Title: The Development of Largearea Picosecondresolution Detectors
1The Development of Large-area Picosecond-resolutio
n Detectors
- Henry J. Frisch
- Enrico Fermi Institute and Argonne Natl. Lab.
- OUTLINE
- SOME APPLICATIONS sub-ps to 100 ps 25cm2 to
10,000 m2 - GRAND CHALLENGE Can we get from 100 ps to 1 ps?
If not, why not? (if so, 0.1 ps?? Limit?) - Argonne has unique world-class resources in MSD,
APS, ES, and MCS Divisions- HEP has access to
them- and they welcome it. - Applications revisited
2Fast Timing and TOF in HEP
Henry Frisch Enrico Fermi Institute, University
of Chicago
- Long-standing motivation- understanding the basic
forces and particles of nature- hopefully
reflecting underlying symmetries
CDF-1979 to present
Discoveries Top quark B_s Mixing Measurements Ma
ny many many- and many more not done yet
Not light compared to Atlas and CMS ( 5000 tons)
3Fast Timing and TOF in HEP
- I believe that the existence of flavor- up,
down, strange, charm, bottom, and top is
essential, in the sense that if we cant
understand it in a deeper way, were in the grip
of initial conditions rather than fundamental
symmetries or principles. - Really a deep divide between the string landscape
community, who are stuck with 10500 equally
possible universes, and us, who have this one
characterized by small integers and interesting
patterns. (Aside- This latter, I believe, is the
future area for Fermilab).
4Application 1 (my initial motivation) Fast
Timing and TOF in HEP
- 1. We (you, we_all) spend big bucks/year
measuring the 3-momenta of hadrons, but cant
follow the flavor-flow of quarks, the primary
objects that are colliding. Principle measure
ALL the information. - 2. Quarks are distinguished by different masses-
up and down are light (MeV), strange a few 100
MeV, charm 1.7 GeV, bottom 4.5 GeV, top 170. - 3. To follow the quarks- 2 direct ways- lifetime
(charm,bottom), measuring the mass (strange). - 4. To measure the mass, measure p and v (vL/dt)
5The unexplained structure of basic building
blocks-e.g. quarks
The up and down quarks are light (few MeV), but
one can trace the others by measuring the mass of
the particles containing them. Different models
of the forces and symmetries predict different
processes that are distinguishable by identifying
the quarks. Hence my own interest.
Q2/3
M2 MeV
M1750 MeV
M175,000 MeV
M300 MeV
M4,500 MeV
Q-1/3
M2 MeV
Nico Berry (nicoberry.com)
6A real CDF Top Quark Event
T-Tbar -gt WbW-bbar
W-gtcharm sbar
Measure transit time here (stop)
B-quark
T-quark-gtWbquark
T-quark-gtWbquark
B-quark
Cal. Energy From electron
- Fit t0 (start) from all tracks
W-gtelectronneutrino
Can we follow the color flow through kaons, cham,
bottom? TOF!
7Application 1- Collider Detector UpgradeCharged
Particle ID
- E.g- Tevatron 3rd-generation detector (combine D0
and CDF hardcore groups) ATLAS Upgrade (true
upgrade) - One example- precision measurements of the top
and W masses
8MW-Mtop Plane
MW 80.398 \pm 0.025 GeV (inc. new CDF
200pb-1) MTop 170.9 \pm 1.8 GeV (March
2007)
9Application 1- Collider Detector Upgrades
Take a systematics-dominated measurement e.g.
the W mass.
Dec 1994 (12 yrs ago)- Here Be Dragons Slide
remarkable how precise one can do at the Tevatron
(MW,Mtop, Bs mixing, )- but has taken a long
time- like any other precision measurements
requires a learning process of techniques,
details, detector upgrades.
10Application 1a- Collider Detector UpgradePhoton
Vertexing
- Real data- 3 events in one beam crossing
- 2 events at same place 2 at same time
- Can distinguish in the 2D space-time plane
11Application 2 Fixed-target GeometriesParticle
ID and Photon Vertexing
Geometry is planar- i.e. the event is projected
onto a detection plane. Timing gives the path
length from the point on the plane to the
interaction. New information for vertexing,
reconstruction of p0 s from 2 photons, direction
of long-lived particles. Very thin in
zdirection, unlike Cherenkovcounters. Can give
a space-point with all 3 coordinates- x,y and
z Key new information- gives tomographic
capability to a plane
Thin Pb Converter
12Application 3- Neutrino Physics
Constantinos Melachrinos (Cypress) (idea of
Howard Nicholson)
- Example- DUSEL detector with 100 coverage and 3D
photon vertex reconstruction. - Need gt10,000 square meters (!) (100 ps resolution)
13Application 4- Medical Imaging (PET)
Advantages Factor of 10 cheaper (?) depth of
interaction measurement 375 ps resolution (H.
Kim, UC)
14Application 5- Nuclear Non-proliferation
Havent thought about this yet- looking for
interested ANL folks. But
- MCPs 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
An area for possible applications- needs thought
15Why has 100 psec been the for 60 yrs?
Typical path lengths for light and electrons are
set by physical dimensions of the light
collection and amplifying device.
These are now on the order of an inch. One inch
is 100 psec. Thats what we measure- no surprise!
(pictures from T. Credo)
Typical Light Source (With Bounces)
Typical Detection Device (With Long Path Lengths)
16Characteristics we need
- Small feature size ltlt 300 microns
- Homogeneity (ability to make uniform large-area-
think solar-panels, floor tiles) - Fast rise-time and/or constant signal shape
- Lifetime (rad hard in some cases)
- Intrinsic low cost application specific
(low-cost materials and simple batch fabrication)
17Our Detector Development- 3 Prongs
- Readout Transmission lineswaveform sampling
- Anode is a 50-ohm stripline- can be long
readout 2 ends - CMOS sampling onto capacitors- fast, cheap,
low-power - Sampling ASICs demonstrated and widely used
- Go from .25micron to .13micron 8ch/chip to
32/chip - Simulations predict 2-3 ps resolution with
present rise times, 1 with faster MCP - MCP development
- Use Atomic Layer Deposition for emissive
materials (amplification) passive substrates - Simulation of EVERYTHING as basis for design
- Modern computing tools plus some amazing people
allow simulation of things- validate with data.
18 Generating the signal (particles)
- Use Cherenkov light - fast
Incoming rel. particle
Custom Anode with Equal-Time Transmission Lines
Capacitative. Return
A 2 x 2 MCP- actual thickness 3/4 e.g. Burle
(Photonis) 85022-with mods per our work
Collect charge here-differential Input to 200 GHz
TDC chip
19Micro-channel Plates
- Currently the glass substrate has a dual
function- - To provide the geometry and electric field like
the dynode chain in a PMT, and - To use an intrinsic lead-oxide layer for
secondary electron emission (SEE)
Micro-photograph of Burle 25 micron tube- Greg
Sellberg (Fermilab)- 2M/m2- not including
readout
20Get position AND timeAnode Design and
Simulation(Fukun Tang)
- Transmission Line- readout both endsgt pos and
time - Cover large areas with much reduced channel
account.
21Photonis Planicon on Transmission Line Board
- Couple 1024 pads to strip-lines with
silver-loaded epoxy (Greg Sellberg, Fermilab).
22Comparison 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
23Scaling Performance to Large AreaAnode
Simulation(Fukun Tang)
- 48-inch Transmission Line- simulation shows 1.1
GHz bandwidth- still better than present
electronics.
24Proof of Principle
- Camden Ertley results using ANL laser-test stand
and commercial Burle 25-micron tube- lots of
photons - (note- pore size may matter less than current
path!- we can do better with ALD custom designs
(transmission lines))
25Measurements in ANL laser test-stand
Jean-Francois Genat, Ed May, Eugene Yurtsev,
John Anderson, Karen Byrum, Gary Drake, Camden
Ertley, Tyler Natoli Bob Wagner
26ANL Test-stand Measurements
Jean-Francois Genat, Ed May, Eugene Yurtsev
- Sample both ends of transmission line with
Photonis MCP (not optimum)
2 ps 100 microns measured
27Large-area Micro-Channel Plate Panel Cartoon
N.B.- this is a cartoon- working on workable
designs-
Front Window and Radiator
Photocathode
Pump Gap
Low Emissivity Material
High Emissivity Material
Normal MCP pore material
Gold Anode
50 Ohm Transmission Line
Rogers PC Card
Capacitive Pickup to Sampling Readout
28Cartoon of a frugal MCP
- Put all ingredients together- flat glass case
(think TVs), capillary/ALD amplification,
transmission line anodes, waveform sampling
29Mechanical Assembly sketch
- Rich Northrop, Bob Stanek, HF, Michael Minot
- Scalable in modules
- Based on Ossys Planicon overall design
- Strong industry involvement Incom, CPS
Technologies, MinoTek- adding others
30Can dial size for occupancy, resolution- e.g.
neutrinos 4by 2
31Plans to Implement This
Have formed a collaboration to do this in 3
years. 4 National Labs, 5 Divisions at Argonne, 3
companies, electronics expertise at UC and
Hawaii RD- not for sure, but we see no
show-stoppers
32Passive Substrates-1
- Self-assembled material- AAO (Anodic Aluminum
Oxide)- Hau Wang (MSD)
33More CNM capabilities-
Hau Wang-MSD
34Passive Substrates-2 Incom glass
capillary substrate
- New technology- use Atomic Layer Deposition to
functionalize an inert substrate- cheaper, more
robust, and can even stripe to make dynode
structures (?)
35Functionalization- ALD
- Jeff Elam, Thomas Prolier, Joe Libera (ESD)
36Functionalization- ALD
- Jeff Elam, Thomas Prolier, Joe Libera (ESD)
37MCP Simulation
- Zeke Insepov (MCSD) and Valentin Ivanov
(Muons,Inc)
38MCP Simulation
- Zeke Insepov (MCSD) and Valentin Ivanov
(Muons,Inc)
39MCP Simulation
- Zeke Insepov (MCSD) and Valentin Ivanov
(Muons,Inc)
40MCP Simulation
- Zeke Insepov (MCSD) and Valentin Ivanov
(Muons,Inc)
41Nano-structured Photocathode Development
- Bernhard Adams, Klaus Attenkofer (APS) Mike
Pellin, Thomas Prolier, Igor Veryovkin, Alex
Zinovev (MSD) Jeff Elam (ES)
42Nano-structured Photocathode Development
43Nano-structured Photocathode Development
44(No Transcript)
45Systematic Precise Characterization of SEE and PE
for materials
- Mike Pellin, Thomas Prolier, Igor Veryovkin, Alex
Zinovev (MSD)
46Systematic Precise Characterization of SEE and PE
for materials
47Photocathode Development- Test setup at
APS laser
- Bernhard Adams, Klaus Attenkofer, (APS), Matt
Wetstein (HEP)
48Measurements of transmission-line anode in
vacuum with photo-cathode and APS laser
- Bernhard Adams, Klaus Attenkofer, (APS), Matt
Wetstein (HEP)
49Front-end Electronics/Readout Waveform sampling
ASIC
First have to understand signal and noise in the
frequency domain
EFI Electronics Development Group Jean-Francois
Genat (Group Leader)
50Front-end Electronics/Readout Waveform sampling
ASIC
EFI Electronics Development Group H. Grabas,
J.F. Genat
- Varner, Ritt, DeLanges, and Breton have
pioneered waveformsampling onto an array of
CMOS capacitors - All these expert groups are involved (Hawaii
formally)
51Front-end Electronics/Readout Waveform sampling
ASIC
Herve Grabas
EFI Electronics Development Group Herve.
Grabas, J.F. Genat
52FY-08 Funds ChicagoAnode Design and
Simulation(Fukun Tang)
53Front-end Electronics
- Resolution depends on 3 parameters
- Number of PEs
- Analog Bandwidth
- Signal-to-Noise
- Wave-form sampling does well- CMOS (!)
54Front-end Electronics
- Wave-form sampling does well - esp at large Npe
55Front-end Electronics-II
- See J-F Genat, G. Varner, F. Tang, and HF
- arXiv 0810.5590v1 (Oct. 2008)- to be published
in Nucl. Instr. Meth.
56Status
- We have submitted the proposal to DOE its out
to 5 reviewers (wish us luck). - We are going ahead in the meantime due to support
from the Director and Mike Pellin and Harry
Weerts- Im amazed by Argonnes strength and
creativity and facilities! - We have a blog and a web page- feel free to look-
http//hep.uchicago.edu/psec (dont be bullied by
the blog). - So far no show-stoppers
57The End-
58BACKUP
59What would TOFlt10psec do for you?
- (disclaimer- I know next to nothing about LHCb,
b-physics, or the Collab. goals..- Im making
this up.needs work- would be delighted to see
someone pick this up.)
- If you can stand a little active material in
front of your em calorimeter, convert photons- 10
psec is 3mm IN THE DIRECTION of the photon flight
path- can vertex photons. Do pizeros, etas, KL
and KS, - This allows all neutral signature mass
reconstruction- new channels. e.g. the CP
asymmetry in BS-gtp K0 (J.Rosner suggestion) - Etas in general are nice e.g. BS-gtJ/psi eta
(again, J.R.) - With two planes and time maybe get to 1 psec,300
microns along flight path- can one vertex from
timing? - Searches for rare heavy long-lived things (other
than bs)- need redundancy. - May help with pileup- sorting out vertices.
60Photo-multiplier in a Pore
- Idea is to build a PMT structure inside each
pore- have a defined dynode chain of rings of
material with high secondary emissivity so that
the start of the shower has a controlled geometry
(and hence small TTS) - One problem is readout- how do you cover a large
area and preserve the good timing? - Proposed solution- build anode into pores,
capacitively couple into transmission lines to
preserve pulse shape.
61Jerrys s re-visited Solutions to get to
ltseveral psec resolution.
- TTS 3.8 psec (from a TTS of 27 psec)
- MCP development- reduce TTS- smaller
pores, smaller gaps, filter chromaticity, ANL
atomic-deposition dynodes and anodes. - Cos(theta)_cherenk 3.3 psec
- Same shape- spatial distribution (e.g.
strips and time-differences measure spot) - 3. Pad size 0.75 psec-
Transmission-line readout and shape
reconstruction - 4. Electronics 3.4 psec
fast sampling- should be able to get lt 2
psec (extrapolation of simulation to faster
pulses)