Can scientists use lasers to interfere with gravitational waves, but can they find high dimensional

I don't know, at present, scientists are only doing experiments, and it is not possible to find it with certainty, and even if there is a high-latitude space, it is difficult to find it.

The probability of finding a high-dimensional space is still very small, because the study of gravitational waves is still in a very early stage, and it will be at least a few decades before progress can be made.

It should be possible, but it requires a high level of science and technology, and it will take some time.

My view on this subject is that general relativity is actually a theory that has not yet been quantified, and that gravitational waves are also considered independent of attempts to find the same gravitational subversion. Thus, the existence of gravitational waves can be explained in the absence of quantum gravity, however, it is generally believed that quantum gravity causes the appearance of gravitons in quantum gravitational waves, and gravitons are actually particles related to gravitational waves, just as photon particles related to electromagnetic waves are small waves.

Its energy is proportional to the frequency of the wave, and, in the context of general relativity, the nature of the wave itself provides us with all sorts of useful information about the quantum version of the gravitational particle, it must have no mass, the spin must be 2, so it will naturally travel at the speed of light relative to a photon with 1 spin, 1 2 electrons and 0 Higgs bosons, gravitational waves are actually composed of a large number of gravitons.

But measuring individual composition is extremely difficult, far beyond our experimental capabilities, laser interferometer gravitational-wave observatory cannot distinguish between individual gravitons, for the same reason that a television antenna cannot distinguish between individual photons, if there is a signal, this detector may be overwhelmed by particles, it is not sensitive to tiny dispersed energy levels, if gravitons are present, the laser will interfere with gravitational-wave observatory to detect it, but it cannot distinguish a large number of gravitons in gravitational waves that have never been quantified.

Therefore, the Laser Interferometer Gravitational-Wave Observatory cannot tell us anything about the existence of gravitons, and as for whether we can learn something about quantum gravity, I can't say for sure because we don't have a theory of quantum gravity yet, so the answer to this question depends on whether you believe in it, or how much you know about quantum gravity, because almost everyone agrees that quantum gravitational effects should become larger in regions with strong curvature of space-time.

Regarding the question of what is quantum gravity, can laser interferometer gravitational-wave observatories detect it, it will be explained here today.

I think that this study can know the degree of the universe and understand the mysteries of the entire universe, which has an immeasurable effect on the development of the entire physics.

The existence of gravitational waves has given people a new understanding in the space dimension that we can use gravitational waves to study the causes of large-scale stars in supernovae.

The existence of gravitational waves can prove that space is only three-dimensional, for example, there are other dimensions in space, and the energy of gravitational waves will leak into other dimensions. Therefore, the amplitude of the gravitational wave perceived at the scientific observatory is much smaller than **. The truth is that scientists analyzed the gravitational waves generated by neutron star collisions and did not find any anomalies in the amplitude.

In other words, when you believe that gravitational waves are real, then space is only three-dimensional.