordinary (X) mode at a mirror-polarizer located at the high field side. The X mode propagates back to the plasma, passes through electron cyclotron resonance (ECR) and experiences a subsequent X to EBW MC near the upper hybrid resonance (UHR). Finally the excited EBW mode is totally absorbed at the Doppler shifted ECR. The absorption of EBW remains high even in cold rarefied plasmas. Furthermore, EBW can generate significant plasma current giving the prospect of a fully solenoid-free plasma start-up. First experiments using this scheme were carried out on MAST [1]. Plasma currents up to 33 kA have been achieved using 28 GHz 100kW 90ms RF pulses. Recently experimental results were extended to longer RF pulses showing further increase of plasma currents generated by RF power alone. A record current of 73kA has been achieved with 450ms RF pulse of similar power. The current drive enhancement was mainly achieved due to RF pulse extension and further optimisation of the start-up scenario.",

author = "Shevchenko, {V. F.} and Baranov, {Y. F.} and T. Bigelow and Caughman, {J. B.} and S. Diem and C. Dukes and P. Finburg and J. Hawes and C. Gurl and J. Griffiths and J. Mailloux and M. Peng and Saveliev, {A. N.} and Y. Takase and H. Tanaka and G. Taylor",

note = "Publisher Copyright: {\textcopyright} Owned by the authors, published by EDP Sciences, 2015.; 18th Joint Workshop on Electron Cyclotron Emission and Electron Cyclotron Resonance Heating, EC 2014 ; Conference date: 22-04-2014 Through 25-04-2014",

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doi = "10.1051/epjconf/20158702007",

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TY - JOUR

T1 - Long pulse EBW start-up experiments in MAST

AU - Shevchenko, V. F.

AU - Baranov, Y. F.

AU - Bigelow, T.

AU - Caughman, J. B.

AU - Diem, S.

AU - Dukes, C.

AU - Finburg, P.

AU - Hawes, J.

AU - Gurl, C.

AU - Griffiths, J.

AU - Mailloux, J.

AU - Peng, M.

AU - Saveliev, A. N.

AU - Takase, Y.

AU - Tanaka, H.

AU - Taylor, G.

PY - 2015/3/12

Y1 - 2015/3/12

N2 - Start-up technique reported here relies on a double mode conversion (MC) for electron Bernstein wave (EBW) excitation. It consists of MC of the ordinary (O) mode, entering the plasma from the low field side of the tokamak, into the extraordinary (X) mode at a mirror-polarizer located at the high field side. The X mode propagates back to the plasma, passes through electron cyclotron resonance (ECR) and experiences a subsequent X to EBW MC near the upper hybrid resonance (UHR). Finally the excited EBW mode is totally absorbed at the Doppler shifted ECR. The absorption of EBW remains high even in cold rarefied plasmas. Furthermore, EBW can generate significant plasma current giving the prospect of a fully solenoid-free plasma start-up. First experiments using this scheme were carried out on MAST [1]. Plasma currents up to 33 kA have been achieved using 28 GHz 100kW 90ms RF pulses. Recently experimental results were extended to longer RF pulses showing further increase of plasma currents generated by RF power alone. A record current of 73kA has been achieved with 450ms RF pulse of similar power. The current drive enhancement was mainly achieved due to RF pulse extension and further optimisation of the start-up scenario.

AB - Start-up technique reported here relies on a double mode conversion (MC) for electron Bernstein wave (EBW) excitation. It consists of MC of the ordinary (O) mode, entering the plasma from the low field side of the tokamak, into the extraordinary (X) mode at a mirror-polarizer located at the high field side. The X mode propagates back to the plasma, passes through electron cyclotron resonance (ECR) and experiences a subsequent X to EBW MC near the upper hybrid resonance (UHR). Finally the excited EBW mode is totally absorbed at the Doppler shifted ECR. The absorption of EBW remains high even in cold rarefied plasmas. Furthermore, EBW can generate significant plasma current giving the prospect of a fully solenoid-free plasma start-up. First experiments using this scheme were carried out on MAST [1]. Plasma currents up to 33 kA have been achieved using 28 GHz 100kW 90ms RF pulses. Recently experimental results were extended to longer RF pulses showing further increase of plasma currents generated by RF power alone. A record current of 73kA has been achieved with 450ms RF pulse of similar power. The current drive enhancement was mainly achieved due to RF pulse extension and further optimisation of the start-up scenario.

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DO - 10.1051/epjconf/20158702007

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JO - EPJ Web of Conferences

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T2 - 18th Joint Workshop on Electron Cyclotron Emission and Electron Cyclotron Resonance Heating, EC 2014

Y2 - 22 April 2014 through 25 April 2014

ER -

Long pulse EBW start-up experiments in MAST

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