Proposed detector and data readout system for the India-based Neutrino Observatory(INO)

1. Proposed detector and data readout system for theIndia-based Neutrino Observatory(INO) B.Satyanarayana(For INO collaboration)Department of High Energy PhysicsTata Institute of Fundamental ResearchHomi Bhabha Road, Colaba, Mumbai, 400 005E-mail: bsn@tifr.res.in

2. Plan of the talk • Introduction • Proposed detector • RPC basics • RPC test stand • Gas mixing and distribution system • RPC R & D results • Electronics for the prototype detector; • Thoughts for the final detector • Status and future plan NSNI-2004, Kalpakkam, February 17-20, 2004

3. What and Why Neutrinos? • Neutrinos are one of the fundamental particles of matter. • Electrically neutral and were initially thought to be mass-less. • Three types or flavors of neutrinos known. • Recent evidence indicates that neutrinos have mass and also experience mixing among these flavors. • Neutrino oscillations can explain the discrepancy between theory and observations about its flux. • Neutrino mass can also be indirectly estimated by detecting its eventual oscillations. • Non-zero mass for neutrino has profound implications on fields as varied as nuclear physics, particle physics, astrophysics and cosmology. • Pioneering experiments at the KGF underground laboratories NSNI-2004, Kalpakkam, February 17-20, 2004

4. INO Collaboration B.S.Acharya, Sudeshna Banerjee, P.N.Bhat, S.R.Dugad, P.Ghosh, K.S.Gothe, S.K.Gupta, S.D.Kalmani, N. Krishnan, N. K Mondal, B.K.Nagesh , P.Nagaraj, Biswajit Paul, A.K.Ray, Probir Roy, B.Satyanarayana, S.Upadhaya, P.Verma Tata Institute of Fundamental Research, Homi Bhabha Road, Mumbai V.M.Datar, M.S.Bhatia, S.K.Kataria Bhabha Atomic Research Centre, Mumbai P. Bhattacharya, S.Bhattacharya, S. Chattopadhyay, A.Ghoshal, A.Goswami K. Kar, D.Majumdar, P.B.Pal, S. Saha, M. Sharan, S.Sarkar, S.Sen Saha Institute of Nuclear Physics, Kolkata S. Chattopadhyay, M.R.Datta Mazumdar, P.Ghosh, G.S.N.Murthy, T.Nayak, Y.P.Viyogi Variable Energy Cyclotron Centre, Kolkata  Amitava Raychaudhuri Calcutta University, Kolkata M.V.N.Murthy, D.Indumathi Institute of Mathematical Sciences, Chennai A. Datta, R.Gandhi, S.Goswami, S. Rakshit, P.Mehta Harish Chandra Research Institute, Allahabad S.C.Phatak, D.P.Mahapatra IOP, Bhubaneswar Amit Roy Nuclear Science Centre, New Delhi J.B.Singh, M.M.Gupta, V.Bhatnagar Panjab University, Chandigarh   S.D.Sharma Himachal Pradesh University, Simla A.Joshipura, S.Rindani P.R.L., Ahmedabad A.Bhadra,B.Ghosh,A.Mukherjee,S.K.Sarkar North Bengal University S.Umasankar IIT, Mumbai S.K.Singh AMU Scientific Advisors: G.Rajasekaran, Bikash Sinha, Ramnath Cowsik,V.S.Narasimham, H.S.Mani, Amit Roy 41 Experimentalists & Engineers 22 Theorists NSNI-2004, Kalpakkam, February 17-20, 2004

5. Proposed INO detector • RPC dimension: 3m X 2m • No of chambers: 11K • No of channels: 220K • No of TDC channels: 3K Magnetised iron calorimeter Iron 140 layers RPC 35KTons NSNI-2004, Kalpakkam, February 17-20, 2004

6. RPC principle of operation NSNI-2004, Kalpakkam, February 17-20, 2004

7. RPC rate capability NSNI-2004, Kalpakkam, February 17-20, 2004

8. RPC construction NSNI-2004, Kalpakkam, February 17-20, 2004

9. A small area RPC prototype Gas inlet Graphite coat Spacer Gas outlet HV terminals NSNI-2004, Kalpakkam, February 17-20, 2004

10. Cosmic muon trigger and timing NSNI-2004, Kalpakkam, February 17-20, 2004

11. RPC test setup Cosmic muon telescope NSNI-2004, Kalpakkam, February 17-20, 2004

12. NIM and CAMAC electronics NSNI-2004, Kalpakkam, February 17-20, 2004

13. Telescope rate monitoring NSNI-2004, Kalpakkam, February 17-20, 2004

14. Schematic of gas mixing unit NSNI-2004, Kalpakkam, February 17-20, 2004

15. Gas mixing unit Argon Iso-butane R134A(Freon) NSNI-2004, Kalpakkam, February 17-20, 2004

16. Schematic of digital gas bubble counter NSNI-2004, Kalpakkam, February 17-20, 2004

17. Digital gas bubble counter Temperature and RH meter NSNI-2004, Kalpakkam, February 17-20, 2004

18. Typical RPC pulse profiles Trigger pulse In streamer mode of operation, pulses are large (>100 mV into 50) and fast (tr < 1ns) X-Strip Y-Strip NSNI-2004, Kalpakkam, February 17-20, 2004

19. Typical RPC efficiency plot NSNI-2004, Kalpakkam, February 17-20, 2004

20. Typical timing distribution plots NSNI-2004, Kalpakkam, February 17-20, 2004

21. Typical time response plot NSNI-2004, Kalpakkam, February 17-20, 2004

22. Typical time resolution plot NSNI-2004, Kalpakkam, February 17-20, 2004

23. RPC typical charge distributions NSNI-2004, Kalpakkam, February 17-20, 2004

24. RPC typical mean charge plot NSNI-2004, Kalpakkam, February 17-20, 2004

25. RPC pulse height Vs timing plot NSNI-2004, Kalpakkam, February 17-20, 2004

26. RPC typical noise rate plot NSNI-2004, Kalpakkam, February 17-20, 2004

27. Typical cross-talk plots NSNI-2004, Kalpakkam, February 17-20, 2004

28. Summary of cross-talk measurements NSNI-2004, Kalpakkam, February 17-20, 2004

29. Gas mixtures’ study plots NSNI-2004, Kalpakkam, February 17-20, 2004

30. Effect of water vapour in gas NSNI-2004, Kalpakkam, February 17-20, 2004

31. Effect of water vapour in gas NSNI-2004, Kalpakkam, February 17-20, 2004

32. Recovering a damaged RPC • Purging with pure Argon at high flow rate. • Bubbling pure Argon through pure ethyl alcohol. • Bubbling pure Argon through 25% Ammonia solution for 24 hours without electric field. • Recovers efficiency and brings down noise rate. • Detail studies underway. NSNI-2004, Kalpakkam, February 17-20, 2004

33. RPC recovery plots No of hours of gas flow NSNI-2004, Kalpakkam, February 17-20, 2004

34. New RPC test setup 8020 Sections NSNI-2004, Kalpakkam, February 17-20, 2004

35. INO prototype detector • Detector and signal specifications • Detector dimensions: 1m X 1m X 1m • 14 layers of RPCs with 6cm iron plates interleaved. • Two signal planes orthogonal to each other and each having 32 pick-up strips • Total channels = 32 X 14 X 2 = 896 • Pulse height = 100 to 300mV; Rise time = < 1 ns • Pulse width = ~50ns; Rate ~ 1KHz • Trigger information • Expected trigger rate is few Hz • Required Trigger logic is m X n fold, where • m = 1 to 4; no. of consecutive channels in a layer • n = 5 to 1; no. of consecutive layers with m fold in each layer • ie m x n = (1 x 5) OR (2 x 4) OR (3 x 3) OR (4 x 2) • Information to be recorded on a trigger • Absolute arrival time of the trigger • Track identification (XYZ points in RPC layers) • Direction of track ( TDC information) • Miscellaneous information and calibration data • Monitoring health of the detector NSNI-2004, Kalpakkam, February 17-20, 2004

36. Readout scheme for prototype NSNI-2004, Kalpakkam, February 17-20, 2004

37. 32-channel front-end module NSNI-2004, Kalpakkam, February 17-20, 2004

38. Prototype detector trigger logic NSNI-2004, Kalpakkam, February 17-20, 2004

39. Readout scheme for final detector The keywords are channel count and fast timing NSNI-2004, Kalpakkam, February 17-20, 2004

40. Current status and future plan • Production and study of small area RPCs successful • Detailed study of effect of water vapour in gas • Repeatability of results and long term stability of RPC • Study of pickup strip materials and geometries • Production of prototype chambers (4 ft X 3 ft) • Gas mixing and distribution system for the prototype detector • Prototype electronics finalised • Production of circuit boards and other components in progress • Initial thoughts given on final electronics and DAQ schemes • Cooperative VLSI and ASIC development programmes explored NSNI-2004, Kalpakkam, February 17-20, 2004