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Gus Sinnis Asilomar Meeting 11/16/2003 The Next Generation All-Sky VHE Gamma-Ray Telescope.

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Presentation on theme: "Gus Sinnis Asilomar Meeting 11/16/2003 The Next Generation All-Sky VHE Gamma-Ray Telescope."— Presentation transcript:

1 Gus Sinnis Asilomar Meeting 11/16/2003 The Next Generation All-Sky VHE Gamma-Ray Telescope

2 Gus Sinnis Asilomar Meeting 11/16/2003 Physics Goals Gamma-Ray Burst Studies –Detect GRBs > 25 GeV –Detect GRBs to z~1 –Quantum Gravity Probe AGN Studies –Monitor all AGN in fov –Detect AGN to z > 0.3 –Sensitivity to ~15 minute flares Discovery –Time domain astronomy at VH energies –New sources unseen at other wavelengths

3 Gus Sinnis Asilomar Meeting 11/16/2003 Performance Requirements GRBs –Energy threshold near ~20 GeV Near known energy Able to see large distances (z~1) –All-sky/All-time Ability to see prompt emission AGN –Large area & low threshold Ability to detect distant AGN (z~0.3) Sensitivity to short transients Large field of view (~2 sr) ~100% duty cycle Crab sensitivity >5  /sqrt(day) - >100  /sqrt(year)

4 Gus Sinnis Asilomar Meeting 11/16/2003 Critical Parameters Effective Area Energy Threshold Angular Resolution Energy Resolution Background Rejection Air shower physics sets fundamental limitations!

5 Gus Sinnis Asilomar Meeting 11/16/2003 Approximation B Approximation B is not enough to understand detector design parameters Fluctuations are critical Resolutions unknown Background rejection Use CORSIKA

6 Gus Sinnis Asilomar Meeting 11/16/2003 CORSIKA: Altitude Effect 5200 m 4500 m 3500 m 2500 m E particle >300 keV 5200 = 2x4500 4500 = 3x3500 3500 = 3x2500

7 Gus Sinnis Asilomar Meeting 11/16/2003 CORSIKA: Altitude Effect (cont’d) 5200 m 4500 m 3500 m 2500 m E particle >10 MeV 5200 = 2x4500 4500 = 3x3500 3500 = 3x2500

8 Gus Sinnis Asilomar Meeting 11/16/2003 CORSIKA: Electron/Photon Ngammas Nelectrons Primary Energy (GeV)

9 Gus Sinnis Asilomar Meeting 11/16/2003 CORSIKA: Electron/Photon All particles E particle >10 MeV Photons 5-10x more plentiful.

10 Gus Sinnis Asilomar Meeting 11/16/2003 CORSIKA: “Event Trigger” Assume –Q.E. x Water efficiency = 0.15 –260 photons/cm generated in water –2 MeV/cm energy loss –3.5E-3 photo-detector coverage Obtain –15 MeV / PE –(Milagro proposal had 10 MeV/PE) Trigger –E particle >770 keV (Cherenkov Threshold) –Radius < 100 m –Detection Probability = E particle /15 –Require 50 “Hits”

11 Gus Sinnis Asilomar Meeting 11/16/2003 CORSIKA: Altitude Effect (cont’d) 5200 m 4500 m 3500 m 2500 m “Trigger” Probability 5200 = 2x4500 4500 = 3x3500 3500 = 3x2500 At low energy the effect is larger

12 Gus Sinnis Asilomar Meeting 11/16/2003 CORSIKA: Particle Distribution All particles E particle >10MeV

13 Gus Sinnis Asilomar Meeting 11/16/2003 Effect of Altitude: Conclusions Each km of atmosphere decreases the number of e-m particles by a factor of 3 A decrease in the # of e-m particles translates into a similar decrease in trigger efficiency The effective area for gamma rays increases by a factor of 3 for each km gain in elevation. Need to detect photons with high efficiency

14 Gus Sinnis Asilomar Meeting 11/16/2003 CORSIKA: Angular Resolution Use zenith showers for simplicity “Trigger” on event Use particle times and positions Determine curvature correction Determine “sampling” correction Optimize “chi” cuts and E min (min. particle energy to use) Fit event direction

15 Gus Sinnis Asilomar Meeting 11/16/2003 Particle Arrival Times For each event time is measured relative to the average particle arrival time. Curvature Correction

16 Gus Sinnis Asilomar Meeting 11/16/2003 Particle Arrival Times (cont’d) For each event time is measured relative to the average particle arrival time. “Sampling” Correction

17 Gus Sinnis Asilomar Meeting 11/16/2003 Direction Fitting: No Corrections

18 Gus Sinnis Asilomar Meeting 11/16/2003 Direction Fitting: After Optimization

19 Gus Sinnis Asilomar Meeting 11/16/2003 Angle Error vs. nParticles

20 Gus Sinnis Asilomar Meeting 11/16/2003 Angle Error vs. nFit

21 Gus Sinnis Asilomar Meeting 11/16/2003 Angle Error vs. Primary Energy

22 Gus Sinnis Asilomar Meeting 11/16/2003 Angle Fitting: Conclusions Curvature is not as simple as we thought Sampling is not as simple as we thought Fundamentally limited by # of particles reaching the ground and their time spread ~0.25 degree seems to be the limiting resolution at high particle numbers

23 Gus Sinnis Asilomar Meeting 11/16/2003 CORSIKA: Energy Resolution

24 Gus Sinnis Asilomar Meeting 11/16/2003 CORSIKA: Energy Resolution

25 Gus Sinnis Asilomar Meeting 11/16/2003 CORSIKA: Energy Resolution

26 Gus Sinnis Asilomar Meeting 11/16/2003 Energy Resolution: Conclusion Good energy resolution (~25%) is possible Counting particles is better than measuring total energy Energy resolution improves rapidly with energy

27 Gus Sinnis Asilomar Meeting 11/16/2003 Proton Background 5200 m 4500 m 3500 m 2500 m # Particles 5200 = 1.3x4500 4500 = 1.8x3500 3500 = 1.8x2500

28 Gus Sinnis Asilomar Meeting 11/16/2003 Proton Showers

29 Gus Sinnis Asilomar Meeting 11/16/2003 Muons in Proton Showers

30 Gus Sinnis Asilomar Meeting 11/16/2003 Hadrons in Proton Showers

31 Gus Sinnis Asilomar Meeting 11/16/2003 Background Rejection: Conclusions #particles vs. altitude grows slower than e-m showers At low energy few muons present Muon number ~independent of altitude Hadrons present at low energies Hadron number strong altitude dependence More work needed for morphology More work needed on e-m component

32 Gus Sinnis Asilomar Meeting 11/16/2003 Angular Resolution 0.75 o resolution Preliminary resolution function

33 Gus Sinnis Asilomar Meeting 11/16/2003 Milagro Strawman Triggered Fit in Bin Effective Area vs. Energy: Gamma Rays

34 Gus Sinnis Asilomar Meeting 11/16/2003 Energy Distribution of Fit Events Median Energy 350 GeV (Milagro ~2 TeV)

35 Gus Sinnis Asilomar Meeting 11/16/2003 Background Rejection Estimate total rate (due to background) by scaling proton response from Milagro –120 kHz trigger rate expected As in Milagro use bottom layer information to detect penetrating component of hadronic showers. Small clumps of intense light indicate presence of penetrating component

36 Gus Sinnis Asilomar Meeting 11/16/2003 Gammas Protons Pulse Heights in Bottom Layer 260 GeV 660 GeV 350 GeV 170 GeV 2.5 TeV2.2 TeV

37 Gus Sinnis Asilomar Meeting 11/16/2003 Background Rejection Use 4 parameters: nTop, nBot2, nBot8, sumPEBot MARS: J. Friedman Reject 95% of protons Accept 55% of gammas 2.5x improvement in sensitivity

38 Gus Sinnis Asilomar Meeting 11/16/2003 D.C. Sensitivity: Galactic Sources Crab Spectrum: dN/dE = 3.2x10 -7 E -2.49 –0.22 (0.12) Hz of gammas from Crab raw (cut) –Whipple 0.025 Hz –Veritas-4 0.5 (.12) Hz raw (cut) Background rate 80 (4) Hz raw (cut) 3  /sqrt(day) raw data 7.5  /sqrt(day) cut data –140  /sqrt(year) 35 mCrab sensitivity (all sky) in one year –Whipple: 140 mCrab per source –VERITAS: 15 mCrab per source (E 2 dN/dE>1.4x10 -12 ergs cm -2 s -1 @ 1 TeV – best sensitivity)

39 Gus Sinnis Asilomar Meeting 11/16/2003 Transient Sensitivity: Galactic Sources

40 Gus Sinnis Asilomar Meeting 11/16/2003 Effect of IR Absorption on Distant Sources z = 0.03 z = 0.1 z = 0.2 z = 0.3 z = 0.0

41 Gus Sinnis Asilomar Meeting 11/16/2003 Energy Distribution of Fit Events

42 Gus Sinnis Asilomar Meeting 11/16/2003 AGN Sensitivity 1 Year

43 Gus Sinnis Asilomar Meeting 11/16/2003 Gamma Ray Burst Sensitivity 50 events

44 Gus Sinnis Asilomar Meeting 11/16/2003 Conclusions A large area, high altitude all sky VHE detector can: –Instantaneous sensitivity comparable to Whipple –D.C. sensitivity approaching VERITAS –AGN sensitivity to z = 0.3 –GRB sensitivity to <50 GeV –GRB sensitivity to z~1 –Detect a significant number of GRBs Continuing work –Background rejection (low energy) –Improved event reconstruction –Detailed detector design (electronics, DAQ, infrastructure) –Reliable cost estimate needed (~$30M???) –Site survey

45 Gus Sinnis Asilomar Meeting 11/16/2003 Work Plan Monte Carlo of 5200m site More MC of 4500m site Paper submitted by March Proposal to NSF next September cycle Need work assignments for the paper and the proposal Interested parties? –Columbia (Stefan, Reshmi) –UNM (John Matthews) –Milagro people (???)

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