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posted by martyb on Tuesday July 14 2020, @03:04AM   Printer-friendly
from the light-reading-on-a-heavy-subject dept.

Simulation Shows Potential for Glowing Gravitons:

Where there is energy, there is gravity. And photons—massless packets of light energy—can, in exceedingly rare cases, spontaneously transform into gravity particles, according to Douglas Singleton, a physicist at California State University, who was not involved with the new study. The reverse happens, too, he says: gravitons can become photons. The new analysis considers a mechanism by which gravitons could unleash many billions of times more photons than earlier research suggested—making it easier to confirm their existence.

“A primitive estimate based on intensities [of gravitons] in the vicinity of black hole mergers came close” to numbers that would produce detectable light, says Raymond Sawyer, the study's author and a physicist at the University of California, Santa Barbara.

[...] Events such as black hole mergers should create the necessary conditions to send out photons in the form of radio waves with wavelengths many kilometers long. This signal would be extremely faint but perhaps possible to pick up from Earth. Events somewhat more violent than previously observed mergers could do it, Sawyer says. Scientists would have to tease the glow of the resulting radio waves from that of interfering gases.

First, though, theorists must check if the model holds up. Sawyer hopes future simulations will prove that photon bursts also occur in more realistic models of intense gravitational events, where many gravitons swirl in intricate patterns. Singleton agrees that the problem needs more computational firepower: current analyses are “gross simplifications,” he says. “The idea is to get people interested enough to do the heavy calculations.”

Journal Reference:
Raymond Sawyer. Seeing Gravitons in Colliding Gravitational Waves, Physics (DOI: 10.1103/PhysRevLett.124.101301)


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  • (Score: 0) by Anonymous Coward on Tuesday July 14 2020, @01:20PM (1 child)

    by Anonymous Coward on Tuesday July 14 2020, @01:20PM (#1021215)

    > Knowing from previous work that other massless particles can abruptly change state in large numbers (a phenomenon known as a quantum break

    But is ungoogleable because Quantum Break is also the name of a game

  • (Score: 3, Informative) by martyb on Tuesday July 14 2020, @02:12PM

    by martyb (76) Subscriber Badge on Tuesday July 14 2020, @02:12PM (#1021236) Journal

    > Knowing from previous work that other massless particles can abruptly change state in large numbers (a phenomenon known as a quantum break
    But is ungoogleable because Quantum Break is also the name of a game

    Check out the DOI link provided in the Journal Reference above: https://doi.org/10.1103/PhysRevLett.124.101301 [doi.org].

    It provides the full text of the journal article as well as all of its references.

    --
    Wit is intellect, dancing.