The value of the Hubble rate at the start of reheating that gives the correct relic abundance, as a function of the mass of the PIDM. The blue curve is for γ=1 , the orange curve is for γ=0.1 , and the green curve is for γ=0.01 . The red region is excluded from the current bound on the tensor-to-scalar ratio, and the purple dashed line is the projected sensitivity for next generation CMB experiments, from Ref. [24]. The dotted lines show the modification when taking also gravitational production into account [12, 13, 14]. The dashed-dotted line marks mX=Hi , and for a scalar PIDM the left-hand side of this line is excluded unless corrections to the PIDM potential are important during inflation. All values are given in units of Mp .
“Maybe it’s because we have looked after dark particles in a way that will never be able to reveal them,” says A/Prof Martin Sloth. For decades, physicists have been working on the theory that dark matter is light and therefore interacts weakly with ordinary matter. This means that the particles are capable of being produced in colliders. This theory’s dark particles are called weakly-interacting massive particles (WIMPs), and they are theorized to have been created in an inconceivably large number shortly after the birth of the universe 13.7 billion years ago.
“But since no experiments have ever seen even a trace of a WIMP, it could be that we should look for a heavier dark particle that interacts only by gravity and thus would be impossible to detect directly,” says Martin Sloth. Sloth and his colleagues call their version of such a heavy particle a PIDM particle (Planckian Interacting Dark Matter). In their new model, they calculated how the required number of PIDM particles could have been created in the early universe.
“It was possible, if it was extremely hot. To be more precise the temperatures in the early universe must have been the highest possible in the Big Bang theory,” says Sloth. Whether this was the case or not can be tested. He explains further: “If the universe indeed was as hot as calculated in our model, several gravitational waves from the very early childhood of the universe would have been created. We might be able to find out in the near future.” With this Sloth refers to a number of planned experiments around the world that will be able to detect signals from very early gravitational waves. “If these experiments do not detect such signals, then our model will be falsified. Thus gravitational waves can be used to test our model,” he says.
More than 10 different experiments are planned. They aim to measure the polarization of the cosmic background radiation, either from the ground or with instruments sent up in a balloon or satellite to avoid atmospheric disturbances. http://www.sdu.dk/en/om_sdu/fakulteterne/naturvidenskab/aktuelt/2016_03_14_heavy_dark_matter
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