Presentation is loading. Please wait.

Presentation is loading. Please wait.

T. Sumiyoshi (TMU) 30, Nov. 2004 del Carmen 1 Development of HPD (HAP D) Photon-detector for the Aerogel RICH Photon-detector for the Aerogel.

Published byMaria McLaughlin Modified over 8 years ago

Similar presentations

Presentation on theme: "T. Sumiyoshi (TMU) 30, Nov. 2004 del Carmen 1 Development of HPD (HAP D) Photon-detector for the Aerogel RICH Photon-detector for the Aerogel."— Presentation transcript:

1 T. Sumiyoshi (TMU) 30, Nov. 2004 RICH04 @Playa del Carmen 1 Development of HPD (HAP D) Photon-detector for the Aerogel RICH Photon-detector for the Aerogel RICH Development of HPD and HAPD Development of HPD and HAPD  Prototype Test Readout Electronics Readout Electronics Summary Summary Aerogel Radiator Cherenkov photons Position sensitive Photon Detector Concept of the Aerogel RICH PID upgrade for the forward end-cap region. e-e+e+

2 T. Sumiyoshi (TMU) 30, Nov. 2004 RICH04 @Playa del Carmen 2 Photon-detector for the Aerogel RICH Requirements Requirements  Can detect a single-photon with high efficiency.  Have sensitivity to ~ 400nm photons from aerogel radiators (due to Rayleigh scattering).  Can detect the position of photons with a resolution ~ a few mm. a resolution ~ a few mm.  Immune to the high magnetic field (1.5 Tesla). HPD or HAPD may be the best candidates for the Photon-detector of the Aerogel RICH. HPD or HAPD may be the best candidates for the Photon-detector of the Aerogel RICH. Fine-mesh PMT: Poor resolution for single photons. Fine-mesh PMT: Poor resolution for single photons. MCP-PMT: 60% collection efficiency. MCP-PMT: 60% collection efficiency.

3 T. Sumiyoshi (TMU) 30, Nov. 2004 RICH04 @Playa del Carmen 3 Development of HPD and HAPD Develop a multi-anode HPD/HAPD with proximity focus. Develop a multi-anode HPD/HAPD with proximity focus. Make the effective area as large as possible. Make the effective area as large as possible. DEP catalogue Photocathode PD/APD HV e-e- Photons Output 8 kV

4 T. Sumiyoshi (TMU) 30, Nov. 2004 RICH04 @Playa del Carmen 4 Development of HPD and HAPD Outer: 72x72 mm 2 Effective : 59x59 mm 2 (65%) Multi-anode:12x12=144 ch. Pixel Size: 4.9x4.9 mm 2 Multi-anode (144ch) HPD/HAPD are under development in the cooperative work between Belle and HPK.

5 T. Sumiyoshi (TMU) 30, Nov. 2004 RICH04 @Playa del Carmen 5 Prototype Test -Single Channel HPD- Single channel HPD Single channel HPD Leak current : 4 [nA] Detector capacitance : 20 [pF] Gain (8kV) : 1500 [electron/photon] Bias voltage : 80 [V] Fig.2 ; single photon response & multi photon response 1pe 2pe 3pe 4pe Sensitive area : φ8[mm]

6 T. Sumiyoshi (TMU) 30, Nov. 2004 RICH04 @Playa del Carmen 6 Single-channel HPD Single-channel HPD : □5 [mm/ch] Diode : □5 [mm/ch] Gain : 26000 [electron/photon] Gain : 26000 [electron/photon] C d : 73 [pF] C d : 73 [pF] I L : 14 [nA] (average/ch) I L : 14 [nA] (average/ch) Condition: V HV =8[KV], V BIAS =320[V] Condition: V HV =8[KV], V BIAS =320[V] 1pe 2pe 3pe 4pe Prototype Test - 3×3multi-channel HAPD - Although the gain of the HAPD is higher than the HPD, noise level is also higher due to its large detector capacitance. The HPD shows better single photon resolution. 53 φ 15mm 1pe 2pe 3pe 4pe

7 T. Sumiyoshi (TMU) 30, Nov. 2004 RICH04 @Playa del Carmen 7 Structure of HPD and HAPD Two types of photodiodes are under development for the 4x(6x6) type HPD/HAPD. APD: surface irradiation type. PD ; back irradiation type. Can reduce dead area btw pixels (0.2->0.1mm) p pn n Surface irradiation typeBack irradiation type Photo electron APD PD

8 T. Sumiyoshi (TMU) 30, Nov. 2004 RICH04 @Playa del Carmen 8 Total gains of HPD and HAPD Gain vs PC Voltage.

9 T. Sumiyoshi (TMU) 30, Nov. 2004 RICH04 @Playa del Carmen 9 Development of HPD and HAPD Leakage current vs Bias voltage.

10 T. Sumiyoshi (TMU) 30, Nov. 2004 RICH04 @Playa del Carmen 10 Timing structure of HPD and HAPD Rise time

11 T. Sumiyoshi (TMU) 30, Nov. 2004 RICH04 @Playa del Carmen 11 Dead region of HPD and HAPD Dead region between the pads.

12 T. Sumiyoshi (TMU) 30, Nov. 2004 RICH04 @Playa del Carmen 12 Development of HPD and HAPD Leakage current before and after activation of PC. HPD HAPD Basic performance has been studied with the 3x3 type HPD /HAPD. 3x3 ch HPD No serious problem Higher EB gain than expected (1500 -> 2100). 3x3 ch HAPD Low yield of good quality APD’s. There is a HV leak from photocathode. High gain but very noisy. Further investigation is underway with a new production batch.

13 T. Sumiyoshi (TMU) 30, Nov. 2004 RICH04 @Playa del Carmen 13 Development of a 12x12 HAPD Production of 12x12 multi-anode HAPD. 4x (6x6) APD is assembled in this bulb by a transfer technology. After the activation many APD’s can’t sustain nominal bias voltage 380V. 73mm

14 T. Sumiyoshi (TMU) 30, Nov. 2004 RICH04 @Playa del Carmen 14 Response of the 12x12 HAPD Response to a single photoelectron and multi-photoelectrons. Single Photoelectron Multi Photoelectron

15 T. Sumiyoshi (TMU) 30, Nov. 2004 RICH04 @Playa del Carmen 15 Uniformity of a 6x6 APD Photocathode EB gain @-8kV

16 T. Sumiyoshi (TMU) 30, Nov. 2004 RICH04 @Playa del Carmen 16 Uniformity of a 6x6 APD Avalanche gain Total gain

17 T. Sumiyoshi (TMU) 30, Nov. 2004 RICH04 @Playa del Carmen 17 Uniformity of a 6x6 APD Over all response QE x gain

18 T. Sumiyoshi (TMU) 30, Nov. 2004 RICH04 @Playa del Carmen 18 Readout Electronics Total number of readout channels for the Total number of readout channels for the full detector amounts to 120k. full detector amounts to 120k. Detector characteristics Detector characteristics Leakage current 10 or 25 [ nA ] Leakage current 10 or 25 [ nA ] Detector capacitance ; 10 or 70 [ p F /pixel ] Detector capacitance ; 10 or 70 [ p F /pixel ] signal ; 2000 or 20000 [electron/photon] signal ; 2000 or 20000 [electron/photon] Need high density front-end electronics. Need high density front-end electronics. Need high gain with very low noise amplifiers. Need high gain with very low noise amplifiers. Deadtimeless readout scheme-> Pipeline. Deadtimeless readout scheme-> Pipeline. Develop an ASIC for the front-end electronics

19 T. Sumiyoshi (TMU) 30, Nov. 2004 RICH04 @Playa del Carmen 19 Rohm CMOS 0.35[μm]) Basic parameters for the ASIC (Rohm CMOS 0.35[μm]) Gain : 5 [V/pC] Shaping time : 0.15 [μs] VGA : 1-16 S/N : 8 (@2000[e]) Readout : pipeline with shift register Package : 18 channels/chip Control : LVDS Power consumption : 5 m W/channel Readout Electronics □ 4.93[mm] Made through VDEC PreampShaper VGA ComparatorShift register

20 T. Sumiyoshi (TMU) 30, Nov. 2004 RICH04 @Playa del Carmen 20 Readout Electronics Current n oise perfo rmance 4000 enc: about twice of SPICE simulation. It could be made half in the next iteration. Threshold behavior. It works as expected.

21 T. Sumiyoshi (TMU) 30, Nov. 2004 RICH04 @Playa del Carmen 21 Summary 12x12 HAPD is under development for the photon detectors of the proximity focusing RICH which 12x12 HAPD is under development for the photon detectors of the proximity focusing RICH which is a good candidate of the Belle PID system in future. is a good candidate of the Belle PID system in future. There still remains some problems: There still remains some problems: APD leakage current goes up after the activation of PC. APD leakage current goes up after the activation of PC. Some APD can’t keep nominal bias voltage. Some APD can’t keep nominal bias voltage. For a readout of many anode signals (120k ch.), For a readout of many anode signals (120k ch.), we have been developing an ASIC. we have been developing an ASIC. Basic performance was checked by test pulses. Basic performance was checked by test pulses. Need minor modification for a further improvement of noise Need minor modification for a further improvement of noise level (current S/N 5 → 8). level (current S/N 5 → 8).

Download ppt "T. Sumiyoshi (TMU) 30, Nov. 2004 del Carmen 1 Development of HPD (HAP D) Photon-detector for the Aerogel RICH Photon-detector for the Aerogel."

Similar presentations

Study of 144-channel Hybrid Avalanche Photo-Detector for Belle II RICH Counter VCI2010 Susumu Shiizuka Nagoya University for Belle II Aerogel RICH group.

Study of 144-channel Hybrid Avalanche Photo-Detector for Belle II RICH Counter VCI2010 Susumu Shiizuka Nagoya University for Belle II Aerogel RICH group.
Picosecond Timing Workshop 18 November 2005 1 Sales meeting 2005 Discovering the Future.

Picosecond Timing Workshop 18 November Sales meeting 2005 Discovering the Future.
Barrel PID upgrade K. Inami (Nagoya-u) and PID group - R&D status - TOP counter - iTOP - Focusing DIRC - To do, cost estimation.

Barrel PID upgrade K. Inami (Nagoya-u) and PID group - R&D status - TOP counter - iTOP - Focusing DIRC - To do, cost estimation.
PID Univ. 31.Aug.2002 Contents 1.Introduction 2.PMT structure & Set up 3.Basic performance 4.Experiment results –Gain –Time resolution.

PID Univ. 31.Aug.2002 Contents 1.Introduction 2.PMT structure & Set up 3.Basic performance 4.Experiment results –Gain –Time resolution.
Peter Križan, Ljubljana Peter Križan University of Ljubljana and J. Stefan Institute The HERA-B RICH counter.

Peter Križan, Ljubljana Peter Križan University of Ljubljana and J. Stefan Institute The HERA-B RICH counter.
*Shuji Maeo 1,2, Takayuki Yanagida 1, Yuui Yokota 1 and Akira Yoshikawa 1,3 1 Division of Physical Process Design, Institute of Multidisciplinary Research.

*Shuji Maeo 1,2, Takayuki Yanagida 1, Yuui Yokota 1 and Akira Yoshikawa 1,3 1 Division of Physical Process Design, Institute of Multidisciplinary Research.
Peter Križan, Ljubljana April 20, 2005Super B Factory Workshop, Hawaii Peter Križan University of Ljubljana and J. Stefan Institute For Belle Aerogel RICH.

Peter Križan, Ljubljana April 20, 2005Super B Factory Workshop, Hawaii Peter Križan University of Ljubljana and J. Stefan Institute For Belle Aerogel RICH.
2002.8.31PID Nagoya univ1 The possibility of improving TOP counter Nagoya university Yuji Enari.

PID Nagoya univ1 The possibility of improving TOP counter Nagoya university Yuji Enari.
Description of BTeV detector Jianchun Wang Syracuse University Representing The BTeV Collaboration DPF 2000 Aug 9 - 12, 2000 Columbus, Ohio.

Description of BTeV detector Jianchun Wang Syracuse University Representing The BTeV Collaboration DPF 2000 Aug , 2000 Columbus, Ohio.
Requirements to RICH FEE Serguei Sadovsky IHEP, Protvino CBM meeting GSI, 10 March 2005.

Requirements to RICH FEE Serguei Sadovsky IHEP, Protvino CBM meeting GSI, 10 March 2005.
10 Picosecond Timing Workshop 28 April 2006 1 PLANACON MCP-PMT for use in Ultra-High Speed Applications.

10 Picosecond Timing Workshop 28 April PLANACON MCP-PMT for use in Ultra-High Speed Applications.
Photon detection Visible or near-visible wavelengths

Photon detection Visible or near-visible wavelengths
Peter Križan, Ljubljana March 17, 2006 Super B Workshop, Frascati Peter Križan University of Ljubljana and J. Stefan Institute Aerogel RICH and TOP: summary.

Peter Križan, Ljubljana March 17, 2006 Super B Workshop, Frascati Peter Križan University of Ljubljana and J. Stefan Institute Aerogel RICH and TOP: summary.
APD, CSP and T-card Characteristics Toru Sugitate / Hiroshima University for PHOS FEE Review / PRR Meeting in Wuhan, China on.

APD, CSP and T-card Characteristics Toru Sugitate / Hiroshima University for PHOS FEE Review / PRR Meeting in Wuhan, China on.
C.Shalem et al, IEEE 2004, Rome, October 18 R. Chechik et al. ________________RICH2004_____________ Playa del Carmen, Mexico 1 Thick GEM-like multipliers:

C.Shalem et al, IEEE 2004, Rome, October 18 R. Chechik et al. ________________RICH2004_____________ Playa del Carmen, Mexico 1 Thick GEM-like multipliers:
Fast Detectors for Medical and Particle Physics Applications Wilfried Vogel Hamamatsu Photonics France March 8, 2007.

Fast Detectors for Medical and Particle Physics Applications Wilfried Vogel Hamamatsu Photonics France March 8, 2007.
Evaluation of Silicon Photomultiplier Arrays for the GlueX Barrel Calorimeter Carl Zorn Radiation Detector & Medical Imaging Group Jefferson Laboratory,

Evaluation of Silicon Photomultiplier Arrays for the GlueX Barrel Calorimeter Carl Zorn Radiation Detector & Medical Imaging Group Jefferson Laboratory,
MPPC Radiation Hardness (gamma-ray & neutron) Satoru Uozumi, Kobe University for Toshinori Ikuno, Hideki Yamazaki, and all the ScECAL group Knowing radiation.

MPPC Radiation Hardness (gamma-ray & neutron) Satoru Uozumi, Kobe University for Toshinori Ikuno, Hideki Yamazaki, and all the ScECAL group Knowing radiation.
Experimental set-up Abstract Modeling of processes in the MCP PMT Timing and Cross-Talk Properties of BURLE Multi-Channel MCP PMTs S.Korpar a,b, R.Dolenec.

Experimental set-up Abstract Modeling of processes in the MCP PMT Timing and Cross-Talk Properties of BURLE Multi-Channel MCP PMTs S.Korpar a,b, R.Dolenec.
Photodetection EDIT EDIT 2011 N. Dinu, T. Gys, C. Joram, S. Korpar, Y. Musienko, V. Puill, D. Renker 1 Micro Channel plate PMT (MCP-PMT) Similar to ordinary.

Photodetection EDIT EDIT 2011 N. Dinu, T. Gys, C. Joram, S. Korpar, Y. Musienko, V. Puill, D. Renker 1 Micro Channel plate PMT (MCP-PMT) Similar to ordinary.

Similar presentations

Ads by Google