قالب وردپرس درنا توس
Home https://server7.kproxy.com/servlet/redirect.srv/sruj/smyrwpoii/p2/ Science https://server7.kproxy.com/servlet/redirect.srv/sruj/smyrwpoii/p2/ Using black holes as acceleration of particles

Using black holes as acceleration of particles



<div _ngcontent-c1

4 = "" internalhtml = "

Impression of a new black hole artist NASA / CXC / M.Weiss [19659006] Following the discovery of the Higgs boson, the Great Hadron Collider, there was much discussion about where to go from here, and at the moment LHC is the most powerful particle acceleration encountered with particles of about 13 though it gave some whose physics hints beyond the standard model it will probably not solve some of the biggest particle physics issues, and we need a much more powerful particle accelerator, a proposal to create a "Circular Collector of the Future" that works almost ten times more than LHC, but its creation and operation would be very expensive, and some scientists ask if it would be worth the cost Anything if we could use a particle accelerator where a already exist in nature? What if we could use black holes? We already know that black holes are powerful engines that generate high energy particle flows that flow from the black hole at almost light speed. Unfortunately, any exotic high energy they produce will quickly disappear, so we wouldn't be able to track them directly. Recently published article "Physical Review" states that we can indirectly observe them by gravity waves

Over the past few years astronomers have observed gravitational waves created by joining black holes and neutron stars. We can observe them sensitively so that we can identify things like the rotation of the original mass and the rotation of the fusion bodies, as well as the mass and rotation of the black hole. However, with greater sensitivity, we should measure other energy fluctuations during the merger, and this new article is emerging here

Rotary black holes tend to give energy to any surrounding cloud of matter through a process called frame dragging. If a diffuse cloud of clouds emerged around the black hole when it started to connect with another, the intermediate frame effect could transmit a huge amount of energy between the two black holes. It is similar to how a satellite can outperform the Jupiter of the past to reach the outer solar system, but much more powerful. It is known as super radiation, it would create a particle beam that would be much more powerful than anything we could create on Earth. And this can create exotic particles that exceed the standard model. We could not directly monitor these particles, but the energy of the particles would affect the gravitational waves caused by the black holes. In search of gravitational wave oscillations we could learn exotic particles or at least determine the boundaries of exotic particles

The black hole in the particle accelerator would not be nearly as accurate as on the ground. But perhaps by studying gravitational waves, we can find out that there are particles in excess of the standard model, and that could make the effort to create new particle accelerations.

Daniel Baumann et al. Sounding of ultrasound bosses with binary black holes. arxiv.org/abs/1804.03208

">

Artist's Impression of the New Black Hole NASA / CXC / M.Weiss

After Higgs Bosson Discovery, Grand Hadron Collider, There Were Many Debates about where to go from here: LHC is currently the most powerful particle acceleration in the world, confronted with about 13 TeV energies, although it has given some physics advice beyond the standard model, it probably won't solve some of the biggest particle physics issues, but we need a lot more powerful particle acceleration, it is proposed to create a Future Circular Collider, which is almost ten times more than LHC, but it would be very expensive to build and operate, and some scientists ask if it is worth it.

But what if we could use what to do if we could use black holes? are powerful engines that create large particles of energy nozzles, flow from the black hole at almost light speed. Unfortunately, any exotic high energy they produce will quickly disappear, so we wouldn't be able to track them directly. However, the latest article, Physical Review D, states that we can indirectly observe them with gravity waves

Over the last few years, astronomers have observed gravitational waves created by joining black holes and neutron stars. We can observe them sensitively so that we can identify things like the rotation of the original mass and the rotation of the fusion bodies, as well as the mass and rotation of the black hole. However, in the case of higher sensitivity, we should be able to assess other fluctuations in energy during the merger, and this new article is emerging here.

Rotary black holes tend to give energy to any surrounding cloud of matter through a process called a frame. drag. If a diffuse cloud of clouds emerged around the black hole when it started to connect with another, the intermediate frame effect could transmit a huge amount of energy between the two black holes. It is similar to how a satellite can outperform the Jupiter of the past to reach the outer solar system, but much more powerful. It is known as super radiation, it would create a particle beam that would be much more powerful than anything we could create on Earth. And this can create exotic particles that exceed the standard model. We could not directly monitor these particles, but the energy of the particles would affect the gravitational waves caused by the black holes. In search of gravitational wave oscillations we could learn exotic particles or at least determine the boundaries of exotic particles

The black hole in the particle accelerator would not be nearly as accurate as on the ground. But perhaps by studying gravitational waves, we can find out that there are particles in excess of the standard model, and that could make the effort to create new particle accelerations.

Daniel Baumann et al. Sounding of ultrasound bosses with binary black holes. arxiv.org/abs/1804.03208


Source link