For all the planets and stars and black holes and mental inadequacies, the universe seems to be missing something, but maybe something is just hiding.
Everything weird out there should be in the universe. So what hasn’t been seen? New research suggests that gravitational waves may help to elucidate more of the supposedly dark energy that is glistening in the gap. It is possible that gravitational waves – ripples during space – could illuminate dark energy. These ripples traverse black holes or large galaxies as they traverse space.
Since gravitational waves (which are probably ubiquitous in galaxy IC 10, above) have been proven to be curved when passing through or near these objects, dark energy affect them too.
“Waves of gravity can be used to study the nature of dark energy,” said Jose Maria Ezquiaga, who co-authored a paper recently published in Corporate Review Letters, told SYFY WIRE. “If the dark energy is indeed a change in gravity, this will affect the way gravitational waves move. This is in some way similar to using light to study the nature of some material. In other words, gravity waves can be used as probes of parts of the globe.
Darkness is said to be behind the expansion of the universe, but the problem is that its origins are still unknown. There are scientists who don’t even think it exists. If it is dark energy that is causing the accelerated expansion of the globe, gravitational waves, coming out of black holes and hitting neutron stars, can tell us something as they walk through the darkness. If, as Ezquiaga points out, dark energy is a strange way to change gravity, it should affect the waves of gravity.
There is a lot of pressure in the galleries and the black holes that run in during space. That level of gravity bends the path of a pull wave. When large masses of mass move space around, as explained in Einstein’s general theory of friendship, they create a gravitational field that magnifies light behind them and makes them more visible. This is a gravitational lens. It is often exploited by telescopes like Hubble to study distant galleries that are beyond what our technology sees. However, light is not the only thing a gravity lens can bend.
“If gravity is changed, those changes are a great place to look,” Ezquiaga said. “If a wave of gravity passes over these media, it can create waves associated with the extra parts of the earth. In many theories, these are scattering waves, which are different from the gravitational waves in their polar properties. “
When gravitational waves approach something large enough to be capable of a lens, they have the right to emit or echo “removal”. This is where smart waves come in. Smart waves, which may or may not be in the world of physics depending on whoever you ask, are electromagnetic waves that are believed to run long distances. When gravity waves approach an object with deep intensity, it is the difference in distance between them and the generated scattering waves that determines whether the gravity waves respond or emit. signal with scratch.
If there is a sufficient difference in distance between the two types of waves, it will cause the gravitational wave to split in two halves, emitting an echo. This can also happen if scattering waves are generated in an area of space that is large enough. If there is not enough difference in speed and the delay is shorter than the time it takes for the gravity wave to pass by a large object, things will be scratched. We may tell for these echoes in gravity wave data to tell us what is happening, and whether it comes face to face with dark energy.
Ezquiaga believes that how we look for dark energy in the future depends on what evidence we find of gravity change.
“If some of these changes are detected, the features of the sign can block the potential gravity changes,” he said. “For example, information on the time delay between echo or polarization content of the sign will be very important. If no such change is found, we can dismiss some theories. These constraints will become stronger as more waves of gravity are detected. ”
Even though we cannot see ourselves or the most powerful telescopes, dark energy may never live in the dark.