logging in or signing up Talk EX8 6 Altoro Download Post to : URL : Related Presentations : Share Add to Flag Embed Email Send to Blogs and Networks Add to Channel Uploaded from authorPOINTLite Insert YouTube videos in PowerPont slides with aS Desktop Copy embed code: (To copy code, click on the text box) Embed: URL: Thumbnail: WordPress Embed Customize Embed The presentation is successfully added In Your Favorites. Views: 21 Category: Travel/ Places.. License: All Rights Reserved Like it (0) Dislike it (0) Added: March 12, 2008 This Presentation is Public Favorites: 0 Presentation Description No description available. Comments Posting comment... Premium member Presentation Transcript Slide1: Confinement and Local Transport in the National Spherical Torus Experiment (NSTX) Stanley M. Kaye1, M.G. Bell1, R.E. Bell1, C. W. Domier2, W. Horton3, J. Kim3, B.P. LeBlanc1, F. Levinton4,N.C. Luhmann2, R. Maingi5, E. Mazzucato1, J.E. Menard1, D.R. Mikkelsen1, H. Park1, G. Rewoldt1, S.A. Sabbagh6, D. Smith1, D. Stutman7, K. Tritz7, W. Wang1, H. Yuh4 21st IAEA/Fusion 2006 Meeting Oct 16 – 21, 2006 Chengdu, China 1 PPPL, Princeton University, Princeton, NJ, USA 08543 2 University of California, Davis, CA, USA 95616 3 IFS, University of Texas, Austin, TX, USA 78712 4 Nova Photonics Inc., Princeton, NJ, USA, 08540 5 ORNL, Oak Ridge, TN, USA 37831 6 Dept. of Applied Physics, Columbia University, NYC, NY, USA 10027 7 The Johns Hopkins University, Baltimore MD 21218 Culham Sci Ctr U St. Andrews York U Chubu U Fukui U Hiroshima U Hyogo U Kyoto U Kyushu U Kyushu Tokai U NIFS Niigata U U Tokyo JAERI Hebrew U Ioffe Inst RRC Kurchatov Inst TRINITI KBSI KAIST ENEA, Frascati CEA, Cadarache IPP, Jülich IPP, Garching ASCR, Czech Rep U Quebec College W&M Colorado Sch Mines Columbia U Comp-X General Atomics INEL Johns Hopkins U LANL LLNL Lodestar MIT Nova Photonics New York U Old Dominion U ORNL PPPL PSI Princeton U SNL Think Tank, Inc. UC Davis UC Irvine UCLA UCSD U Colorado U Maryland U Rochester U Washington U WisconsinNSTX Addresses Transport & Turbulence Issues Critical to Both Basic Toroidal Confinement and Future Devices: NSTX Addresses Transport & Turbulence Issues Critical to Both Basic Toroidal Confinement and Future Devices NSTX offers a novel view into plasma T&T properties NSTX operates in a unique part of dimensionless parameter space: R/a, bT, (r*, n*) Dominant electron heating with NBI: relevant to a-heating in ITER Major Radius R0 0.85 m Aspect Ratio A 1.3 Elongation k 2.8 Triangularity d 0.8 Plasma Current Ip 1.5 MA Toroidal Field BT 0.55 T Pulse Length 1.5 s NB Heating (100 keV) 7 MW bT,tot up to 40% Excellent laboratory in which to study electron transport: electron transport anomalous, ions close to neoclassical Large range of bT spanning e-s to e-m turbulence regimes Strong rotational shear that can influence transport Localized electron-scale turbulence measurable (re ~ 0.1 mm)This Presentation Will Focus on Confinement & Transport Trends in NSTX and Their Underlying Processes: This Presentation Will Focus on Confinement & Transport Trends in NSTX and Their Underlying Processes Major accomplishments Key confinement and transport dependences established (BT, Ip, b, n*, q(r),…) High priority ITPA tasks have been addressed Dimensionless parameter scans in bT, ne* Established more accurate e (=a/R) scaling with NSTX (& MAST) data included in the ITPA database t98y2~Ip0.93 BT0.15 ne0.41 P-0.69 R1.97 e0.58… tnew~Ip0.73 BT0.36 ne0.39 P-0.62 R2.14 e1.03 (Kaye et al., PPCF 48 [2006] A429) Localized turbulence characteristics being assessed across wide range of k (upper ITG/TEM to ETG) Theory/simulations have indicated ETG modes could be important in controlling electron transport Dimensionless Parameter Scans Have Addressed High-Priority ITPA Issues: Dimensionless Parameter Scans Have Addressed High-Priority ITPA Issues b-scan at fixed q, BT - b-dependence important to ITER advanced scenarios (Bt98y2~b-0.9) - Factor of 2-2.5 variation in bT - Degradation of tE with b weak on NSTX 20% variation in re, ne* ne*-scan at fixed q - Factor of >3 variation in ne* - Strong increase of confinement with decreasing collisionality k=2.1 d=0.6Dedicated H-mode Confinement Scaling Experiments Have Isolated the BT and Ip Dependences: Dedicated H-mode Confinement Scaling Experiments Have Isolated the BT and Ip Dependences Scans carried out at constant density, injected power (4 MW) 0.50 s 0.50 sDedicated H-mode Confinement Scaling Experiments Have Revealed Some Surprises: Dedicated H-mode Confinement Scaling Experiments Have Revealed Some Surprises Strong dependence of tE on BT tE,98y,2 ~ BT0.15 H98y,2 ~ 0.9 → 1.1 → 1.4 4 MW tE,98y,2 ~ Ip0.93 H98y,2 ~ 1.4 → 1.3 → 1.1 Weaker dependence on Ip tE~Ip1.3-1.5 at fixed q tE,98y,2~Ip1.1 at fixed q NSTX tE exhibits strong scaling at fixed q 4 MWSlide7: Variation of Electron Transport Primarily Responsible for BT Scaling Broadening of Te & reduction in ce outside r/a=0.5 with increasing BT Ions near neoclassical NeoclassicalSlide8: Theory/Gyrokinetic Calculations Suggest ETG May Play an Important Role in Determining Electron Transport at Low BT Non-linear simulations indicate formation of radial streamers (up to 200re): FLR-modified fluid code [Horton et al., PoP 2005] Good agreement between experimental and theoretical saturated transport level at 0.35 T Experimental ce profile consistent with that predicted by e-m ETG theory [Horton et al., NF 2004] at 0.35 T Not at higher BT Kim, IFS ETG linearly unstable only at lowest BT - 0.35 T: R/LTe 20% above critical gradient - 0.45, 0.55 T: R/LTe 20-30% below critical gradient 0.35 T GS2Slide9: Ion Transport Primarily Governs Ip Scaling - Ions Near Neoclassical Level - ci,GTC-NEO (r/a=0.5-0.8) GTC-Neo neoclassical: includes finite banana width effects (non-local)Slide10: Turbulence Measurements + Gyrokinetic Calculations Have Helped Identify Possible Sources of Transport Ion transport during H-phase is neoclassical Electron transport reduced, but remains anomalous Ion and electron transport change going from L- to H-modes - Localized measurement (axis to edge) - Excellent radial resolution (6 cm)Slide11: Theory/Gyrokinetic Calculations Indicate Both ITG/TEM and ETG are Possible Candidates for Electron Transport GS2 calculations indicate lower linear growth rates at all wavenumbers during H- than during L-phase: ETG unstable Experimental ce profile consistent with that predicted by e-s ETG theory (Horton et al, Phys. Plasmas [2004]) Non-linear GTC results indicate ITG modes stable during H-phase; ci ~ neoclassicalNSTX Plays a Key Role in Multi-Scale Transport & Turbulence Research: NSTX Plays a Key Role in Multi-Scale Transport & Turbulence Research Confinement and transport trends found to differ from those at higher R/a Strong BT, weaker Ip scaling Electron transport variation primarily responsible for BT scaling Ions near neoclassical; primarily responsible for Ip scaling Understand the source of the difference in confinement trends at different R/a (low vs high-k turbulence dominant at different R/a, BT?) Data provided to ITPA H-mode database for R/a and bT scalings No degradation of BtE with bTBackup Vugraphs: Backup Vugraphs Slide14: New Diagnostic Capabilities Have Facilitated Progress in Understanding Transport Processes 12 channel MSE [NOVA Photonics] LRDFIT Reconstruction Rmag 51-point CHERS 20-point MPTS Tangential microwave scattering measures localized electron-scale turbulence kr=2 (upper ITG/TEM) to ~24 (ETG) cm-1 re ~0.01 cm Dr ~ 6 cm Dk ~ 1 cm-1 Can vary location of scattering volume (near Rmag to near edge) Important for equilibrium and microinstability calculationsNew Diagnostic Capabilities Have Facilitated Progress in Understanding Transport Processes: New Diagnostic Capabilities Have Facilitated Progress in Understanding Transport Processes Tangential micorwave scattering measures localized electron-scale turbulence 12 channel MSE [NOVA Photonics] Important for equilibrium and microinstability calculations kr=2 (upper ITG/TEM) to ~24 (ETG) cm-1 re ~0.01 cm Dr ~ 6 cm Dk ~ 1 cm-1 Can vary location of scattering volume (near Rmag to near edge) Dimensionless Variable Scans Have Addressed High Priority ITPA Physics Issues (e, b - scaling): Dimensionless Variable Scans Have Addressed High Priority ITPA Physics Issues (e, b - scaling) b-scan at fixed re, ne* - b-dependence important to ITER advanced scenarios (Bt98y2~b-0.9) - Degradation of tE with b weak on NSTX NSTX data used in conjunction with ITPA data to establish e (=a/R) scaling with more confidence ITER98PB(y,2) scaling does not represent low R/a data well t98y2~Ip0.93BT0.15ne0.41P-0.69R1.97e0.58… tnew~Ip0.73BT0.36ne0.39P-0.62R2.14e1.03 (Kaye et al., PPCF 48 [2006] A429) 2-2.5 variation in bT 20% variation in re, ne* Slide17: Stronger Reversed Magnetic Shear Is Associated with Reduced Transport Weak vs Reverse-Shear L-mode Global non-linear GTC and GYRO simulations show that a pure ITG mode is unstable without ExB flow shear included TEM & ETG calculations underwaySlide18: Pellet Perturbations Are Being Used to Probe Relation of Critical Gradient Physics to q-Profile H-mode with monotonic q-profile exhibits stiff profile behavior → Te close to marginal stability Reversed magnetic shear L-mode responds to pellet perturbation over several ms Soft X-ray array diagnoses fast DTe R/LTe t=297→301 ms R/LTe t=440→444 ms Stutman, JHU You do not have the permission to view this presentation. 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Talk EX8 6 Altoro Download Post to : URL : Related Presentations : Share Add to Flag Embed Email Send to Blogs and Networks Add to Channel Uploaded from authorPOINTLite Insert YouTube videos in PowerPont slides with aS Desktop Copy embed code: (To copy code, click on the text box) Embed: URL: Thumbnail: WordPress Embed Customize Embed The presentation is successfully added In Your Favorites. Views: 21 Category: Travel/ Places.. License: All Rights Reserved Like it (0) Dislike it (0) Added: March 12, 2008 This Presentation is Public Favorites: 0 Presentation Description No description available. Comments Posting comment... Premium member Presentation Transcript Slide1: Confinement and Local Transport in the National Spherical Torus Experiment (NSTX) Stanley M. Kaye1, M.G. Bell1, R.E. Bell1, C. W. Domier2, W. Horton3, J. Kim3, B.P. LeBlanc1, F. Levinton4,N.C. Luhmann2, R. Maingi5, E. Mazzucato1, J.E. Menard1, D.R. Mikkelsen1, H. Park1, G. Rewoldt1, S.A. Sabbagh6, D. Smith1, D. Stutman7, K. Tritz7, W. Wang1, H. Yuh4 21st IAEA/Fusion 2006 Meeting Oct 16 – 21, 2006 Chengdu, China 1 PPPL, Princeton University, Princeton, NJ, USA 08543 2 University of California, Davis, CA, USA 95616 3 IFS, University of Texas, Austin, TX, USA 78712 4 Nova Photonics Inc., Princeton, NJ, USA, 08540 5 ORNL, Oak Ridge, TN, USA 37831 6 Dept. of Applied Physics, Columbia University, NYC, NY, USA 10027 7 The Johns Hopkins University, Baltimore MD 21218 Culham Sci Ctr U St. Andrews York U Chubu U Fukui U Hiroshima U Hyogo U Kyoto U Kyushu U Kyushu Tokai U NIFS Niigata U U Tokyo JAERI Hebrew U Ioffe Inst RRC Kurchatov Inst TRINITI KBSI KAIST ENEA, Frascati CEA, Cadarache IPP, Jülich IPP, Garching ASCR, Czech Rep U Quebec College W&M Colorado Sch Mines Columbia U Comp-X General Atomics INEL Johns Hopkins U LANL LLNL Lodestar MIT Nova Photonics New York U Old Dominion U ORNL PPPL PSI Princeton U SNL Think Tank, Inc. UC Davis UC Irvine UCLA UCSD U Colorado U Maryland U Rochester U Washington U WisconsinNSTX Addresses Transport & Turbulence Issues Critical to Both Basic Toroidal Confinement and Future Devices: NSTX Addresses Transport & Turbulence Issues Critical to Both Basic Toroidal Confinement and Future Devices NSTX offers a novel view into plasma T&T properties NSTX operates in a unique part of dimensionless parameter space: R/a, bT, (r*, n*) Dominant electron heating with NBI: relevant to a-heating in ITER Major Radius R0 0.85 m Aspect Ratio A 1.3 Elongation k 2.8 Triangularity d 0.8 Plasma Current Ip 1.5 MA Toroidal Field BT 0.55 T Pulse Length 1.5 s NB Heating (100 keV) 7 MW bT,tot up to 40% Excellent laboratory in which to study electron transport: electron transport anomalous, ions close to neoclassical Large range of bT spanning e-s to e-m turbulence regimes Strong rotational shear that can influence transport Localized electron-scale turbulence measurable (re ~ 0.1 mm)This Presentation Will Focus on Confinement & Transport Trends in NSTX and Their Underlying Processes: This Presentation Will Focus on Confinement & Transport Trends in NSTX and Their Underlying Processes Major accomplishments Key confinement and transport dependences established (BT, Ip, b, n*, q(r),…) High priority ITPA tasks have been addressed Dimensionless parameter scans in bT, ne* Established more accurate e (=a/R) scaling with NSTX (& MAST) data included in the ITPA database t98y2~Ip0.93 BT0.15 ne0.41 P-0.69 R1.97 e0.58… tnew~Ip0.73 BT0.36 ne0.39 P-0.62 R2.14 e1.03 (Kaye et al., PPCF 48 [2006] A429) Localized turbulence characteristics being assessed across wide range of k (upper ITG/TEM to ETG) Theory/simulations have indicated ETG modes could be important in controlling electron transport Dimensionless Parameter Scans Have Addressed High-Priority ITPA Issues: Dimensionless Parameter Scans Have Addressed High-Priority ITPA Issues b-scan at fixed q, BT - b-dependence important to ITER advanced scenarios (Bt98y2~b-0.9) - Factor of 2-2.5 variation in bT - Degradation of tE with b weak on NSTX 20% variation in re, ne* ne*-scan at fixed q - Factor of >3 variation in ne* - Strong increase of confinement with decreasing collisionality k=2.1 d=0.6Dedicated H-mode Confinement Scaling Experiments Have Isolated the BT and Ip Dependences: Dedicated H-mode Confinement Scaling Experiments Have Isolated the BT and Ip Dependences Scans carried out at constant density, injected power (4 MW) 0.50 s 0.50 sDedicated H-mode Confinement Scaling Experiments Have Revealed Some Surprises: Dedicated H-mode Confinement Scaling Experiments Have Revealed Some Surprises Strong dependence of tE on BT tE,98y,2 ~ BT0.15 H98y,2 ~ 0.9 → 1.1 → 1.4 4 MW tE,98y,2 ~ Ip0.93 H98y,2 ~ 1.4 → 1.3 → 1.1 Weaker dependence on Ip tE~Ip1.3-1.5 at fixed q tE,98y,2~Ip1.1 at fixed q NSTX tE exhibits strong scaling at fixed q 4 MWSlide7: Variation of Electron Transport Primarily Responsible for BT Scaling Broadening of Te & reduction in ce outside r/a=0.5 with increasing BT Ions near neoclassical NeoclassicalSlide8: Theory/Gyrokinetic Calculations Suggest ETG May Play an Important Role in Determining Electron Transport at Low BT Non-linear simulations indicate formation of radial streamers (up to 200re): FLR-modified fluid code [Horton et al., PoP 2005] Good agreement between experimental and theoretical saturated transport level at 0.35 T Experimental ce profile consistent with that predicted by e-m ETG theory [Horton et al., NF 2004] at 0.35 T Not at higher BT Kim, IFS ETG linearly unstable only at lowest BT - 0.35 T: R/LTe 20% above critical gradient - 0.45, 0.55 T: R/LTe 20-30% below critical gradient 0.35 T GS2Slide9: Ion Transport Primarily Governs Ip Scaling - Ions Near Neoclassical Level - ci,GTC-NEO (r/a=0.5-0.8) GTC-Neo neoclassical: includes finite banana width effects (non-local)Slide10: Turbulence Measurements + Gyrokinetic Calculations Have Helped Identify Possible Sources of Transport Ion transport during H-phase is neoclassical Electron transport reduced, but remains anomalous Ion and electron transport change going from L- to H-modes - Localized measurement (axis to edge) - Excellent radial resolution (6 cm)Slide11: Theory/Gyrokinetic Calculations Indicate Both ITG/TEM and ETG are Possible Candidates for Electron Transport GS2 calculations indicate lower linear growth rates at all wavenumbers during H- than during L-phase: ETG unstable Experimental ce profile consistent with that predicted by e-s ETG theory (Horton et al, Phys. Plasmas [2004]) Non-linear GTC results indicate ITG modes stable during H-phase; ci ~ neoclassicalNSTX Plays a Key Role in Multi-Scale Transport & Turbulence Research: NSTX Plays a Key Role in Multi-Scale Transport & Turbulence Research Confinement and transport trends found to differ from those at higher R/a Strong BT, weaker Ip scaling Electron transport variation primarily responsible for BT scaling Ions near neoclassical; primarily responsible for Ip scaling Understand the source of the difference in confinement trends at different R/a (low vs high-k turbulence dominant at different R/a, BT?) Data provided to ITPA H-mode database for R/a and bT scalings No degradation of BtE with bTBackup Vugraphs: Backup Vugraphs Slide14: New Diagnostic Capabilities Have Facilitated Progress in Understanding Transport Processes 12 channel MSE [NOVA Photonics] LRDFIT Reconstruction Rmag 51-point CHERS 20-point MPTS Tangential microwave scattering measures localized electron-scale turbulence kr=2 (upper ITG/TEM) to ~24 (ETG) cm-1 re ~0.01 cm Dr ~ 6 cm Dk ~ 1 cm-1 Can vary location of scattering volume (near Rmag to near edge) Important for equilibrium and microinstability calculationsNew Diagnostic Capabilities Have Facilitated Progress in Understanding Transport Processes: New Diagnostic Capabilities Have Facilitated Progress in Understanding Transport Processes Tangential micorwave scattering measures localized electron-scale turbulence 12 channel MSE [NOVA Photonics] Important for equilibrium and microinstability calculations kr=2 (upper ITG/TEM) to ~24 (ETG) cm-1 re ~0.01 cm Dr ~ 6 cm Dk ~ 1 cm-1 Can vary location of scattering volume (near Rmag to near edge) Dimensionless Variable Scans Have Addressed High Priority ITPA Physics Issues (e, b - scaling): Dimensionless Variable Scans Have Addressed High Priority ITPA Physics Issues (e, b - scaling) b-scan at fixed re, ne* - b-dependence important to ITER advanced scenarios (Bt98y2~b-0.9) - Degradation of tE with b weak on NSTX NSTX data used in conjunction with ITPA data to establish e (=a/R) scaling with more confidence ITER98PB(y,2) scaling does not represent low R/a data well t98y2~Ip0.93BT0.15ne0.41P-0.69R1.97e0.58… tnew~Ip0.73BT0.36ne0.39P-0.62R2.14e1.03 (Kaye et al., PPCF 48 [2006] A429) 2-2.5 variation in bT 20% variation in re, ne* Slide17: Stronger Reversed Magnetic Shear Is Associated with Reduced Transport Weak vs Reverse-Shear L-mode Global non-linear GTC and GYRO simulations show that a pure ITG mode is unstable without ExB flow shear included TEM & ETG calculations underwaySlide18: Pellet Perturbations Are Being Used to Probe Relation of Critical Gradient Physics to q-Profile H-mode with monotonic q-profile exhibits stiff profile behavior → Te close to marginal stability Reversed magnetic shear L-mode responds to pellet perturbation over several ms Soft X-ray array diagnoses fast DTe R/LTe t=297→301 ms R/LTe t=440→444 ms Stutman, JHU