The Experimental Program of the “FLASH” Experiment
Fluorescence efficiency is the foundation for our belief that we are measuring “energy”
• How well is it know ( for an ionizing particle)?
• Is it linear with particle number (size) in an extensive air shower?
• Can it be affected by “accidental” conditions? Impurities, etc.
• How do we determine answers to these issues with sufficient accuracy?
Second Knee, showing correlation between knee energy and spectral normalization
Second Knee Spectrum, Shifted to make knee come out at same energy
Second Knee, cont.
• All experiments agree when a scale shift is applied.
• But what is the actual energy of the second knee?
• Fluorescence method should be very reliable ( nearby events, little atmospheric attenuation ).
• Position comes primarily from our knowledge of air fluorescence efficiency.
Bunner Air-fluorescence spectrum
Current Understanding
• Bunner (1967), Kakimoto et al. (1995), Nagano et al. ( 2002, unpublished) indicates ~15% systematic errors in overall yield and larger errors in individual spectral lines.
• Ground based experiments – non-linear effects possible due to λ dependence of atmospheric attenuation.
• At 30 km, event energy can change by 25% if 390 nm line intensity changes by 40%.
Photon yields between 300 and 406nm from Nagano, Kakimoto( HiRes) and Bunner
Relative Contributions of Different Spectral Lines at Different Horizontal Distances
Relative Spectral Line Contribution to Energy
0
0.2
0.4
0.6
0.8
1
1.2
0 10 20 30 40
Horizontal Distance ( km)
Re
lati
ve c
on
trib
uti
on
(n
orm
ali
zed
to
910
)
316
337
355
390
Importance to Euso and OWL (space-based) experiments
• Path-lengths from shower to detector almost constant – small λ dependence (~10% integral variation over different fluorescence models)
• Most showers detected over oceans – effect of water-vapor and other impurities may be important. Some evidence for H2O quenching already exists.
Fluorescence Pressure Dependence
oo
onn
nnc
cocollisionquenchingradiation
pp
kMTp
p
kMT
1
'
11
1
4'
1
4
111111
int_
τ= lifetime
P=pressure
T=temp.
Reference Pressure
T
D
M
MMff
TkMp o
onnoonnn
n
o
co
2
4
'
1
Fluorescence Yield
• Y = photons per meter-ionizing particle
• P, P’ = pressure and reference pressure
• C = spectral line intensity at zero pressure
i
ii
ppp
CY
'1
Dependence of Air Fluorescence ( from Nagano et al (personal communication) at .85 MeV
Life time vs Pressure (Air) from Nagano et al.(p.c.)-at .85 MeV
• Air fluorescence lifetimes ~ 25 nsec
• Bunner quotes lifetimes near 40 nsec
• Large uncertainties remain.
Dependence on electron energy – Kakimoto et al. and T461
SLAC test run results
• Two week run in June 2002
• Prototype thin target setup
• Measured pressure dependence integrated over 300-400 nm.
• Measured average lifetime over 300-400 nm.
• Confirmed linear behaviour of Y with respect to beam current below 109 ppb
T461 Setup
LEDs
PMTs
SLAC test result on linearity
SLAC test result- comparison of N2 and Air efficiency
SLAC test N2 Decay Time Measurement
N2 (in air) Decay Time Measurement
SLAC Test and Beyond
• Test clearly established ability to detect air fluorescence in FFTB beams.
• Test showed that we can measure the pressure dependence and fluorescence lifetime integrated over total spectrum
• What is needed, however, is spectrally resolved pressure and lifetime measurement.
• Test only measured Y at 28.5 GeV. Energy dependence over realistic shower energies is required.
OBJECTIVES OF E-165
• Spectrally resolved measurement of fluorescence yield to better than 10%.
• Investigate dependence on electron energy.
• Study effects of atmospheric impurities.
• Observe showering of electron pulses in air equivalent substance (Al2O3) with energy equivalents around 1018 eV.
Proposed Program
• Gas Composition– N2/O2 dependence, and Ar, CO2, H2O impurities
• Pressure Dependence– Yield versus Pressure down to 10 torr
• Energy Dependence– Yield versus electron energy distribution down to
100keV
• Fluorescence Spectrum– Resolve individual bands using narrow band filters
or spectrometer.
• Pulse Width– Pressure dependence of fluorescence decay time
for each spectral band
THIN TARGET STAGE
• Pass electron beam through a thin-windowed air chamber.– Measure the total fluorescence yield in air at ~30
GeV.– Measure the yield over wide range of pressures at
and below atmospheric.– Measure emission spectrum using narrow band
filters or spectrometer.– Effects of N2 concentration. Pure N2 to air. Also H2O,
CO2, Ar, etc.
General Requirements for thin target run
• FFTB downstream of last magnets
• <1% R.L. in beam – no radiation problem
• Require 108 – 109 e/pulse for linear operation.
• Require improved torroid sensitivity to monitor beam at this intensity (or equivalent cross-calibrated measurement).
THICK TARGET STAGE
• Pass electron beam through varying amounts of ~ air equivalent showering material (Al2O3).
• Measure light yield as a function of depth in the shower ( sample light from a wide range of electron energies).– Is fluorescence proportional to dE/dx?– What are the contributions of low-energy (<1
MeV) electrons?– Can existing shower models (EGS, GEANT,
CORSIKA) correctly predict fluorescence light?– How does the fluorescence yield in an air shower
track the shower development?
Comparison - Cosmic/SLAC
• Cosmic Ray
• Dump 1017 to 1020 eV perparticle into atmosphere
• 600-800 gm/cm2 intoshower (Xmax) particlesare electrons withenergies between100keV and few GeV
• SLAC beam
• Dump 3x1018 to 3x1019
eV per beam bunch intoAlumina target
• 200 gm/cm2 (Xmax),particles are electronswith energies between100 keV and…. GeV
Comparison, cont.
• Fluorescence generatedby electron interactionswith N2 molecules, O2acts as quenching agent,Y is ~ independent ofPressure.
• Signal S(X) prop toY*N(X). Infer N(X) frommeasurement
• Fluorescence generatedby electrons exitingAlumina into air atcontrolled Pressure.
• S(X) prop to Y(X)*N(X).N(X) calculated from EGSetc., S(X) measured, Y(X)can then be established
THICK TARGET SETUP
CORSIKA AIR SHOWERS
BREMSSTRAHLUNG BEAM OPTION
THICK TARGET SHOWER DEVELOPMENT
Thick Target Requirements
• Electron shower implies~100x multiplier
• Can run beam intensity 107 to 108 (radiation OK) withsame signal strength (or brem option ).
• Showering beam spreads out in air (~50cm ) - Carefulcalculation/measurement of optical acceptancenecessary.
• Measurement with optical masks to check relative tuberesponse to radial displacement of source during run.
• LED mapping of optical response off-line.
SYSTEMATIC UNCERTAINTIES
• Beam charge should be measurable by the beam toroids to better than 2%.
• The uncertainties in showering 3%.
• Detector systematic uncertainties of 5.4%.
• Detector Optics 4% (thin) 6.5 % (thick).
• Total systematic uncertainty of 7-9%.
SYSTEMATIC UNCERTAINTIES
Thin Target Thick Target
Beam 2% 2.2%
Showering - 3%
Detector System
5.4% 5.4%
Optical System
4% 6.5%
Total 7% 9.2%
CONCLUSION• FLASH aims to achieve an accuracy of 10% in the total
fluorescence yield and individual spectral lines.• Verify energy dependence of yield down to ~100keV.• Both thin target and thick target approaches will be
invoked.• Dependence of yield and spectrum on pressure and
atmospheric impurities will be measured.• Shower developments equivalent to ~1018 eV will be
measured at various depths and compared with codes.• We hope that FLASH will help to shed light on the
apparent differences between HiRes and AGASA, and provide reliable information for future fluorescence-based UHECR experiments.