Magnet Areas In Big Atmosphere

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Astronomers at the Max Planck Company for Astronomy have, for initially, tested the place of magnet areas in big atmosphere of gas and particles in a do not have universe. Their success recommend that such magnet areas have fun with a key position in directing topic to kind more dense atmosphere, and thus in location the level for the beginning of new actors.

The operate is being publicized in the paper Characteristics.

Stars and their planet's are blessed when large atmosphere of interstellar gas and particles fall. You've probably seen the producing good plant centers in wonderful large images: Vibrant nebulae, lit by the shiny fresh actors they have introduced forth.

Astronomers know quite a bit about these so-called molecular clouds: They be made up mainly of hydrogen substances -- uncommon in a cosmos where circumstances are hardly ever right for hydrogen atoms to connection together into substances. And if one remnants the syndication of atmosphere in a control universe like our own Milky Way universe, one confirms that they are covered up along the control hands.

But how do those clouds come into being? What makes matter congregate in regions a hundred or even a thousand times more dense than the surrounding interstellar gas?

One candidate mechanism involves the galaxy's magnetic fields. Everyone who has seen a magnet act on iron filings in the classic classroom experiment knows that magnetic fields can be used to impose order. Some researchers have argued that something similar goes on in the case of molecular clouds: that galaxies' magnetic fields guide and direct the condensation of interstellar matter to form denser clouds and facilitate their further collapse.

Some astronomer see this as the key mechanism enabling star formation. Others contend that the cloud matter's gravitational attraction and turbulent motion of gas within the cloud are so strong as to cancel any influence of an outside magnetic field.

If we were to restrict attention to our own galaxy, it would be difficult to find out who is right. We would need to see our galaxy's disk from above to make the appropriate measurements; in reality, our Solar System sits within the galactic disk. That is why Hua-bai Li and Thomas Henning from the Max Planck Institute for Astronomy chose a different target: the Triangulum galaxy, 3 million light-years from Earth and also known as M 33, which is oriented in just the right way (cf. image).

Using a telescope known as the Submillimeter Array (SMA), which is located at Mauna Kea Observatory on Mauna Kea Island, Hawai'i, Li and Henning measured specific properties of radiation received from different regions of the galaxy which are correlated with the orientation of these region's magnetic fields. They found that the magnetic fields associated with the galaxy's six most massive giant molecular clouds were orderly, and well aligned with the galaxy's spiral arms.

If turbulence played a more important role in these clouds than the ordering influence of the galaxy's magnetic field, the magnetic field associated with the cloud would be random and disordered.

Thus, Li and Henning's observations are a strong indication that magnetic fields indeed play an important role when it comes to the formation of dense molecular clouds -- and to setting the stage for the birth of stars and planetary systems like our own.