![]() In 1911, Domenico Pacini observed simultaneous variations of the rate of ionization over a lake, over the sea, and at a depth of 3 metres from the surface. However, his paper published in Physikalische Zeitschrift was not widely accepted. In 1909, Theodor Wulf developed an electrometer, a device to measure the rate of ion production inside a hermetically sealed container, and used it to show higher levels of radiation at the top of the Eiffel Tower than at its base. Measurements of increasing ionization rates at increasing heights above the ground during the decade from 1900 to 1910 could be explained as due to absorption of the ionizing radiation by the intervening air. History Īfter the discovery of radioactivity by Henri Becquerel in 1896, it was generally believed that atmospheric electricity, ionization of the air, was caused only by radiation from radioactive elements in the ground or the radioactive gases or isotopes of radon they produce. Most cosmic rays, however, do not have such extreme energies the energy distribution of cosmic rays peaks at 300 megaelectronvolts (4.8 ×10 −11 J). ![]() As a result of these discoveries, there has been interest in investigating cosmic rays of even greater energies. At 50 joules (3.1 ×10 11 GeV), the highest-energy ultra-high-energy cosmic rays (such as the OMG particle recorded in 1991) have energies comparable to the kinetic energy of a 90- kilometre-per-hour (56 mph) baseball. One can show that such enormous energies might be achieved by means of the centrifugal mechanism of acceleration in active galactic nuclei. Energy Ĭosmic rays attract great interest practically, due to the damage they inflict on microelectronics and life outside the protection of an atmosphere and magnetic field, and scientifically, because the energies of the most energetic ultra-high-energy cosmic rays have been observed to approach 3 × 10 20 eV (1.4 ×10 13 eV) ( CERN, 2021) ]. ![]() An active search from Earth orbit for anti-alpha particles has failed to detect them. The precise nature of this remaining fraction is an area of active research. A very small fraction are stable particles of antimatter, such as positrons or antiprotons. These fractions vary highly over the energy range of cosmic rays. Of the nuclei, about 90% are simple protons (i.e., hydrogen nuclei) 9% are alpha particles, identical to helium nuclei and 1% are the nuclei of heavier elements, called HZE ions. Of primary cosmic rays, which originate outside of Earth's atmosphere, about 99% are the bare nuclei of well-known atoms (stripped of their electron shells), and about 1% are solitary electrons (that is, one type of beta particle). In common scientific usage, high-energy particles with intrinsic mass are known as "cosmic" rays, while photons, which are quanta of electromagnetic radiation (and so have no intrinsic mass) are known by their common names, such as gamma rays or X-rays, depending on their photon energy. The term ray is somewhat of a misnomer, as cosmic rays were, originally, incorrectly believed to be mostly electromagnetic radiation. Based on observations of neutrinos and gamma rays from blazar TXS 0506+056 in 2018, active galactic nuclei also appear to produce cosmic rays. ĭata from the Fermi Space Telescope (2013) have been interpreted as evidence that a significant fraction of primary cosmic rays originate from the supernova explosions of stars. Particle detectors similar to those used in nuclear and high-energy physics are used on satellites and space probes for research into cosmic rays. ![]() ĭirect measurement of cosmic rays, especially at lower energies, has been possible since the launch of the first satellites in the late 1950s. Upon impact with Earth's atmosphere, cosmic rays produce showers of secondary particles, some of which reach the surface, although the bulk is deflected off into space by the magnetosphere or the heliosphere.Ĭosmic rays were discovered by Victor Hess in 1912 in balloon experiments, for which he was awarded the 1936 Nobel Prize in Physics. They originate from the Sun, from outside of the Solar System in our own galaxy, and from distant galaxies. Left image:Cosmic ray muon passing through a cloud chamber undergoes scattering by a small angle in the middle metal plate and leaves the chamber.Right image: Cosmic ray muon losing considerable energy after passing through the plate as indicated by the increased curvature of the track in a magnetic field.Ĭosmic rays are high-energy protons and atomic nuclei that move through space at nearly the speed of light. ![]()
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