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High rate studies of TRD at GSI (update)

D. Gonzalez-Diaz, GSI 27-02-2008. High rate studies of TRD at GSI (update). Experimental setup. Fit to exponential curves and determination of the glow discharge voltage. glow discharge. Slopes of the gain curve. The onset of the glow discharge. chamber unstable (not understood yet).

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High rate studies of TRD at GSI (update)

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  1. D. Gonzalez-Diaz, GSI 27-02-2008 High rate studies of TRD at GSI (update)

  2. Experimental setup

  3. Fit to exponential curves and determination of the glow discharge voltage. glow discharge

  4. Slopes of the gain curve

  5. The onset of the glow discharge

  6. chamber unstable (not understood yet) maximum gain depends on the fraction of quencher maximum gain roughly constant The onset of the glow discharge

  7. Global fit to the Mathieson formula • Chamber parameters: s=4 mm, h=3 mm. • Fit parameters: μnoble and μCO2 combined by assuming the Blanc's additive law (with f being the fraction of noble gas):

  8. A. Kalweit Xenon

  9. G.Hamar Argon

  10. Neon

  11. Rate capability. After obtaining the parameters of the fit (2x3 mobilities), the rate capability r at arbitrary gain drop F can be re-obtained as:

  12. Rate capability. A handy representation. ΔE = 6.7 keV~2 ΔEmips systematic error CBM goal

  13. Beam size dependence Therefore: the rate capability is overestimated by the same factor (an independent measurement with de-focused beam points also to a factor around 0.6). Preliminary A. Kalweit 0 2 4 8 10 6 r [mm]

  14. very conservatively one can assign a systematic uncertainty of up to a factor 2x2 [maximum] in the rate capability (more systematic measurements are on the way!)

  15. Some scalings

  16. Gap h (~1/h2)

  17. Wire pitch s (~1/s)

  18. Gain drop F (~F)

  19. Gain Mo (~Mo)

  20. Conclusions. • Existing data (from different measurements conducted at GSI) on gain and rate capability was compiled and re-analized by using a common framework. A rate capability of 100x2 Hz/cm2 for mips at Mo=104 and F=5% drop was demonstrated on 3 mm gap chambers with 4 mm pitch. • The uncertainty coming from the finite beam size and partially inconsistent sets of data is conservatively below a factor 4. • The rate capability improves linearly with MoF. Therefore, operation of this geometry at gains below 104 provides a safe margin regarding the rate capability required by CBM (100 Hz/cm2), a wide dynamic range for primary ionizations (glow discharge at Mo~2 105 for Xenon) and reduced ageing. • Measurements will continue in order to reduce the systematic uncertainties and to extract the ion mobilities and compare with existing data. • Hopefully next meeting we can show the final picture! 

  21. Appendix

  22. Experimental procedure for gain measurements. • The rate was monitored with a CAMAC scaler and corrections for the system dead-time applied. In these measurements this correction is at most 13%. • The current was measured with a power supply of 1 nA resolution. At low gains, a Keithley picoamperemeter with resolution below pA was used. • The pressure and temperature were monitored continuously, and the operating voltage re-normalized to the corresponding voltage at P=1000 bar and T=20 oC, to account for changes in density. • The rate over the chamber was kept at the level of 10 kHz for gains M>105 and at the level of 120 kHz for gains M<105 (this reduces the space-charge at high gains, simplifying the theoretical description). This was achieved for all the gas mixtures studied, by accommodating the different X-ray conversion probabilities with changes in the current of the tube. • Measurements for s = 2, 3, 4 mm and gas mixtures of Ne,Ar,Xe/CO2 at concentrations of noble gas f = 0, 10, 20, 40, 60, 80, 90, 99 were performed

  23. X-ray tube vs (reference) Fe55 source (I). The energy distributions are very similar but, in the case of the source, the measured distribution is dominated by the detector resolution and in the case of the tube it is dominated by the shape of the primary X-ray distribution. Ar/CO2 (80/20) escape peak

  24. X-ray tube vs (reference) Fe55 source (II). Good mutual agreement (below 5%) between both! SO: Once calibrated in energy, the tube was used for the whole data taken

  25. 2.1. Measurements on gain.

  26. Typical measurements (Xenon). Curves fitted to the phenomenological expression

  27. Typical measurements (Argon). Curves fitted to the phenomenological expression

  28. Gain systematics as a function of the fraction of Xenon and chamber pitch s.

  29. Gain systematics as a function of the gas mixture.

  30. 2.2 The glow-discharge.

  31. A. Battiato The glow discharge. Photon or ion feedback may result in re-generation of electrons close to the cathode that causes a self-sustained current in the detector (glow-discharge). In this kind of mixtures and at this temperature and pressure conditions, it is the main cause of gain limitation of the detectors

  32. Maximum gain before the onset of the glow discharge for Xenon. PRELIMINARY! The maximum achievable gain is rather independent on the quencher, being suggestive of the presence of ion feedback.

  33. Maximum gain before the onset of the glow discharge for different gas mixtures. PRELIMINARY! Maximum gain in Neon and Argon mixtures depend strongly on the quencher, being suggestive of photon feedback.

  34. C. Garabatos Comparison with models (Magboltz). Meta-stable Ar* always appear during the avalanche process. If Ar*finds a CO2 molecule, it can be de-excited upon ionization of it (Penning effect). The fraction of Ar* atoms that undergoes Penning or ‘Penning fraction’ is a free parameter, but can be constrained by our data since it depends only on the mixture. Ar/CO2 (80/20) PRELIMINARY!

  35. 2. Measurements on rate capability.

  36. Experimental procedure for rate capability measurements. • The gain was measured as a function of the primary rate. The dead-time of the system was estimated (and corrected) by making use of the proportionality between the current of the X-ray tube and the primary rate, and using a phenomenological model with only 1 free parameter. • The area of illumination has been measured by exposing a Polaroid film. • The current was measured • through the power supply. • The rate was measured with • a NIM scaler.

  37. Rate capability. The ‘standard model’ (I). E. Mathieson, NIM A 249(1986)413 In the particular case where , the dependence of the gain with rate is given by the transcendental equation: Where nois the initial number of clusters, φthe primary flux in [Hz/cm2], Clis the capacitance per unit length, μ the ion mobility, s the wire pitch and h the gap between anode and cathode.

  38. A. Kalweit Rate capability. Data and model. XENON. Xenon/CO2 (90/10)

  39. A. Kalweit Rate capability. Data and model. XENON. Xenon/CO2 (80/20)

  40. G. Hamar Rate capability. Data and model. ARGON.

  41. G. Hamar Rate capability. Data and model. ARGON.

  42. Rate capability. Data and model. NEON.

  43. Rate capability. The ‘standard model’ (2). From expression: The flux at arbitrary drop in gain (F), can be obtained: That we denote as ‘rate capability’

  44. Rate capability. The ‘standard model’ (3). • Parameters of the model: • For the mobility it is assumed that it is the CO2 who actually drifts and the Blanc’s additive law is valid. The values of the mobility in pure gases are then obtained from existing tables. For simplicity, the mobility at zero field is taken and assumed to be constant. • For the primary ionization, the values reported in Sauli’s yellow paper are used. • The mobility of CO2+ in Xe has not been directly measured (up to my knowledge) so I took as an ansatz that the mobility of Xe+ in Xe scales to the one of CO2+ in Xe in the same way that Ar+ in Ar scales to CO2+ in Ar.

  45. Rate capability. All in one. PRELIMINARY! required by CBM

  46. Conclusions. • The gain and rate capability has been measured for several chambers and gases, and seems to be reasonably well described by transport models (Magboltz). • The maximum operating gain in Xenon mixtures is systematically below Argon and Neon. • The rate capability of the chambers has been measured and is well described within 20% for Xenon, Argon and Neon mixtures by using the Mathieson formula. The good agreement gives some confidence on how to extrapolate to different geometries, mixtures and primary ionization. • Given the energy loss for mips in Xe (ΔE~5 KeV/cm), it seems that the rate capability in Xe/CO2 based mixtures for 4 mm chambers and M=104 fits to the CBM requirements. Drops in gain are expected to be below 5%.

  47. Outlook. • Improve the quality of the analysis of the existing data on rate capability under X-ray illumination. In particular, the existing data has been analyzed independently by different people. • An assessment of the dependence of the rate capability with the beam size must be pursued before extracting further conclusions. • Analysis of data under illumination with ionizing particles will be pursued in short term.

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