LC-TPC R&D

1. LC-TPC R&D M. Ronan LBNL Berkeley and many others not mentionned from LBNL Berkeley, LAL Orsay, DAPNIA Saclay, IPN Orsay and LBNL Berkeley, CERN, Karlsruhe, MPI Munich • GEM, MicroMEGAS and MWPC techniques • Preliminary studies • drift velocities, positive ion feedback , aging, ... • Fe55, Sr90 and cosmic ray measurements • Mini-TPC construction and magnetic field test program M. Ronan LC-TPC R&D

2. Gas Electron Multiplier (GEM) • High (100 mm) pitch small pad response function • No ExB effects better resolution • Direct electron signal no losses • Efficient ion collection no gating grid ?? • Easy to build dead zones potentially small • Robust to aging insensitive to LC backgrounds • Multi-stage structures large gains (103-104) • Low mass construction no wire frames M. Ronan LC-TPC R&D

3. MicroMEGAS readout structures • High (50 mm) pitch small pad response function • No ExB effects better resolution • Direct electron signal no losses • Funnel effect very efficient ion collection • Electron amplification independent of the gap to first order promising dE/dx • Easy to build dead zones potentially small • Robust to aging insensitive to LC backgrounds • Good electro-mechanical stability large gains (103-104) • Low mass construction no wire frames M. Ronan LC-TPC R&D

4. Principle of operation • Very Drift space M. Ronan LC-TPC R&D

5. Gain Stability The gain variation is flat (maximal) as a function of the gap around a few 10mm Thus a MicroMEGAS TPC has a good potential for dE/dx measurements. M. Ronan LC-TPC R&D

6. Positive ion feed-back - funnel effect Due to diffusion, when S2 small wrt avalanche cloud size, the positive ions are unlikely to follow the field lines back into the drift space. • Very S1 Ideal feedback = Eamplification / Edrift = S2 / S1 Ions return to the grid: related space charge effects are suppressed S2 M. Ronan LC-TPC R&D

7. Gas studies Drift properties: to obtain a high drift velocity plateau at low E-field, an Ar-dominated carrier is required Hydrogen should be avoided because of neutron background Use of CF4 as a quencher improves sT M. Ronan LC-TPC R&D

8. Small-gap Wire TPC MicroMEGAS TPC 0 -340 V - 640 V 0 +2KV 0 - 300 V 55Fe 90Sr wires grid Cathode anode mesh Cathode 2mm 2mm 1cm 50 mm 1cm M. Ronan LC-TPC R&D

9. Magnetic field tests • The positive ion feedback doesn ’t depend on magnetic field for the Wire chamber or for MicroMEGAS M. Ronan LC-TPC R&D

10. Large Mini-TPC Test Chamber • Saclay 2 Tesla superconducting (MRI) magnet • STAR Front-End (FEE) electronics Analog waveform sampling at 10-40 MHz, 1024 channels with amplifier-shape, SCA, 10 bit ADC, 512 time slices deep, low noise • Modular VME data acquisition running VxWorks Stand-alone and MIDAS online systems, VB Pad Monitor, Java histogramming package • Removable detector endplate plan to test MicroMEGAS, asymmetric Wire chamber, options for spreading signal M. Ronan LC-TPC R&D

11. M. Ronan LC-TPC R&D

12. STAR READOUT ELECTRONICS TEST BENCH VME processor Pulse generator Optical link Mother board Front end cards M. Ronan LC-TPC R&D

13. M. Ronan LC-TPC R&D

14. CONCLUSION • Amplification, drift velocities, diffusion, aging, positive ion feedback, ... are being studied for GEM, MicroMEGAS and MWPC TPC ’s operating with different gases and readout technologies. • New results for a GEM TPC running on cosmic rays without a magnetic field. • First operation of a MicroMEGAS TPC in a magnetic field. • Strong multi-institution collaborations building GEM, MicroMEGAS and asymmetric Wire chamber Mini-TPCs for cosmic ray tests in high magnetic fields. M. Ronan LC-TPC R&D