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  • About two or three times a century, a massive in our galaxy explodes. The star's core may

  • survive as a neutron star or a black hole, but the rest of it rushes into space as swiftly

  • expanding debris behind a powerful shockwave. As the supernova remnant grows, it sweeps

  • up interstellar gas and gradually decelerates. Yet even thousands of years later, its imprint

  • on the galaxy remains impressive.

  • Exploding stars and their remnants have long been suspected of producing cosmic rays, some

  • of the fastest matter in the universe. Where and how these protons, electrons and atomic

  • nuclei are boosted to such high speeds has been an enduring mystery. Now, observations

  • of two supernova remnants by NASA's Fermi Gamma-ray Space Telescope provide new insights.

  • Because cosmic rays carry electric charge, their direction changes as they travel through

  • magnetic fields.

  • By the time the particles reach us, their paths are completely scrambled. We can't trace

  • them back to their sources. So scientists must locate their origins by indirect means,

  • which is where Fermi comes in. The interaction of high-energy particles with light and ordinary

  • matter can produce gamma rays, the most powerful form of light. Unlike cosmic rays, gamma rays

  • travel to us straight from their sources. In 1949, physicist Enrico Fermi worked out

  • what he called "magnetized clouds" could accelerate cosmic rays. Later studies showed that a variant

  • of his method, called Fermi acceleration worked especially well in supernova remnants.

  • Confined by a magnetic field, high-energy particles move around randomly. Sometimes

  • they cross the shock wave. With each round trip, they gain about 1 percent of their original

  • energy. After dozens to hundreds of crossings, the particle is moving near the speed of light

  • and is finally able to escape. If the supernova remnant resides near a dense molecular cloud,

  • some of those escaping cosmic rays may strike the gas, and produce gamma rays.

  • But electrons and protons make gamma rays in different ways. Cosmic ray electrons do

  • so when they're deflected by passing near the nucleus of an atom. Accelerated protons

  • may collide with an ordinary proton and produce a short-lived particle called a neutral pion.

  • These pions quickly decay into a pair of gamma rays. At their brightest, both types of emission

  • look very similar. Only with sensitive measurements at lower gamma-ray energies can scientists

  • determine which process is responsible.

  • Now, Fermi observations have done just that. They conclusively show these supernova remnants

  • are accelerating protons. When they strike protons in nearby molecular clouds, they produce

  • pions... and ultimately the gamma-ray emission Fermi sees. NASA's Fermi has detected gamma

  • rays from many more supernova remnants, but the jury is still out on whether accelerated

  • protons are always responsible and what their maximum energies may be. Nevertheless, the

  • Fermi team has taken a major step--a century after the discovery of cosmic rays-- in establishing

  • just where they arise. Something that would satisfy, but certainly not surprise, the original

  • Fermi.

About two or three times a century, a massive in our galaxy explodes. The star's core may

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NASA望遠鏡發現宇宙射線的起源 (NASA Telescope Discovers the Origin of Cosmic Rays)

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    Jack 發佈於 2021 年 01 月 14 日
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