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Explore the historical journey of cosmic ray research from 1938 to 2007, including significant breakthroughs and key researchers. Dive into the evolution of detection techniques, operational periods of various instruments, and the latest advancements in understanding cosmic ray energies and compositions. Discover how scientists are bridging the gap between observations and cosmic accelerators, steering towards a deeper understanding of cosmic phenomena.
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Solving the Mystery of the Highest Energy Cosmic Rays : 1938 to 2007 cosmic rays: James W. Cronin Inaugural Conference: Institute for Gravitation and the Cosmos Aug 9, 2007 Penn State University
On the way to Solving the Mystery of the Highest Energy Cosmic Rays : 1938 to 2007 cosmic rays: James W. Cronin Inaugural Conference: Institute for Gravitation and the Cosmos Aug 9, 2007 Penn State University
Decoherence curve at the Jungfraujoch Auger and collaborators
Following World War II cosmic ray research resumed with arrays of Geiger counters
Volcano Ranch J. Linsley 1963 1st cosmic ray ~ 1020 eV
Two techniques: • detect shower particles on the ground • detect air fluorescence produced by shower particles
Cassiday, Bergeson, Loh, Sokolsky et al. Utah Fly’s Eye 1981-1993
Instruments for the study of the highest energy cosmic rays operation area exposure period km2 1016 (m2 sec sr) Volcano Ranch 1960-1980 80.2 (?) Haverah Park 1967-1987 12 2.6 SUGAR ~1968-1980 60 ~2.6 Yakutsk 1974-1995 18 1.4 Fly’s Eye 1981-1992 2.6 (mono) HiRes ~1998-2006 ~10 (mono) AGASA 1992-2004 100 ~6.0 Auger 2004- 3000 16 (~0.8 yr opr.)
1020 eV proton 16 joules energy Kinetic energy of Andy Roddick’s second serve But momentum of a snail Macroscopic energy in a microscopic particle No known astrophysical sources “seem” able to produce such enormous energies 1/ km2/ century 3000 km2 -> 30 events / year Simon Swordy University of Chicago
Portugal Netherlands
1438 deployed 1400 filled 1364 taking data 090707 ~ 85% All 4 fluorescence buildings complete, each with 6 telescopes 1st 4-fold on 20 May 2007 AIM: 1600 tanks HYBRID DETECTOR
Surface Detector GPS timing precision Cosmic Muon Calibration 7
The Fluorescence Detector 3.4 metre diameter segmented mirror 2.2m diameter aperture stop, corrector lens and optical filter. 440 pixel camera. 24 telescopes in 4 eyes
HYBRID → PRECISE SHOWER GEOMETRYfirst step towards precise energy, depth of maximum Arrival time at ground provided by the SD, removes degeneracy in the FD geometry fit Can be ~ straight line,but 3 parameters in fit
HYBRID → PRECISE SHOWER GEOMETRYfirst step towards precise energy, depth of maximum Arrival time at ground provided by the SD, removes degeneracy in the FD geometry fit (= 90o- Ψ) Get T0 from SD tank!Geometry uncertainties shrink!
A “perfect” hybrid event: few are as beautiful as this one ! Miguel Mostafa New Mexico/Utah
S1000 is Energy parameter 8
S38 (1000)vs. E(FD) 4 x 1019 eV Nagano et al, FY used 387 hybrid events
Three spectra combined weighting statistical error in each energy bin. Low energy from Hybrid observation, High energy from SD. ‘ankle’ and ‘steepening’ seen in (nearly) model and mass-independent measurement . Auger Spectrum 2007 JS E-2.6
6 sigma deficit from power-law assumption
How we try to infer the variation of mass with energy photons Xmax protons Data Fe Energy
Elongation Rate measured over two decades of energy Fluctuations in Xmax to be exploited
326 111 69 25 12 426 Large number of events allows good control and understanding of systematics
Conclusions We are at the point where we have some confidence that the angles and energies of the highest energy cosmic rays can be measured accurately. Good progress is being made for statistical determination of the composition. It remains to make a connection with the cosmic accelerators. This requires patience and the benevolence of Nature.