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1st page of proposal with 2 pictures and institution list

Explore the unique scientific abilities of Milagro, a TeV observatory complementing VERITAS/GLAST. Learn about its budget, funding history, and completion plans for enhanced sensitivity and data analysis. Discover why improved TeV observatories are crucial for detecting weaker and distant sources in astrophysics.

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1st page of proposal with 2 pictures and institution list

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  1. 1st page of proposal with 2 pictures and institution list 1

  2. Milagro@SAGENAP OUTLINE I. Astrophysics from Milagro Brenda Dingus, University of Wisconsin--Madison II. The Milagro Detector Gus Sinnis, Los Alamos National Laboratory III. Results from Milagro Don Coyne, University of California Santa Cruz IV. Completion of Milagro with Outriggers Tony Shoup, University of California Irvine V. Budget & Funding History Jordan Goodman, University of Maryland BOTTOM LINE Large field of view TeV observatory has unique scientific abilities that complement VERITAS / GLAST. Milagro has been built to budget and is now taking data. Milagrito & preliminary Milagro data indicate the scientific goals are within reach. A significant improvement in the sensitivity can be accomplished by completing the planned construction. Need support for Milagro operations, data analysis, and last 10% of construction. 2

  3. TeV Astrophysics Typical Multiwavelength Spectrum from High Energy g-ray source • Lower Energy Bump is • Synchrotron Emission from Relativistic Electrons • Higher Energy Bump is ? • Electron Inverse Compton Scattering • AND/OR Proton Induced Cascades • Peak of Both Bumps is sensitive to Eparticle, B, nphoton, ngas • Peak of Both Bumps exhibits greatest VARIABILITY

  4. Astrophysical Sources • TeV All Sky Map

  5. Why so Few Observed TeV Sources? • Perhaps Fewer TeV Accelerators, but • X-ray emission from supernova remnants and active galactic nuclei => TeV electrons • Sources of ultrahigh energy cosmic rays likely to emit TeV g-rays • TeV g-rays are Attenuated • g (TeV) + g (eV) --> e - + e + • Attenuation can be internal to the source or in transit • Transit attenuation depends on model of Galaxy Formation • Observation of ~200 GeV g-rays implies z<0.3 • Better TeV Observatories are Required • Improved Flux Sensitivity to Detect Weaker Sources • VERITAS, HESS, MAGIC, CANGAROO • Lower Energy Threshold to Detect Distant Sources • STACEE, CELESTE, Solar 2 • Large Field of View, High Duty Factor to Identify New and Flaring Sources • MILAGRO, Tibet EAg, ARGO Primack et al, 1999

  6. TeV Observatories • GeV Observatories • EGRET 0.6 sr 30% live time • GLAST 2.4 sr 90% live time • TeV Observatories • Atmospheric 0.003 sr 5-10% live time • Cherenkov=> ~ dozen sources / year • Telescopes with plotted sensitivity • Milagro 2 sr > 90% live time

  7. Variability of Active Galactic Nuclei (AGN) • GeV Observations • 66-93 AGN detected • (Hartman et al, 1999) • >70% are variable • (Mukherjee et al, 1999) • Some variability • is correlated with • other wavelengths, • but some is NOT • TeV Observations • Mrk 421 & Mrk 501 Detected by Many Observers Both Variable • Mrk 421 Rapid Flares • Mrk 501 Long High State • Other AGN Only detected once Only detected by 1 Observer 1ES2344+514 PKS2155-304 1ES1959+650 3C66A > 100 MeV X-ray Whipple Mrk501 light curve Quinn et al 1999

  8. Gamma Ray Bursts (GRBs) • Rapid Variability, Unknown Direction, ~ 1 / day / 4p sr • => Large Field of View, High Duty Factor ESSENTIAL Slew time for Pointed TeV Observatories

  9. Are GRBs near enough? • Distance has been measured to the host galaxies or optical afterglows of ~ dozen GRBs • % of GRBs near enough for TeV observations is uncertain • Distance distributions inferred from the BATSE-measured fluence distribution varies from <0.1% (Schmidt,1999) to ~10% (Dermer, 2000) of GRBs being within z < 0.3. • Different distance distributions are expected from hypernovae (death of massive stars) than from neutron star - neutron star coalescences • More than one population of GRB sources may exist with different distance distributions

  10. TeV g -rays from GRBs • GeV Observations => Relativistically expanding fireball with Bulk Lorentz Factors of 100-1000 • Average EGRET spectrum from brightest bursts => E-1.95±0.25 differential power law extending to 10 GeV • Evidence of TeV emission from GRB970417a from Milagrito (Atkins et al. 2000 ApJ Lett in press) GRB Spectral evolution from model of Dermer, 1999

  11. Non-Transient Sources • Extended Sources • Atmospheric Cherenkov Telescopes are less effective at rejecting cosmic-ray background for non-point sources • Long integration time of Milagro can improve sensitivity • Supernova Remnants • Sizes can extend to a few degrees • Highest energy observations identify proton produced g-rays • Galactic Plane • GeV flux measurements are higher than model prediction • Excess can be explained by Inverse Compton emission which may be observable in TeV g-rays • Milagro observes 106 cosmic-rays/day within 1o of plane and Air Cherenkov Telescope u.l. are ~10-3 of the cosmic ray flux Poh l & Esposito, 1998 p+p IC Brem.

  12. The Unknown • 60% of EGRET sources are unidentified • Many are Galactic • Some have hard spectra • Some are variable (one exceeded the Crab flux once) • TeV detections would measure more precise position • New TeV sources may exist • Milagrito performed 1st all sky TeV survey No point sources with continuous flux > 5 x Crab flux exist in Northern Hemisphere (A. Smith et al. 1999) • Possible new sources include • Evaporation of Primordial Black Holes • Galactic Black Holes with Relativistic Jets • X-ray Binaries • TeV- selected Active Galactic Nuclei • ??????

  13. Astrophysics from Milagro • TeV g-ray observations add to our understanding of Nature’s Highest Energy Particle Accelerators • GeV-TeV g-ray astrophysics is an active and growing field with new observations and observatories • Milagro is an All-Sky TeV monitor of the northern hemisphere with unique, but complementary, capabilities to the many current and planned TeV pointed observatories

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