Webgravitons, when the massive graviton is generated, the massless graviton is also generated. Massless gravitons would then be observed as a gravitational wave back-ground. Therefore, if the massive graviton in bigravity is dark matter, the gravitational wave background can carry information about dark matter. As an example, we assume WebNov 4, 2024 · Dark matter could consist of particles called gravitons that appeared right after the Big Bang - possibly from other dimensions, according to a new study published in the journal Physical Review Letters.Having teamed up with colleagues from the Korea University - Haiying Cai and Seung J. Lee - Cacciapaglia found that the number of …
Can dark matter be made up of gravitons? - Quora
The term graviton was originally coined in 1934 by Soviet physicists Dmitrii Blokhintsev [ru; de] and F.M. Gal'perin. A mediation of the gravitational interaction by particles was anticipated by Pierre-Simon Laplace. Just like Newton's anticipation of photons, Laplace's anticipated "gravitons" had a greater speed than c, the speed of gravitons expected in modern theories, and were not connected to quantum mechanics or special relativity, since these theories didn't yet exist during … WebDec 14, 2015 · This effect, known as gravitational lensing, depends on how much matter, both normal and dark, is in a galaxy – we can use it to calculate the amount of matter lurking around. However, we now know it is unlikely that enough of these dark bodies could accumulate to make up the vast amount of dark matter that exists. 4. The Kaluza-Klein … earl hanson elementary
Massive Gravitons as Feebly Interacting Dark Matter Candidates
Weblength for every particle, or in other words the gravitational energy of the particle distributed in their Compton length is just the particle energy or the “mass”. Keywords: Origin of gravity, gravitons, gravitational charge, Dark Matter, virtual black holes, free photons, color magnetic charges, gluons, photons mass, electrons 1. Introduction WebDark matter does cluster, collapsing gravitationally into clumps, but those clumps are much larger and more diffuse than the clumps of ordinary matter we're so familiar with. Why not? The answer seems to be that dark matter has few ways to dissipate energy. earl hartlen photography