1. Status of the Advanced Implantation Detector Array (AIDA) BRIKEN Collaboration Workshop Valencia, July 2015 Alfredo Estrade on behalf of the AIDA collaboration (Edinburgh – Liverpool – STFC DL & RAL – et al)

2. Outline AIDA overview Beam test at RIKEN (May 2015) Outlook

3. AIDA: Introduction Advanced Implantation Detector Array (AIDA) UK collaboration: University of Edinburgh, University of Liverpool, STFC Daresbury Laboratory & STFC Rutherford Appleton Laboratory SuperFRS Exotic nuclei ~ 50 – 200MeV/u Implant – decay correlations Multi-GeV implantation events Subsequent low-energy decays Tag events for gamma and neutron detectors Detector: multi-plane Si DSSD array wafer thickness 1mm 8cm x 8cm (128x128 strips) or 24cm x 8cm (384x128 strips) Instrumentation: ASIC low noise (<12keV FWHM), low threshold (0.25% FSR) 20GeV FSR plus ( 20MeV FSR or 1GeV FSR) fast overload recovery (~  s) spectroscopy performance time-stamping & independent DAQ instances

4. DSSD: MSL type BB18 128 x 128 strips (16384 pixels) multi-guard ring 0.560mm strip pitch 1mm wafer thickness 95 mm 71.6 mm

5. Front-End Electronics Mezzanine: 4x 16 channel ASICs Cu cover EMI/RFI/light screen cooling FEE: 4x 16-bit ADC MUX readout (not visible) 8x octal 50MSPS 14-bit ADCs Xilinx Virtex 5 FPGA PowerPC 40x CPU core/Linux OS – DAQ Gbit ethernet, timestamp, JTAG ports Power FEE width: 8cm Prototype – air cooling Production – recirculating coolant Each FEE64 card acts as an independent DAQ Each data word encoded with 48-bit timestamp Data merged at network switch and time-ordered by Linux workstation

6. Front-End Electronics Mezzanine: 4x 16 channel ASICs Cu cover EMI/RFI/light screen cooling FEE: 4x 16-bit ADC MUX readout (not visible) 8x octal 50MSPS 14-bit ADCs Xilinx Virtex 5 FPGA PowerPC 40x CPU core/Linux OS – DAQ Gbit ethernet, timestamp, JTAG ports Power FEE width: 8cm Prototype – air cooling Production – recirculating coolant Each FEE64 card acts as an independent DAQ Each data word encoded with 48-bit timestamp Data merged at network switch and time-ordered by Linux workstation

7. FEE64 data merging Each FEE64 card acts as an independent DAQ Each data word encoded with 48-bit timestamp Data merged at network switch and time-ordered by Linux workstation Workstation (data merging) Tape server (data storage) FEE#1 (64 ch) FEE#4 (64 ch) FEE#3 (64 ch) FEE#2 (64 ch) Clock 100MHz

8. AIDA: Supporting equipment Test setup at STFC Daresbury Lab: instrumentation for 32 FEE cards = 8 DSSD with 128x128 strips

9. DAQ integration with other detector systems Correlation of AIDA data with DAQ in different time domain (e.g. BigRIPS)

10. DAQ integration with other detector systems Correlation of AIDA data with DAQ in different time domain (e.g. BigRIPS) J. Agramunt

11. Run control software Web-based experiment and DAQ control software interface, including online monitor for raw data. Data merger for multiple FEE64 modules. Web-based MIDAS software interface:

12. AIDA at RIKEN AIDA equipment arriving at RIBF in RIKEN, April 2014. AIDA@F11 May2014 parasitic test

13. April 2014 Parasitic Beam test PID detectors (TOF?) beam movable degrader EURICA degrader veto scintillator AIDA beam stop for EURICA Stable operation of full DAQ system: 32 Front-end Electronics cards. Test of response to high energy signal from heavy ions. Identified instability of input signal at preamplifier stage when connected to DSSD capacitance load.

14. May 2015 Beam test at RIBF PID detectors Beam Variable degrader Al stopper MACi - plastic detector AIDA EURICA Parasitic beam test to SEASTAR in-beam gamma measurement: -setup at F11 -neutron-rich beams in Z~35 region; ≈ kHz rate. AIDA+EURICA

15. 2015 Test: stack with 3 DSSDs 3 x BB18 DSSD (3mm Si) 1 cm x Al plates as stopper

16. 2015 Test: setup at F11

17. Test results: DAQ Integration

18. Correlation Scalar/1.e6 event # scalar reset AIDA run started PID data (EURICA DAQ)

19. Test results: DAQ Integration offset= 11.5 usec Correlation Scalar/1.e6 event # scalar reset AIDA run started PID data (EURICA DAQ)

20. Test results: Resolution Resolution of front-end electronics Pulser resolution with BB18 DSSD 100 keV FWHM

21. Test results: Implantation (100Kr setting)

22. Test results: Decays [s] Decay of integrated activity (i.e. no PID cut) 88 Ge setting gate 99 Rb (t 1/2 = 55 ms) gate 100 Sr (t 1/2 = 200 ms)

23. Outlook AIDA operational at RIKEN. 20x MSL type BB18-1000 (AIDA DSSSD) available - 4x pre-production (~8uA leakage current), 16x production (~4uA) Wider snout (10.6 x 10.6 cm) with more room to fit DSSD/Kapton cables. new Kapton PCBs, 3 options being developed: 1) integrated Kapton PCB with lower capacitance per unit length 2) Kapton PCB (no integrated shielding, external shielding) 3) hybrid - Kapton+ribbon cable+external shielding AIDA FEE64 firmware updated data throughput 300 -> 400 kevents/s (per FEE64, 64 channels) Online/offline analysis tools under development (event reconstruction, implant-decay correlation, complete energy calibration).

24. Acknowledgements My thanks to: STFC DL I. Burrows, P. Coleman-Smith, A. Grant, M. Kogimtzis, I. Lazarus, S. Letts, P. Morrall, V. Pucknell, J. Simpson & J. Strachan STFC RAL D. Braga, M. Prydderch & S. Thomas University of Liverpool L. Harkness-Brennan, T. Grahn, P. Nolan, R. Page, S. Ritta-Antila & D. Seddon University of Edinburgh T. Davinson, A. Estrade, C. Griffin, Z. Liu, G. Lotay & P. Woods University of Brighton O. Roberts RIBF at RIKEN G. Lorusso, K. Matsui, S. Nishimura, H. Baba, P-A Soderstrom, G. Kiss, P. Bi, et al. IFIC at Valencia J. Agramunt.

25. AIDA: Project Partners The University of Edinburgh (lead RO) Phil Woods et al. The University of Liverpool Rob Page et al. STFC DL & RAL John Simpson et al. Project Manager: Tom Davinson Further information: http://www.ph.ed.ac.uk/~td/AIDAhttp://www.ph.ed.ac.uk/~td/AIDA TDR - November 2008: http://www.ph.ed.ac.uk/~td/AIDA/Design/aida_tdr.pdf

26. Test results: Resolution Pulser walkthough run (background) 207 Bi source run with BB18 DSSD

27. Test results: Resolution Resolution of front-end electronics 207 Bi source run with BB18 DSSD need better clustering algorithm?

28. Tests with pre-production components BENCH TESTING WITH SOURCE RESPONSE TO HEAVY IONS Beat test at GSI: 250 MeV/u 209 Bi Beam delivery direct to HTC Significant ballistic deficit effects Implies preamp risetime for high energy heavy- ions >500ns

29. Parasitic beam test at RIKEN PID detectors beam 78 Ni !!! movable degrader EURICA fixed degrader veto scintillator AIDA beam stop for EURICA

30. Outlook Experiments at RIBF for 2015++ –Decay spectroscopy with EURICA gamma-ray detector array. – Half-lives and Pn-values as part of BRIKEN collaboration setup (Beta-delayed neutrons at RIKEN). –TAS@RIKEN ?! Experiments at DESPEC setup in FAIR from 201X… AIDA expected to be ready for experiments by Fall 2014. BRIKEN setup

31. Parasitic test at RIBF Stable running of detector system under experimental conditions (10 days of beamtime). Tested data merging for full system, and clusterization algorithm. Identified issue of high noise for low amplitude range (20MeV) with BB18 sensor connected to system. Data analysis ongoing (K. Matsui, C. Griffins). Heavy ion signals (20 GeV range)