Science, asked by haaneisa0108, 5 months ago

How do scientist gain information about the properties of distant stars in the universe​

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Answered by CandyCakes
6

Answer:

Spectroscopy also tells you a star's temperature, mass and surface gravity. A star's mass effects the way atoms in its atmosphere act, giving very narrow spectrum lines. ... "The next generation of really big telescopes will be powerful enough to see distant planets and study their atmospheric spectrum.

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Answered by sutapa86ad
4

Spectroscopy also tells you a star's temperature, mass and surface gravity. A star's mass effects the way atoms in its atmosphere act, giving very narrow spectrum lines. ... "The next generation of really big telescopes will be powerful enough to see distant planets and study their atmospheric spectrum.The most common method astronomers use to determine the composition of stars, planets, and other objects is spectroscopy. Today, this process uses instruments with a grating that spreads out the light from an object by wavelength. This spread-out light is called a spectrum.The science of spectroscopy is quite sophisticated. From spectral lines astronomers can determine not only the element, but the temperature and density of that element in the star. The spectral line also can tell us about any magnetic field of the star. The width of the line can tell us how fast the material is moving.

Astronomy: Rick Johnson

The most common method astronomers use to determine the composition of stars, planets, and other objects is spectroscopy. Today, this process uses instruments with a grating that spreads out the light from an object by wavelength. This spread-out light is called a spectrum. Every element — and combination of elements — has a unique fingerprint that astronomers can look for in the spectrum of a given object. Identifying those fingerprints allows researchers to determine what it is made of.

That fingerprint often appears as the absorption of light. Every atom has electrons, and these electrons like to stay in their lowest-energy configuration. But when photons carrying energy hit an electron, they can boost it to higher energy levels. This is absorption, and each element’s electrons absorb light at specific wavelengths (i.e., energies) related to the difference between energy levels in that atom. But the electrons want to return to their original levels, so they don’t hold onto the energy for long. When they emit the energy, they release photons with exactly the same wavelengths of light that were absorbed in the first place. An electron can release this light in any direction, so most of the light is emitted in directions away from our line of sight. Therefore, a dark line appears in the spectrum at that particular wavelength.

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