Presentation is loading. Please wait.

Presentation is loading. Please wait.

05/02/031 Next Generation Ground- based  -ray Telescopes Frank Krennrich April, 30 2001.

Published byByron Pope Modified over 8 years ago

Similar presentations

Presentation on theme: "05/02/031 Next Generation Ground- based  -ray Telescopes Frank Krennrich April, 30 2001."— Presentation transcript:

1 05/02/031 Next Generation Ground- based  -ray Telescopes Frank Krennrich April, 30 2001

2 05/02/031 Outline - Scientific objectives - Technique - Design considerations - Solar arrays - Large single imaging telescope - Arrays of imaging telescopes - Summary

3 05/02/031 Early 1990s 10 -1 10 0 10 1 10 2 10 3 10 4 10 5 [GeV] 10 -2 10 -3 EGRET Whipple Compton, Pair conversion (Satellite) Atmospheric Cherenkov (Ground)

4 05/02/031 Early 1995 10 -1 10 0 10 1 10 2 10 3 10 4 10 5 [GeV] 10 -2 10 -3 EGRET Whipple, CAT, HEGRA Pair conversion (Satellite) Atmospheric Cherenkov (Ground)

5 05/02/031 2005 10 -1 10 0 10 1 10 2 10 3 10 4 10 5 [GeV] 10 -2 10 -3 GLAST STACEE, CELESTE MAGIC VERITAS, HESS, CANGAROO III Chandra Integral

6 05/02/031 Design Goals of New Atmospheric Cherenkov Telescopes - Large effective area ~ 0.1 km 2 (10 5 GLAST) - Low energy threshold ~ 10 GeV – 50 GeV - Better flux sensitivity ~ 5 mCrab (50 hours) - Energy resolution  E/E ~ 10% - 15% - Angular resolution  ~ 0.02 o – 0.1 o - Wide energy range ~ 10 GeV – 100 TeV - Large Field of View ~ 3 o – 10 o (1/80 GLAST)

7 05/02/031 Scientific Objectives Active Galactic Nuclei Supernova Remnants Infrared Background (Diffuse) Galactic Plane Gamma Ray Bursts Neutralino Annihilation, Primordial Black Holes, Quantum Gravity, … Pulsars   e + + e -

8 05/02/031 Existing telescopes Whipple * Arizona, USA 10 m 489 250 1984 Crimea Crimea, Ukraine 6 x 2.4 m 6 x 37 1000 1985 SHALON Tien Shen, Russia 4 m 244 1000 1994 CANGAROO Woomera, Aust. 3.8 m 256 500 1994 HEGRA * La Palma, Sp. 5 x 3 m 5 x 271 500 1994 CAT * Pyrenees, Fr. 4 m 600 250 1996 Durham/Mk6 Narrabri/Aust. 3 x 7 m 1 x 109 250 1996 TACTIC Mt. Abu, India 4 x 3.5 m 1 x 225 300 1997 Seven TA Utah, USA 7 x 2 m 2 x 256 500 1998 * Significance (1Crab) > 5  x  t/hours  1/2 Solar-2 Barstow, USA 32x 7m 32 x 1 ?? 2000 GRAAL Almeria, Spain 63 x 7m 4 200 1999 Group/ Location Reflectors Camera Threshold Epoch Instrument Number x Aperture Pixels (GeV) Beginning STACEE Sandia, New Mexico 32(64) x 7m 32(64) x 1 180(50) 1998 CELESTE Pyrenees, Fr. 40 x 7m 40 x 1 50 2000

9 05/02/031 Future telescopes VERITAS MAGIC STACEE CELESTE CangarooIII HESS GRAAL

10 05/02/031 Imaging Atmospheric Cherenkov Telescopes Imaging Camera Area ~ 100,000 m 2 (10 5 x GLAST) E ~ 0.2 – 100 TeV  ~ 0.2 o 0.01 – 100 TeV

11 05/02/031  -ray images: - narrow, short, smooth Hadronic images: - broad, long - local muons, patchy hadron rejection: 99.7% (10 -3 )  -ray proton Cosmic Ray Rejection Technique Crab Nebula 7  in 1hour

12 05/02/031 Design: Energy Threshold - Night Sky Background : NSB = 2 – 4 x 10 12 photons/sr/m 2 /s  ~ 1.3 photons/m 2 (5ns, 0.5 o aperture) - Signal from  -ray shower: S ~ 0.1 [E /GeV] photons/m 2  ~ 5 photons/m 2 (50 GeV)  Signal/Noise ~ S/NSB 1/2  E ~ A -1/2  mirrorthreshold

13 05/02/031 Design: Energy Threshold E ~ (NSB  A) 1/2 threshold dark site solid angle  pixel size electronics & optics QE efficiency

14 05/02/031 General Strategies - increase mirror area: 250 GeV  50 GeV 10m - reduce optical losses:  f/number, light concentrators, mirrors  photodetectors QE (future): 25%  50% … 80% - reduce NSB:  improve telescope resolution  reduce pixel size in IACTs: 0.25 o  0.10 o  fast electronics: 20 ns  5 - 10 ns 50m

15 05/02/031 General Strategies - increase mirror area: 250 GeV  50 GeV 10m - reduce optical losses:  f/number, light concentrators, mirrors  photodetectors QE (future): 25%  50% … 80% - reduce NSB:  improve telescope resolution  reduce pixel size in IACTs: 0.25 o  0.10 o  fast electronics: 20 ns  5 - 10 ns 50m

16 05/02/031 Solar Arrays heliostats reflect light onto secondary optics (tower) wavefront sampling (light density profile) rejection of hadrons in trigger mirror area ~ 1200 - 2000 m 2 energy threshold ~ 50 GeV Significance (1Crab) ~ 1.0 – 1.6  x  t/hours  1/2

17 05/02/031 Solar Arrays Base Ecole Polytechnique MPI, Munich UC, Riverside UCLA Location Pyrenees, Fr. Almeria, Spain Barstow, CA Sandia, NM # of heliostats 40 (54) 63 32 32(48) Mirror area 2160 m 2 2520 m 2 1200 m 2 1200 (1800) m 2 Pixels 40 4 32 32(48) Energy threshold 50 GeV 100 GeV ? 190 GeV (50 GeV) Parameter CELESTE GRAAL Solar-1 STACEE

18 05/02/031 Single Large Imaging Telescope - parabolic reflector ~ 236 m 2 - focal length ~ 17 m - carbon fiber space frame - diamond-milled aluminum mirrors - swift slew speed 3 o /s - 800 pixels: ~ 0.1 o - fast electronics  5 ns trigger, FADCs - future (high QE detectors 45%) - E ~ 30 GeV MAGIC threshold - First light 2002

19 05/02/031 Arrays of Imaging Telescopes I - 50 GeV – 50 TeV -  ~ 0.03 o @1TeV ~ 0.09 o @100GeV - Flux sensitivity: 15 mCrab @100GeV 5 mCrab @300GeV 80 m VERITAS

20 05/02/031 Arrays of Imaging Telescopes I - 50 GeV – 50 TeV -  ~ 0.03 o @1TeV ~ 0.09 o @100GeV - Flux sensitivity: 15 mCrab @100GeV 5 mCrab @300GeV 80 m VERITAS

21 05/02/031 Arrays of Imaging Telescopes II Stereoscopic detection: - reduction of energy threshold - improved angular resolution  - rejection of local muons  - shower core reconstruction  - analysis of faint images

22 05/02/031 Arrays of Imaging Telescopes III - Science topics with NGGGRT

23 05/02/031 HESS - 4 x Davis-Cotton ~ 120 m 2 - focal length ~ 15 m - steel space frame - ground-glas mirrors - 960 pixels: ~ 0.16 o - distance 120 m First light 2002

24 05/02/031 CANGAROO III - 4 x parabola ~ 80 m 2 - focal length ~ 8 m - composite mirrors - 552 pixels - distance 100 m First light 2004

25 05/02/031 VERITAS - 7x Davis-Cotton ~ 100 m 2 - focal length ~ 12 m - steel structure - ground-glas mirrors - 499 pixels: ~ 0.15 o - distance 80 m - 300 MHz FADC - Sub-arrays - mirror covers First light 2003/2005?

26 05/02/031 VERITAS

27 05/02/031 Overview of Future Telescopes Parameter MAGIC HESS CANGAROO-III VERITAS Base MPI, Munich MPI, Heidelberg Tokyo, Japan SAO, Arizona Location La Palma Namibia Woomera, Australia Arizona # of telescopes 1 4(16) 4 7 Mirror area/tel. 236 m 2 120 m 2 80 m 2 100 m 2 Elevation 2.3 km 1.8 km S.L. 1.3 km Energy threshold 30 GeV 40 GeV 100 GeV 50 GeV # of pixels 800 960 x 4 552 x 4 499 x 7 Sub-arrays First light 2002 2002 2004 2003/2005?

28 05/02/031 Point Source Sensitivity

29 05/02/031 Sensitivity of Telescope Arrays

30 05/02/031 CELESTE: Crab at 50 GeV de Naurois et al., Proceed. of Gamma Ray Astrophysics workshop, in press (Heidelberg)

31 05/02/031 Sensitivity to flares 5 mCrab (50 h) 20 x Whipple  second time scale for flares  Good match with X-ray satellites hypothetical lightcurve

32 05/02/031 Status of Projects? Very Energetic Radiation Imaging Telescope Array System (VERITAS) Astronomy & Astrophysics in the New Millenium NRC 10-year Report

Download ppt "05/02/031 Next Generation Ground- based  -ray Telescopes Frank Krennrich April, 30 2001."

Similar presentations

The MAGIC telescope and the GLAST satellite La Palma, Roque de los Muchacos (28.8° latitude - 17.8° longitude, 2225 m asl) INAUGURATION: 10/10/2003 LAT.

The MAGIC telescope and the GLAST satellite La Palma, Roque de los Muchacos (28.8° latitude ° longitude, 2225 m asl) INAUGURATION: 10/10/2003 LAT.
INDIRECT DARK MATTER SEARCHES WITH HESS J-F Glicenstein IRFU/CEA-Saclay on behalf of the HESS collaboration.

INDIRECT DARK MATTER SEARCHES WITH HESS J-F Glicenstein IRFU/CEA-Saclay on behalf of the HESS collaboration.
COSMIC RAY ORIGINS Stella Bradbury, University of Leeds, U.K.  -ray sources the cosmic ray connection detection technique galactic and extragalactic.

COSMIC RAY ORIGINS Stella Bradbury, University of Leeds, U.K.  -ray sources the cosmic ray connection detection technique galactic and extragalactic.
OBSERVATIONS OF AGNs USING PACT (Pachmarhi Array of Cherenkov Telescopes) Debanjan Bose (On behalf of PACT collaboration) “The Multi-Messenger Approach.

OBSERVATIONS OF AGNs USING PACT (Pachmarhi Array of Cherenkov Telescopes) Debanjan Bose (On behalf of PACT collaboration) “The Multi-Messenger Approach.
High-energy particle acceleration in the shell of a supernova remnant F.A. Aharonian et al (the HESS Collaboration) Nature 432, 75 (2004) Nuclear Physics.

High-energy particle acceleration in the shell of a supernova remnant F.A. Aharonian et al (the HESS Collaboration) Nature 432, 75 (2004) Nuclear Physics.
Cut off more slowly ~ 50GeV Thompson astro-ph/0101039Credit: A.K. Harding (NASA/GSFC) Our first target: Crab pulsar/nebula The standard candle for gamma-ray.

Cut off more slowly ~ 50GeV Thompson astro-ph/ Credit: A.K. Harding (NASA/GSFC) Our first target: Crab pulsar/nebula The standard candle for gamma-ray.
Observations of the AGN 1ES1959+650 with the MAGIC telescope The MAGIC Telescope 1ES1959+650 Results from the observations Conclusion The MAGIC Telescope.

Observations of the AGN 1ES with the MAGIC telescope The MAGIC Telescope 1ES Results from the observations Conclusion The MAGIC Telescope.
Mathieu de Naurois, H.E.S.S.High Energy Phenomena in the Galacic Center. 2005 1 H.E.S.S. Observations of the Galactic Center  The H.E.S.S. Instrument.

Mathieu de Naurois, H.E.S.S.High Energy Phenomena in the Galacic Center H.E.S.S. Observations of the Galactic Center  The H.E.S.S. Instrument.
WP-Technology Working Group Future of Ground Based Gamma-ray Astronomy Feb 8, 2007 1 Technology & Cost WP Working Group GOALS With the Current Generation.

WP-Technology Working Group Future of Ground Based Gamma-ray Astronomy Feb 8, Technology & Cost WP Working Group GOALS With the Current Generation.
Gamma-Ray Astronomy Call no. 07483 Assoc. Prof. Markus Böttcher Clippinger # 339 Phone: 593-1714

Gamma-Ray Astronomy Call no Assoc. Prof. Markus Böttcher Clippinger # 339 Phone:
 Jim Hinton 2006 High Energy Stereoscopic System (H.E.S.S.)  Array of four 107 m 2 telescopes in Namibia, 120 m spacing  5° FOV  Threshold 100 GeV.

 Jim Hinton 2006 High Energy Stereoscopic System (H.E.S.S.)  Array of four 107 m 2 telescopes in Namibia, 120 m spacing  5° FOV  Threshold 100 GeV.
Jamie Holder School of Physics and Astronomy, University of Leeds, U.K Increasing the Collection Area for IACTs at High Energies Future of Gamma Ray Astronomy.

Jamie Holder School of Physics and Astronomy, University of Leeds, U.K Increasing the Collection Area for IACTs at High Energies Future of Gamma Ray Astronomy.
The signature of the nearby universe on the very high energy diffuse gamma sky Århus, November 2006 Troels Haugbølle Institute for.

The signature of the nearby universe on the very high energy diffuse gamma sky Århus, November 2006 Troels Haugbølle Institute for.
The Transient Universe: AY 250 Spring 2007 New High Energy Telescopes Geoff Bower.

The Transient Universe: AY 250 Spring 2007 New High Energy Telescopes Geoff Bower.
Large Magellanic Cloud, 1987 (51.4 kparsec) SN 1987a after before 2006 Hubble.

Large Magellanic Cloud, 1987 (51.4 kparsec) SN 1987a after before 2006 Hubble.
The Spectrum of Markarian 421 Above 100 GeV with STACEE Jennifer Carson UCLA / Stanford Linear Accelerator Center February 2006 100 MeV 1 GeV 10 GeV 100.

The Spectrum of Markarian 421 Above 100 GeV with STACEE Jennifer Carson UCLA / Stanford Linear Accelerator Center February MeV 1 GeV 10 GeV 100.
The future of ground-based gamma ray astronomy Where do we go?

The future of ground-based gamma ray astronomy Where do we go?
Gamma-ray Astrophysics Pulsar GRB AGN SNR Radio Galaxy The very high energy  -ray sky NEPPSR 25 Aug. 2004 Guy Blaylock U. of Massachusetts Many thanks.

Gamma-ray Astrophysics Pulsar GRB AGN SNR Radio Galaxy The very high energy  -ray sky NEPPSR 25 Aug Guy Blaylock U. of Massachusetts Many thanks.
On A Large Array Of Midsized Telescopes Stephen Fegan Vladimir Vassiliev UCLA.

On A Large Array Of Midsized Telescopes Stephen Fegan Vladimir Vassiliev UCLA.
Search of High Energy Cosmic Sources with the Plataforma Solar de Almeria: The GRAAL Experiment Fernando Arqueros Universidad Complutense de Madrid F.

Search of High Energy Cosmic Sources with the Plataforma Solar de Almeria: The GRAAL Experiment Fernando Arqueros Universidad Complutense de Madrid F.

Similar presentations

Ads by Google