1 Electron Bernstein Wave Research and Plans Gary Taylor Presentation to the 16th NSTX Program Advisory Committee September 9, 2004.

Slides:

Advertisements

Similar presentations

JongGab Jo, H. Y. Lee, Y. H. An, K. J. Chung and Y. S. Hwang* Effective pre-ionization using fundamental extraordinary mode with XB mode conversion in.

Advertisements

14th IEA RFP Workshop RF Heating and Current Drive Experiments on MST Jay Anderson for the MST team.

Active Control of MHD Stability, Austin, 3-5 November 2003J.A. Hoekzema, FZ-Juelich / IPP Association EURATOM-FOM FOM-Instituut voor Plasmafysica “Rijnhuizen”

ELECTRON CYCLOTRON SYSTEM FOR KSTAR US-Korea Workshop Opportunities for Expanded Fusion Science and Technology Collaborations with the KSTAR Project Presented.

Fundamental X-mode Electron Cyclotron Current Drive using Remote-Steering Symmetric Direction Antenna at Larger Steering Angles H. Idei 1, K. Hanada 1,

1 ST workshop 2008 Conception of LHCD Experiments on the Spherical Tokamak Globus-M O.N. Shcherbinin, V.V. Dyachenko, M.A. Irzak, S.A. Khitrov A.F.Ioffe.

C. Kessel Princeton Plasma Physics Laboratory For the NSTX National Team DOE Review of NSTX Five-Year Research Program Proposal June 30 – July 2, 2003.

1 NSTX Wave-Particle Plans Revision 2.3 9/10/07 Supported by Office of Science Culham Sci Ctr U St. Andrews York U Chubu U Fukui U Hiroshima.

ECRF Heating on CS Reactors T.K. Mau UC-San Diego With input from L.P. Ku (PPPL), J.F. Lyon (ORNL), X.R. Wang (UCSD) ARIES Project Meeting May 6-7, 2003.

1 Association Euratom-Cea TORE SUPRA Tore Supra “Fast Particles” Experiments LH SOL Generated Fast Particles Meeting Association Euratom IPP.CR, Prague.

Profile Measurement of HSX Plasma Using Thomson Scattering K. Zhai, F.S.B. Anderson, J. Canik, K. Likin, K. J. Willis, D.T. Anderson, HSX Plasma Laboratory,

1 XP720: EBW Emission in H-Mode Plasmas S.J. Diem Presented at the 2007 NSTX Results Review July 23-24, 2007.

Exploring ECRF Heating on CS Reactors T.K. Mau UC-San Diego ARIES Project Meeting January 8-10, 2003 University of California-San Diego.

Initial Exploration of HHFW Current Drive on NSTX J. Hosea, M. Bell, S. Bernabei, S. Kaye, B. LeBlanc, J. Menard, M. Ono C.K. Phillips, A. Rosenberg, J.R.

12/03/2013, Praga 1 Plasma MHD Activity Observations via Magnetics Diagnostics: Magnetic island Analysis Magnetic island Analysis Frederik Ostyn (UGent)

Review and Update of ITER ECE System M.E. Austin, U. Texas (DIII-D) R.F. Ellis, U. Maryland (DIII-D ) A.E. Hubbard, MIT (C Mod) P.E. Phillips, U. Texas.

Current Drive for FIRE AT-Mode T.K. Mau University of California, San Diego Workshop on Physics Issues for FIRE May 1-3, 2000 Princeton Plasma Physics.

Fyzika tokamaků1: Úvod, opakování1 Tokamak Physics Jan Mlynář 8. Heating and current drive Neutral beam heating and current drive,... to be continued.

RF simulation at ASIPP Bojiang DING Institute of Plasma Physics, Chinese Academy of Sciences Workshop on ITER Simulation, Beijing, May 15-19, 2006 ASIPP.

2 The Neutral Particle Analyzer (NPA) on NSTX Scans Horizontally Over a Wide Range of Tangency Angles Covers Thermal ( keV) and Energetic Ion.

D. A. Rasmussen, NCSX Research Forum 2006 Page 1 ECH and Fast Wave Electron Heating Systems for NCSX Tim Bigelow, Dave Rasmussen, Phil Ryan, Mike Cole.

HHFW and ECW/EBW Progress and Plans for Office of Science G. Taylor, PPPL For the NSTX Research Team NSTX 5 Year Plan Review for Conference.

Advances In High Harmonic Fast Wave Heating of NSTX H-mode Plasmas P. M. Ryan, J-W Ahn, G. Chen, D. L. Green, E. F. Jaeger, R. Maingi, J. B. Wilgen - Oak.

ASIPP Long pulse and high power LHCD plasmas on HT-7 Xu Qiang.

Investigation of fast ion mode spatial structure in NSTX N.A. Crocker, S. Kubota, W.A. Peebles (UCLA); E.D. Fredrickson, N.N. Gorelenkov, G.J. Kramer,

NSTX EXPERIMENTAL PROPOSAL - OP-XP-825 Title: HHFW Heating/CD phase scans in D L-mode plasmas P. Ryan, J. Hosea, R. Bell, L. Delgado-Aparicio, S. Kubota,

MAST V.Shevchenko et al, ISTW 2006, October 2006, Chengdu, China EBW Experiments on MAST V. Shevchenko 1, G. Cunningham 1, A. Gurchenko 2, E. Gusakov.

NSTX HIGH HARMONIC FAST WAVE CALCULATIONS

Rajesh Maingi Oak Ridge National Laboratory M. Bell b, T. Biewer b, C.S. Chang g, R. Maqueda c, R. Bell b, C. Bush a, D. Gates b, S. Kaye b, H. Kugel b,

HL-2A Heating & Current Driving by LHW and ECW study on HL-2A Bai Xingyu, HL-2A heating team.

Weixing Ding University of California, Los Angeles,USA collaborators: D.L. Brower, W. Bergerson, D. Craig, D. Demers, G.Fiksel, D.J. Den Hartog, J. Reusch,

Plan for Fast Wave, Electron Cyclotron and Electron Bernstein Wave Research NSTX-U Supported by Culham Sci Ctr York U Chubu U Fukui U Hiroshima U Hyogo.

1 EBW & HHFW Research - G. Taylor PAC-19 2/23/06 EBW & HHFW Research (Including EBW Collaborations with MAST & P EGASUS ) Gary Taylor presented on behalf.

Summary of RF-Related Presentations at the 2011 EPS Meeting G. Taylor NSTX Physics Meeting July 25, 2011 NSTX Supported by 1.

Dependence of Pedestal Structure on Ip and Bt A. Diallo, R. Maingi, S. Zweben, B.P. LeBlanc, B. Stratton, J. Menard, S. Gerhardt, J. Canick, A. McClean,

MHD Issues and Control in FIRE C. Kessel Princeton Plasma Physics Laboratory Workshop on Active Control of MHD Stability Austin, TX 11/3-5/2003.

Summary of RF Work To Date G. Taylor NSTX Monday Physics Meeting June 21, 2010 NSTX Supported by 1.

Advanced Tokamak Modeling for FIRE C. Kessel, PPPL NSO/PAC Meeting, University of Wisconsin, July 10-11, 2001.

Characterization of Fast Ion Power Absorption of HHFW in NSTX A. Rosenberg, J. Menard, J.R. Wilson, S. Medley, R. Dumont, B.P. LeBlanc, C.K. Phillips,

NSTX Team Meeting - Physics Analysis September 25, 2003 C.K. Phillips and S. Kaye.

Using microwaves to study fast ion driven modes in NSTX N.A. Crocker, S. Kubota, W.A. Peebles, G. Wang, T. Carter (UCLA); E.D. Fredrickson, B.P. LeBlanc,

Gary Taylor presented on behalf of the NSTX Research Team Non-Inductive Operation 5-Year Research Plan NSTX Program Advisory Committee Meeting (PAC-14)

47th Annual Meeting of the Division of Plasma Physics, October 24-28, 2005, Denver, Colorado ECE spectrum of HSX plasma at 0.5 T K.M.Likin, H.J.Lu, D.T.Anderson,

FY WEP TSG Goals & WEP-Relevant Diagnostic Upgrades NSTX Supported by WEP TSG Meeting September 14,

1PAC37, non-inductive ramp-up, Francesca Poli, Jan Francesca Poli, Gary Taylor for the Integrated Scenarios science group ECH/EBWH Research Plans.

1 NSTX EXPERIMENTAL PROPOSAL - OP-XP-712 Title: HHFW Power Balance Optimization at High B Field J. Hosea, R. Bell, S. Bernabei, L. Delgado-Aparicio, S.

Simulation of Non-Solenoidal Current Rampup in NSTX C. E. Kessel and NSTX Team Princeton Plasma Physics Laboratory APS-DPP Annual Meeting, Savannah, Georgia,

Scaling experiments of perturbative impurity transport in NSTX D. Stutman, M. Finkenthal Johns Hopkins University J. Menard, E. Synakowski, B. Leblanc,R.

1 Electron Bernstein Wave Physics on NSTX - Taylor Electron Bernstein Wave Physics on NSTX G. Taylor, J.B. Caughman, M.D. Carter, S. Diem, P.C. Efthimion,

NSTX Meeting name – abbreviated presentation title, abbreviated author name (??/??/20??) Goals of NSTX Advanced Scenario and Control TSG Study, implement,

Effect of Energetic-Ion/Bulk-Plasma- driven MHD Instabilities on Energetic Ion Loss in the Large Helical Device Kunihiro OGAWA, Mitsutaka ISOBE, Kazuo.

NSTX Electron Bernstein Wave Research - Taylor 1 of 8 Supported by Columbia U Comp-X General Atomics INEL Johns Hopkins U LANL LLNL Lodestar MIT Nova Photonics.

5.4 Stored Energy Crashes  Diamagnetic loop shows the plasma energy crashes at low plasma density  ECE signals are in phase with the energy crashes 

1 ASIPP Sawtooth Stabilization by Barely Trapped Energetic Electrons Produced by ECRH Zhou Deng, Wang Shaojie, Zhang Cheng Institute of Plasma Physics,

XP 514: Thermal Electron Bernstein Wave Conversion to O-Mode at GHz G. Taylor, P. Efthimion, J. Wilgen, J. Caughman Goals for this experiment: –Measure.

1 NSTX Electron Bernstein Wave Emission Measurements Gary Taylor NSTX Results Review September 20-21, 2004.

Presented by Gary Taylor In collaboration with Cynthia Phillips, Phil Ryan, Randy Wilson and The NSTX RF Research Team NSTX Wave-Particle Physics, Heating.

Nonlinear plasma-wave interactions in ion cyclotron range of frequency N Xiang, C. Y Gan, J. L. Chen, D. Zhou Institute of plasma phsycis, CAS, Hefei J.

Lower Hybrid Wave Coupling and Current Drive Experiments in HT-7 Tokamak Weici Shen Jiafang Shan Handong Xu Min Jiang HT-7 Team Institute of Plasma Physics,

= 2·10 18 m -3 T e (0) = 0.4 keV ECH and ECE on HSX Stellarator K.M.Likin, A.F.Almagri, D.T.Anderson, F.S.B.Anderson, C.Deng 1, C.W.Domier 2, R.W.Harvey.

Long Pulse High Performance Plasma Scenario Development for NSTX C. Kessel and S. Kaye - providing TRANSP runs of specific discharges S.

1 Program & Plans for EBW and HHFW Research - J. Hosea & G. Taylor - NSTX PAC-21 - January 17-19, 2007 Supported by Office of Science Culham Sci Ctr U.

The Role of VLF Transmitters in Limiting the Earthward Penetration of Ultra-Relativistic Electrons in the Radiation Belts J. C. Foster, D. N. Baker, P.J.

For the NSTX Five-Year Research Program 2009 – 2013 M.G. Bell Facility and Diagnostic Plans.

Managed by UT-Battelle for the Department of Energy The Use of a 28 GHz Gyrotron for EBW Startup Experiments on MAST John Caughman,Tim Bigelow, Steffi.

JongGab Jo, H. Y. Lee, Y. H. An, K. J. Chung and Y. S. Hwang*

ECE Diagnostic on the HSX Stellarator

11th IAEA Technical Meeting on H-mode Physics and Transport Barriers" , September, 2007 Tsukuba International Congress Center "EPOCHAL Tsukuba",

A.D. Turnbull, R. Buttery, M. Choi, L.L Lao, S. Smith, H. St John

First Experiments Testing the Working Hypothesis in HSX:

Presentation transcript:

1 Electron Bernstein Wave Research and Plans Gary Taylor Presentation to the 16th NSTX Program Advisory Committee September 9, 2004

2 ~ 100 kA of off-axis CD needed to sustain  ~ 40% in NSTX Cannot use ECCD in NSTX since  pe /  ce ~ 3-10 Modeling indicates that EBWCD can provide needed current EBWCD may also assist startup and stabilize NTM's 4 MW, 28 GHz EBWCD system is being planned for NSTX EBWs Can Generate Critical Off-Axis Current Drive in NSTX at High  NSTX,  = 40% 0 01 r/a Charles Kessel (PPPL) Tokamak Simulation Code J // (A/Wb)

3 EBW Launcher Design Guided by Modeling EBW Coupling, Ray Tracing and Emission Measurements EBW coupling at 14 GHz has been modeled with OPTIPOL/GLOSI [Mark Carter, ORNL] Coupling at 28 GHz being modeled with OPTIPOL/AORSA1D [Mark Carter & Fred Jaeger, ORNL] EBW emission measurements on NSTX and other machines can test EBW coupling predictions:  EBW emission also studied as a possible T e (R,t) diagnostic

4 Modeling Predicts Efficient EBW Coupling with Oblique, Circularly Polarized, “O-Mode” Launch "X-mode" EBW coupling requires steep density gradient at EBW conversion layer:  need L n ~ 2-3 mm for ~100% EBW conversion on NSTX  need limiter to maintain steep L n  very sensitive to L n fluctuations Oblique "O-mode" EBW conversion efficiency less sensitive to fluctuations in L n at EBW mode conversion layer Theory predicts launch with near-circular polarization provides ~100% EBW conversion efficiency

5 New Obliquely Viewing Antenna Installed on NSTX Measures “O-Mode” EBW Emission Two 8-18 GHz radiometers simultaneously measure orthogonal polarizations with quad-ridged antenna:  compare emission results to OPTIPOL/GLOSI coupling predictions Focusing lens optimized for GHz EBW emission Antenna views along 35 degree B field pitch, suitable for NSTX plasmas with I p ~ 1 MA at B t (0) ~ 4.0 kG Adjustable Limiters

6 Ray Tracing Calculations Show 16.5 GHz EBW Emission is Generated Locally at r/a = 0.4 CompX EBW Emission Frequency = 16.5 GHz B t (0) = 4 kG GENRAY t = 325 ms Shot OPTIPOL/GLOSI L n = 1 cm, f = 14 GHz Poloidal Angle (deg.) Toroidal Angle (deg.) > 90% EBW Coupling 10% B Approx. Antenna Acceptance Angle GENRAY ray tracing uses EFIT equilibrium and T e (R) & n e (R) from Thomson scattering Antenna acceptance angle much larger than predicted 90% EBW conversion region

7 EBW Emission Analysis Indicates Near-Circular Polarization & EBW T rad /T e ~ 70%; Consistent with Theory Freq. = 16.5 GHz Emission fluctuations due to fluctuation in L n at EBW conversion layer Fluctuations should be smaller at 28 GHz:  smaller antenna acceptance angle  smaller L n fluctuation

8 Obliquely Viewing GHz EBW Radiometer to Measure 28 GHz EBW Mode Conversion on NSTX Next Year Larger vacuum window & higher frequency should allow much better collimation:  current GHz antenna has ± 12 degree acceptance angle, GHz antenna should achieve less than ± 5 degrees Detailed 28 GHz coupling study using OPTIPOL/AORSA1D and realistic EBW launcher model planned for FY05:  compare to 28 GHz emission measurements ~ 1 MW, 60 GHz and ~ 100 kW, 28 GHz EBW experiments on MAST will also test oblique “O-mode” conversion theory

9 GENRAY/CQL3D [Bob Harvey, CompX] NSTX B t = 3.75 kG  = 42% 28 GHz Modeling Predicts 28 GHz EBW Drives Efficient Off-Axis Current at  ~ 40% via Ohkawa CD Mechanism Current Density (A/cm 2 ) r/a G. Taylor et al, Physics of Plasmas (October 2004)

10 Normalized Ohkawa EBWCD Efficiency (  ec ) Increases with r/a on Low Field Side of Axis  ec = 3.27 x I p (A) x R(m) x n e (10 19 m -3 ) T e (keV) x P(W) [C.C. Petty, AIP Proc. 595, 275 (2001)] R CompX GENRAY/CQL3D Frequency = 15 GHz Power = 1 MW Initial estimates suggest interaction with bootstrap current may modify EBWCD efficiency by ~10% Will extend EBWCD modeling to include bootstrap current, trapped particle pinch and electron transport

11 1 MW “Proof-of-Principle” EBW System Tests Viability of Heating & Current Drive in NSTX ~ 750 kW EBW power delivered to plasma:  allowing for transmission loss and EBW conversion  drive kA Final 4 MW system will add three more gyrotrons, transmission lines & launchers  provides 3 MW of EBW power in the plasma & generates > 100 kA

12 Summary We are looking at 28 GHz EBWCD for NSTX Initial emission results at GHz via EBW conversion to “O-mode” look promising & consistent with theory We will measure 28 GHz EBW emission via “O-mode” conversion next year Modeling EBW coupling is now being extended to 28 GHz EBWCD modeling results show efficient Ohkawa off-axis CD & predict ~ 3 MW of EBW power will drive > 100 kA