Detector Stability Analysis Using MoRI Data

1. David Barnhill UCLA Detector Stability Analysis Using MoRI Data

2. Motivation • Monitor detector performance of key quantities: • Anode and Dynode Baselines • VEM Area and Area/Peak • Dynode Anode ratio • Detect any peculiar behavior as a function of temperature and/or time • Check Quality Assurance specifications suggested in November meeting

3. Method • We analyzed 188 preproduction tanks from January to February this year • We used LS Calibration Data (MoRI) • We analyzed RMS over this period for Anode and Dynode baselines and RMS/Mean for Dynode/Anode, VEM Area, and Area/Peak for each tank • We also looked at behavior over time and as a function of temperature • * In the next slides: • Then = September – October 2003 • Now = January – February 2004

4. Then Now Typical Baselines vs. Time

5. Then Anode Baseline RMS 3 out of spec – 2.2% Now 45 over 2 channel RMS 15 are due to pedestal readjustments 30 out of spec – 5.3%

6. Then Dynode Baseline RMS 1 out of spec – 0.7% Now 32 over 2 channel RMS 8 are due to pedestal readjustments 24 out of spec – 4.3%

7. Baseline RMS vs. Station ID Anode Dynode

8. Baseline Problems All 6 channels => FE problems? (~10 tanks)

9. Temperature Coefficients - Baselines Anode Then Now

10. Temperature Coefficients - Baselines Dynode Then Now

11. Typical LS VEM vs. Time and Temperature Then

12. Typical LS VEM vs. Time and Temperature Now

13. VEM Area vs. Station ID

14. LS VEM Area Then 6 out of spec – 4.4% Now 29 over 5% 11 due to recalib. 18 out of spec – 3.2%

15. Then Now Tank 205 (Mage) VEM Area PMT 1 seems to be decaying

16. Temperature – LS VEM Area LS VEM Area Then Now

17. Temperature Problem • As documented in Bugzilla: • http://bugzilla.auger.org.ar/ • There is a known problem with temperature causing jumps in certain quantities • Tanks 116, 147 and possible 158 and 167 • Problem is known, but cause and solution are unknown

18. Then Now Tank 147 VEM Area

19. Then Now Tank 116 VEM Area

20. New Problems

21. Then Now Typical LS VEM Area/Peak vs. Time

22. Area/Peak vs. Station ID

23. LS VEM Area/Peak Then All 3 PMTs in each tank affected 35 over 5% -> 6.2% 2 out of spec – 1.5% Now

24. Temperature - LS VEM Area/Peak Then Now

25. Then Now Typical Dynode/Anode Ratio

26. Dynode/Anode vs. Station ID

27. Then Dynode/Anode 7 out of spec -> 5.1% Now 8 out of spec -> 1.4%

28. Dynode/Anode Problems

29. Temperature – Dynode Anode Ratio Then Now

30. Then Now Tank 128 (Vatly) Dynode/Anode No entries in bugzilla

31. Then Now Dynode/Anode Spiky Behavior - Gone

32. Quality Assurance Specifications THEN NOW

33. Stability Conclusions • Pedestals: • All due to ~10 tanks with varying pedestals on all 6 channels • Area/Peak: • All 3 PMTs in a tank affected when one goes bad ~13 tanks • Statistics looks bad, but roughly divide 6.2% by 3 = ~2% problem • Dynode Anode ratio is more consistent and stable, 3 PMTs with bad D/A problem only • VEM Area • Temperature correlation issues ~7 PMTs • Other problems ~3 PMTs • Tanks with PMTs failing multiple specs: • 102, 193, 214, 262

34. PE at 1st Dynode

35. PE at 1st Dynode vs. Gain