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The Large-Area Psec Photo-detector Collaboration

The Large-Area Psec Photo-detector Collaboration. Henry Frisch Enrico Fermi Institute and Argonne National Laboratory. 4 National Labs, 5 Divisions at Argonne, 3 US small companies; electronics expertise at Universities of Chicago and Hawaii Goal of 3-year R&D- commercializable modules.

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The Large-Area Psec Photo-detector Collaboration

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  1. The Large-Area Psec Photo-detector Collaboration Henry Frisch Enrico Fermi Institute and Argonne National Laboratory 4 National Labs, 5 Divisions at Argonne, 3 US small companies; electronics expertise at Universities of Chicago and Hawaii Goal of 3-year R&D- commercializable modules.

  2. The Development of Large-area Detectors With Space and Time Resolution OUTLINE • Application Space: Four frontiers- time resolution, area, QE, and cost (different applications sit at different points in this 4D space, but not separated by large amounts of development effort- all 4 are fertile.) • The LAPPD Collaboration: present status, and introduction to the posters and breakout session • Challenges and Surprises (e.g., funding has been available at ANL for only 1 month- not yet available at SSL, Hawaii, UC, Arradiance, Minotech, Muons,Inc, Synkera,…) FRA_Chicago, 2009

  3. Motivationand Requirements FRA_Chicago, 2009

  4. PET (UC/BSD, UCB, Lyon) Collider (UC, ANL,SLAC,.. DUSEL (Matt, Mayly, Bob, John, ..) K->pnn (UC(?)) Security (TBD) Parallel Efforts on Specific Applications Explicit strategy for staying on task . LAPD Detector Development ANL,Arradiance,Chicago,Fermilab, Hawaii,Muons,Inc,SLAC,SSL/UCB, Synkera, U. Wash. Drawing Not To Scale (!) FRA_Chicago, 2009

  5. At colliders we measure the 3-momenta of hadrons, but can’t follow the flavor-flow of quarks,the primaryobjects that are colliding. 2-orders-of-magnitude in time resolution would all us to measure ALL the information=>greatly enhanced discovery potential. Application 1-Energy Frontier Specs: Signal: 50-10,000 photons Space resolution: 1 mm Time resolution 1 psec Cost: <100K$/m2: FRA_Chicago, 2009 t-tbar -> W+bW-bbar

  6. Application 2- Lepton Flavor Physics • Example- DUSEL detector with 100% coverage and 3D photon vertex reconstruction. • Need >10,000 square meters (!) (100 ps resolution) • Spec: signal single photon, 100 ps time, 1 cm space, low cost/m2 (5-10K$/m2)* (Howard Nicholson) * Hermetic DUSEL specs TBD FRA_Chicago, 2009

  7. Stimulated simulation effort on 4th(?) generation water Cherenkovs Slide from Matt Wetstein’s talk atNNN09 last week FRA_Chicago, 2009

  8. Stimulated simulation effort on 4th(?) generation water Cherenkovs Slide from Matt Wetstein’s talk atNNN09 last week FRA_Chicago, 2009

  9. Application 3- K->pnn • Thin planes allow sampling Cherenkov calorimeters with psec time and mm space resolution, probably at small loss of energy resolution (needs simulation). • For rare K decay expts this likely allows precise pizero vertex reconstruction from the times and positions of individual photons- strong constraint from pizero mass on backgds. • Cherenkov-based fine-grained (longitudintal) calorimetry discriminates against charged pion charge-exchange, overlaps • Transmission-line readout allows planar readout FRA_Chicago, 2009

  10. Application 4- Medical Imaging (PET) Reminder- mention new iniative in France for PET and Hadron Therapy using these ideas- US should not have to follow….. Depth of interaction measurement; 375 ps resolution (H. Kim, UC). (note distinguished ANL/UC history in medical imaging, esp. PET) Spec: signal 10,000 photons,30 ps time, 1 mm space, 30K$/m2, MD-proof FRA_Chicago, 2009

  11. Application 4- Medical Imaging (PET) Sampling Calorimeters work here too- Heejong Kim (UC) has tested putting an MCP ahead of the crystal- has a full MC FRA_Chicago, 2009

  12. Application 5- Nuclear Non-proliferation • MCP’s loaded with Boron or Gadolinium are used as neutron detectors with good gamma separation (Nova Scientific). • Large-area means could scan trucks, containers • Time resolution corresponds to space resolution out of the detector plane IF one has a t_0– i.e can do 3D tomography of objects Specs: Unknown An area for possible applications- need a counterpart to form an application group (Nova visits in 2 weeks). FRA_Chicago, 2009

  13. SUMMARYCharacteristics in common we need • Small feature size << 300 microns • Homogeneity – the ability to make uniform large-areas (think solar-panels, floor tiles, 50”-HDTV sets) • Intrinsic low cost: although application specific, all need low-cost materials and robust batch fabrication. Need to be simple. FRA_Chicago, 2009

  14. Using New Technologies to Exploit Fundamentally Simple Ideas FRA_Chicago, 2009

  15. Detector Development- 3 Prongs MCP development- use modern fab processes to control emissivities, resistivities, out-gassing Use Atomic Layer Deposition for emissive material (amplification) on cheap inert substrates (glass capillary arrays, AAO). Scalable to large sizes; economical; pure – i.e. chemically robust and stable. Readout: Use transmission lines and modern chip technologies for high speed cheap low-power high-density readout. Anode is a 50-ohm stripline. Scalable up to many feet in length ; readout 2 ends; CMOS sampling onto capacitors- fast, cheap, low-power. Use computational advances -simulation as basis for design Modern computing tools allow simulation at level of basic processes- validate with data. FRA_Chicago, 2009

  16. Micro-channel Plates PMTs Satisfies small feature size and homogeneity Photon and electron paths are short- few mm to microns=>fast, uniform Planar geometry=>scalable to large areas FRA_Chicago, 2009

  17. Simplifying MCP Construction Conventional Pb-glass MCP OLD Incom Glass Substrate NEW Chemically produced and treated Pb-glass does 3-functions: • Provide pores • Resistive layer supplies electric field in the pore • Pb-oxide layer provides secondary electron emission Separate the three functions: • Hard glass substrate provides pores; • Tuned Resistive Layer (ALD) provides current for electric field (possible NTC?); • Specific Emitting layer provides SEE FRA_Chicago, 2009

  18. Glass Substrate Status ANL, Chicago, Incom, Minotech, SSL • Have received multiple samples of 10-micron, 20-micron, 40-micron glass substrates from Incom in 3/4”-sq and 33 mm round formats (latter the SSL/ANL development format) • Incom has ordered 8”x8” shell- they are sharing development cost (largely paying for it, in fact) • Incom is refining 8”x8” process- changes to draw, grinding, polishing. Very responsive to our needs, very flexible. FRA_Chicago, 2009

  19. Self-Assembled Passive Substrates AAO Group: Hau Wang (ANL), Dmitry Routkevitch (Synkera)+postdoc, Synkera • Alternative to glass capillary substrate- parallel path. • Some advantages: batch production (could be very cheap), inherent purity, low radioactivity • May naturally allow funnel geometry with reflection photocathode (could be very very fast and cheap) • Longer development path, at present glass is priority FRA_Chicago, 2009

  20. Functionalization- ALD ALD Group: Jeff Elam, Anil Mane, Qing Peng, Thomas Proslier (ANL:ESD/HEP), Neal Sullivan (Arradiance), Anton Tremsin (Arradiance, SSL) Jeff Elam, Thomas Proslier FRA_Chicago, 2009

  21. Functionalizing Incom samples ALD Group: Jeff Elam, Anil Mane, Qing Peng, Thomas Proslier (ANL:ESD/HEP), Neal Sullivan (Arradiance), Anton Tremsin (Arradiance, SSL) Jeff Elam, Thomas Proslier (ESD) ALD film Cross-sectional EDAZ of JE1401a ALD ZnO and AL203 extend into pores Sputtered Au only on edge of pores SEM from Middle of JE1401a 100 nm ALD film visible in middle of MCP FRA_Chicago, 2009

  22. ALD-Functionalized substrates Picture is seam between blocks Jeff Elam, Thomas Prolier (ESD) FRA_Chicago, 2009

  23. MCP and Photocathode Testing First measurements of gain in an ALD SEE layer at the APS laser test setup (Bernhard Adams, Matthieu Cholet, and Matt Wetstein) Testing Group: Bernhard Adams, Matthieu Cholet, and Matt Wetstein at the APS, Ossy Siegmund’s group at SSL N. B.! LAPPD Preliminary (very) FRA_Chicago, 2009

  24. Characterization of Secondary Emission, Photo-Emission of Materials Characterization Group: Igor Veryovkin, Thomas Proslier, Alexander Zinovev (MSD), postdoc (meets biweekly, joint with photocathode group- perhaps ALD gp too in the future.) • Constructing dedicated setup for low-energy SEE and PE measurements of ALD materials- parts on order. (will see on tour in Bld 200). Goal is systematic exploration of best SEE materials • Has parts-per-trillion capability for characterizing photocathodes after exposure to Argon, MCP’s before&after scrubbing, aging. Goal is to avoid having to scrub, aging- it is essential to measure and understand the surface chemistry. • Planning interfaces to SSL, APS vacuum systems, common sample database • Has close ties/overlap with ALD and testing groups FRA_Chicago, 2009

  25. Photocathode Group Photocathode Group: Klaus Attenkofer(APS), Sharon Jelinsky(SSL), Jason McPhate(SSL), Mike Pellin (MSD), Ossy Siegmund (SSL), Thomas Proslier(MSD), Zikri Yusof(HEP), postdoc (meets biweekly, joint with characterization group) Work is going on on multiple fronts- the photo-cathode is probably the most complex area we are dealing with. Bialkali photocathodes are not hard to make, have good QE and a spectral response well matched to water cherenkov counters and most optical applications. We (will) have a strong effort on them at SSL, which has the experience and a long track record. This will ensure having a solution as good as typical commercial tubes. At the same time, there is a strong case to be made that there can be substantial improvements in QE (see Townsend’s paper), spectral matching, and possibly chemical robustness. In addition, MCP’s may allow reflection rather than transmission cathodes, with big gains in speed (sub-psec) and QE. There may be new ideas based on ALD, e.g., (see Mike Pellin’s, Greg Engel’s talks at Photocathode workshop) that are feasible and disruptive. We are reaching out to university groups to access high-end facilities and young talent- UIUC, UIC, and WashU. (Yes, risky, but high payoff- if not us, who? see Chu, Koonin) FRA_Chicago, 2009

  26. SSL Photocathode Group Sharon Jelinsky(SSL), Jason McPhate(SSL), Ossy Siegmund (SSL), • Sealed tubes with up to 5” format havebeen processedwith multialkaliphotocathodes • MCPs and delayline readout From Ossy Siegmund’s talk at the First Photocathode Workshop, July 20-21, Univ. of Chicago/ANL FRA_Chicago, 2009

  27. MCP Simulation- use to make informed decisions on materials, geometry, field,… Simulation Group: Zikri Yusov, Valentin Ivanov (Muons,Inc), Sergey Antipov (HEP), Zeke Insepov (MCSD) , Anton Tremsin (SSL/Arradiance ), Neal Sullivan (Arradiance) FRA_Chicago, 2009

  28. MCP Simulation • Zeke Insepov (MCSD) and Valentin Ivanov (Muons,Inc) FRA_Chicago, 2009

  29. MCP Simulation • Zeke Insepov (MCSD) and Valentin Ivanov (Muons,Inc) FRA_Chicago, 2009

  30. Front-end Electronics/Readout Waveform sampling ASIC Electronics Group: Jean-Francois Genat, Gary Varner, Mircea Bogdan, Michael Baumer, Michael Cooney, Zhongtian Dai, Herve Grabas, Mary Heintz, James Kennedy,Sam Meehan, Kurtis Nishimura,Eric Oberla, Larry Ruckman, Fukun Tang (meets weekly) First have to understand signal and noise in the frequency domain FRA_Chicago, 2009

  31. Front-end Electronics Resolution depends on 3 parameters: Number of PhotoElectrons, Analog Bandwidth, and Signal-to-Noise Wave-form sampling is best, and can be implemented in low-power widely available CMOS processes (e.g. IBM 8RF). Low cost per channel. See J-F Genat, G. Varner, F. Tang, and HF arXiv: 0810.5590v1 (Oct. 2008)- now published in Nucl. Instr. Meth. FRA_Chicago, 2009

  32. Front-end Electronics/Readout Waveform sampling ASIC prototype • Varner, Ritt, DeLanges, and Breton have pioneered waveform–sampling onto an array of CMOS capacitors. FRA_Chicago, 2009

  33. First 0.13micron ASIC due back Oct. 20 The chip submitted to MOSIS -- IBM 8RF (0.13 micron CMOS)- 4-channel prototype. Plan on 16 channels/chip- possibly 32 later (??). FRA_Chicago, 2009

  34. Get position AND timeAnode Design and Simulation(Fukun Tang) • Transmission Line- readout both ends=> pos and time • Cover large areas with much reduced channel account. • US Patent FRA_Chicago, 2009

  35. Photonis Planicon on Transmission Line Board Couple 1024 pads to strip-lines with silver-loaded epoxy (Greg Sellberg, Fermilab). FRA_Chicago, 2009

  36. Comparison of measurements (Ed May and Jean-Francois Genat and simulation (Fukun Tang) • Transmission Line- simulation shows 3.5GHz bandwidth- 100 psec rise (well-matched to MCP) • Measurements in Bld362 laser teststand match velocity and time/space resolution very well FRA_Chicago, 2009

  37. Scaling Performance to Large AreaAnode Simulation(Fukun Tang) • 48-inch Transmission Line- simulation shows 1.1 GHz bandwidth- still better than present electronics. KEY POINT- READOUT FOR A 4-FOOT-WIDE DETECTOR IS THE SAME AS FOR A LITTLE ONE- HAS POTENTIAL… FRA_Chicago, 2009

  38. ANL Test-stand Measurements Jean-Francois Genat, Ed May, Eugene Yurtsev Sample both ends of transmission line with Photonis MCP (not optimum) 2picoseconds; 100 microns measured FRA_Chicago, 2009

  39. Test Fixture for integration of ASIC and transmission-line anode being designed ``Both parts are completely routed and ready for submission after pinout check etc.” Illustration of how we operate- close Hawaii/UC collaboration on ASIC, system design. Larry Ruckman (Hawaii)- From our electronics blog (open to all- go to http://hep.uchicago.edu/psec) Test fixture for OptionE glass anode interface to first proto-type sampling ASIC – test bandwidth, reflections, cross-talk. FRA_Chicago, 2009

  40. Mechanical Assembly Mechanical Group: Dean Walters (NE), Rich Northrop (UC), Henry Frisch (UC), Michael Minot (Minotech Eng.), Greg Sellberg (Fermilab) Ossy Siegmund (SSL), Anton Tremsin (SSL/Arradiance), R. Wagner (HEP)+0.5postdoc, Sam Asare (UC), Rahul Barwhani (UCB) Group meets weekly Ongoing work on: • Sealing- tray options A,C,E; window seal • Anode fabrication, testing • Sealed-tube considerations- outgassing, getters, surface-physicsAssembly- • Vacuum assembly/Alternatives • Cost (a driver for everything) FRA_Chicago, 2009

  41. Cartoon of the `Frugal’ MCP • Put all ingredients together- flat glass case (think TV’s), capillary/ALD amplification, transmission line anodes, waveform sampling FRA_Chicago, 2009

  42. In principle, can dial size for occupancy, resolution- e.g. neutrinos 4’by 2’ This is not what we will do first…. FRA_Chicago, 2009

  43. Mechanical Assembly 8” proto-type stack Design sketch 8” proto-type mock-up FRA_Chicago, 2009

  44. Administration Transparency/Dissemination Administration Group: Karen Byrum (co-PI), Henry Frisch (co-PI), Bob Wagner (Project Physicist), Dean Walters (Project Engineer) • Weekly all-subgroup meeting (Tues at 10 am) • Web site has Blogs used for weekly meeting- open to the world. Has played a significant role in interfacing to small technical companies (both reassuring and also interesting them). See http://hep.uchicago.edu/psec/ • Web site has Library of our talks, papers, internal notes, documents, backup materials,etc,- again, goal is to be transparent and accountable. • We have been running >= 2 workshops/year, 1 in Chicago, 1 in France. Very influential on a wide community-we benefit from contacts FRA_Chicago, 2009

  45. Internal Review Panels (open to additional suggestions). • Introduced on CDF- worked very very well. FRA_Chicago, 2009

  46. First Collaboration Meeting FRA_Chicago, 2009

  47. Thoughts on Role of FRA Funding • Allowed crucial proto-typing of ASICs and transmission lines, acquisition of commercial MCP’s and electronics, visiting students • Not large- 75K$ first yr; 90K$ 2nd yr, so only 25-30K$/institution/yr. Not enough alone… • Consequently should be spent at FNAL and ANL on things that are hard for a national lab, and at UC on things that are hard for a university group (i.e. use it for items not easily supported by federal spending). • In our case, being able to order expensive instrumentation and have foreign visitors made a huge difference (2-ledger accounts are worth their weight in gold). FRA_Chicago, 2009

  48. The End- FRA_Chicago, 2009

  49. BACKUP FRA_Chicago, 2009

  50. FY-09 Funds- Chicagoa) 40 GHz sampling electronics; b) Anode transmission lines c) Test Beam • FRA-FY08 has supported writing a proposal for funding for ASIC development- have all 4 teams as collab/advisors- seed funding will support finishing the proposal stage • Have 1st prototype transmission line board from FY08 funding- will test (laser first)- have plans for 2nd and 3rd (bigger area, capacitive coupling) • Anode/transmission line connection still in proto-type stage (Sellberg, Tang, Ertly, HF)- development costs (BEST in Rolling Hills). FRA_Chicago, 2009

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