Progress in Development of Time-of-Flight Refractometer for ITER

1. ITPA-10 Progress in Development of Time-of-Flight Refractometer for ITER Alexei Petrov, Vladimir Petrov, MassimoDe Benedetti, Onofrio Tudisco (FTU) SRC RF TRINITI, Troitsk Moscow region, RussiaE-mail: vpetrov@triniti.ru 2006

2. OUTLINE SPECIFIC FEATURES PROBLEMS, TASKS PROGRESS RECENT EXPERIMENTS, STATUS CONCLUSION, PLANS, TASKS

3. SPECIFIC FEATURES A robust measurement of line integrated electron density (without fringe jumps) needed for many application, in particular for real time control. Measure time delay • Unambiguous line int. density for feedback control • Microwave pulse - just above Xl cutoff freq. from LFS: single or double pass • ITER– using transparency window on X-mode in low frequency band (60 – 100 GHz): to avoid “first mirror” problem • Less sensitive to the reflection surface quality

4. PROBLEMS, TASKS -1 • SNR – long distances, long waveguides, accuracy of measurements ~ • Refraction – attenuation, change of wave trajectory- need ray-tracing/(Full wave-analysis) to take into account • Additionally, for high Te (45keV) regimes: absorption, relativistic effects). Transparency window – 60-80-100 GHz - ? • Choose of probing geometry: double- or single pass • Multi-freq. probing to avoid profile dependence • Experiments on tokamaks • Integration with ITER-chamber, LFS-X reflectometer (76-220 GHz; F.02 system, Eq#11)

5. PROBLEMS, TASKS - 2 SNR – accuracy of measurements: • Optimization of probe geometry, optimization of antenna-waveguide system, use scheme with low-noise microwave amplifier, measure time delay by phase measurements • Probe geometry: • 1. Double-pass (DB). • Pro - use only LFS antennas. • Contra –absorption higher. Influence of refraction larger? • 2. Single pass (SP), using HFS antenna and LFS antenna. • Pro – absorption less. • Contra – complicate HFS antenna system. Compare two systems: k = P1/P2 ~ A1·L22/A2·L12, A1~ 9*9 cm2, A2~9*1 cm2;L1~2·(2a+l), L2~(2a+l). k~10 dB (DB - better), w/o absorption and refraction

6. PROBLEMS, TASKS - 3 - 50dB (single pass) - 10dB - 0.4dB G. Vayakis, J. Sánchez, ITPA-6 Absorption, choice frequencies Reference Te profiles Integrated absorption for equatorial trajectories at different frequencies (60-100 GHz) and Te values (25-45 keV), ne(0) = 1.03·1020 m-3 ~4.7 dB Total single pass transmission: At least 3 freq. in a range 60-78? GHz to secure immunity to density profile, 95-96 GHz – up to 25 keV

7. PROGRESS - 1 SNR • 1. Development of the prototype of a receiver for a refractometer with a pulse microwave amplifier (PMA) based on a IMPATT-diode (SNR): • Frequency 60.0±0.5 GHz • Gain >20 dB • Noise <5 dB • Net effect – 15 dB • 2. Improved prototype of a time delay measurements unit with a fast peak detector (PD) - enhanced accuracy of time delay measurements (for low SNR), net effect - 2-3 times better accuracy • 3. Method of a double-frequency differential refractometry (DFR) for time delay measurements is offered and tested in T-11M (higher SNR, sensitivity) [1,2] (CW, net effect +10 dB and more) • Measurements of phase shift between 2 waves with close frequencies (fringe jump-free) :12,Df12 < 2p [1]. V. Petrov et al.Plasma Physics Reports, 2006, Vol. 32, No. 4, p. 317. [2]. V. Petrov et al.Instr. and Exper. Techn., 2006, Vol. 49, No. 2, p. 238.

8. T-11M FTU ITER BT [T] 1.2 5.0– 8.0 5.3 R [м] 0.70 0.935 6.2 a [м] 0.2 0.305 2.0 R/a 3.5 3.07 3.1 Ne [м-3] 0.5*1020 >1*1020 RECENT EXPERIMENTS - 1 • Experiments in tokamaks – T-11M, FTU Tokamak Parameter • Testing 60 GHz prototype of refractometer (X-mode) in ITER-like conditions on the FTU tokamak (Frascati, Italy) >1*1020 0.5 10-12 15 Te [keV]

9. RECENT EXPERIMENTS - 2 • Experiments in tokamaks – FTU Transparence window on FTU: Df =50-120 GHz N0 Df flc B0 Df flc fuc N= N0(1-r2)a B0 > 3.5 T needed The behavior of cut-off and ECE frequencies on FTU for typical plasma parameters

10. RECENT EXPERIMENTS - 3 • Experiments in tokamaks – T-11M, FTU • MO – microwave oscillator, I-isolator, DC-directional coupler, PCS- pulse current source, A1, A2 – amplifiers, D1, D2 – detectors, PD – adaptive threshold pulse discriminator, TVC – time-to-voltage converter P ~ 200 mW, tpulse = 5 ns, tfr< 2 ns, f (PRR) ~ 500 kHz

11. RECENT EXPERIMENTS - 4 • Experiments in tokamaks – FTU, geometry and picture Signal detector with pulse amplifier CO2/CO interferometer Refractometer Electronic unit for signal handling (PD) Pulse microwave oscillator Antenna system of ECE and reflectometer for the firstexperiments in FTU, antennae directed along minor radius – refraction minimal

12. Ip = 500 kA Bt = 6 T <N> = 0.8 RECENT EXPERIMENTS - 5 • FTU experiments Time delays ~1.5 ns Now accuracy ~10 ps (~1 ms time resolution) Sensitivity of density measurements ~ 1.5 ns/1020 m-3. Lower density limit: 0.7% of max density. N= (N(0)-N(a))·(1-r2)a+N(a) J= J0(1-r2)g g= q(a)-1 Time delay, ns The behavior of the calculated time delays for X-mode versus density for typical plasma parameters

13. RECENT EXPERIMENTS - 6 FTU experiments ADC, code 0.8 ns 0.8 0.4 Time, ms Time, s Raw data of TFR: Time delay (code ADC) versus shot time for the typical shot # 27992 (Bt = 6 T, Ip = 500 kA, Ohmic heating Mean density, 1020 m-3: Refractometer (blue) and Interferometer(red) for the shot #27982

14. Cut-off at the density 1-1.1•1020 m-3; Adequate density measurements up to cut-off RECENT EXPERIMENTS - 7 FTU - Reflectometry regime Mean density 1020 m-3 Td, ns 1 1 -3 Time, s Time, s Mean density: Refractometer (blue line) and Interferometer (red) for the shot #27983

15. Blue – refractometer Red –IR-interferometer (22.5 cm) RECENT EXPERIMENTS - 8 Mean density, a.u. Time, ms

16. STATUS -1 Eq#11 Integration in ITER: • TFR probing geometry is part of HFS/LFS antennae-wave guide system (A. Malaquias)

17. STATUS - 2 C.I.Walker, et.al, ITPA-6 Eq#11

18. CONCLUSION, PLANS, TASKS -1 1. Development of the prototype of a receiver with a pulse microwave amplifier (PMA) based on a IMPATT-diode (SNR): + 15 dB. 2. Improved prototype of a time delay measurements unit with a fast peak detector (PD) - enhanced accuracy of time delay measurements (for low SNR), net effect - 2-3 times better accuracy 3. Method of a double-frequency differential refractometry (DFR) for time delay measurements is offered and tested in T-11M. +10 dB and more. 4. Testing of TFR in ITER-like configuration (X-mode, double-pass horizontal probing, the same frequency) has been performed successfully in FTU. The first measurements of plasma density with TFR on X-mode have been performed, up to the cut-off density, influence of refraction is low for reflectometry type antenna system (looking along density gradient). Good signal-to-noise ratio is obtained with time resolution of ~50 ms

19. CONCLUSION, PLANS, TASKS - 2 Density measured by TFR corresponds to the one measured by interferometer (along vertical chord) within 10%. Double-pass scheme of TFR is preferential. Plans: to proceed testing of TFR in different regimes of FTU (ITER-relevant regimes), to develop algorithms of data elaboration (refraction, relativistic effects), hardware modernization (ADC, signal handling electronic); test measurements in JET (D-shape large plasma); testing in T-11M of prototypes of TFR; development of multifrequency prototype; Tasks. Integration in ITER. Study influence of refraction – experimentally and numerically.