Why does Gravity affects Light?

In summary, according to special relativity, energy is equivalent to mass, so photons have some "effective" mass which can be affected by gravity. If you want the more complicated answer, you need to invoke the analogy of gravity "bending" space while light always goes "straight", which makes it look to us like it's not.
  • #1
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Hi all , its my first post here in PF.

Well basically , I have this really simple question (To you guys , but its hard for me).

Why does Gravity affects light?

In school , we are taught that gravity affects things that has mass. Now since light is composed of photons and since they are massless , how does gravity affects them?

Can anyone explains this to me? Try to give me a really simple answer , because I am not really a physics whizz ;)
 
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  • #2
Welcome at PF.

The simplest way of looking at it, is that light does not have mass, but it does have energy. For example, a photon with frequency f, has energy E = h f (with h Planck's constant, up to possible factors of 2 pi). Now according to special relativity, energy is equivalent with mass, so although photons do not have a rest mass, they have energy which gives them some - if you want - "effective" mass which can be affected by gravity.

If you want the more complicated answer, you need to invoke the analogy of gravity "bending" space while light always goes "straight", which makes it look to us like it's not. The famous (flawed, but for this purpose sufficient) analogy is of space like a rubber sheet and heavy objects making a dent in it. So in this image a photon would go "straight" along one of the black lines, for example - but to us it would appear as if it is being curved.

If you want the technically correct answer (which I suppose you don't, given your last sentence, but I think it's good to state it): a photon always follows a geodesic. The geodesics are defined by the metric on the space, which in turn depends on the mass content of the universe. If the metric is not flat but we are pretending it is, the geodesic will look curved.
Basically this the same as the "more complicated" answer above but without involving things like rubber sheets.
 
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  • #3
CompuChip said:
Welcome at PF.

The simplest way of looking at it, is that light does not have mass, but it does have energy. For example, a photon with frequency f, has energy E = h f (with h Planck's constant, up to possible factors of 2 pi). Now according to special relativity, energy is equivalent with mass, so although photons do not have a rest mass, they have energy which gives them some - if you want - "effective" mass which can be affected by gravity.

If you want the more complicated answer, you need to invoke the analogy of gravity "bending" space while light always goes "straight", which makes it look to us like it's not. The famous (flawed, but for this purpose sufficient) analogy is of space like a rubber sheet and heavy objects making a dent in it. So in this image a photon would go "straight" along one of the black lines, for example - but to us it would appear as if it is being curved.


@ Your first answer , what is the relationship between frequency and energy? Pi is that 3.142 thing.. ?


Does that means that light is going straight , but the path it is moving is not straight , but bent? So to us it appears to be curved? And was the path that the 'ball' take spacetime?

Sorry for asking these questions.. They don't teach these stuff in school.
 
  • #4
Please read an entry in the FAQ thread. This has been addressed.

Zz.
 

1. Why is light affected by gravity?

Light, like any other form of energy, is subject to the laws of gravity. Gravity is a property of mass, and since light has energy, it also has a tiny amount of mass. Therefore, it is affected by the gravitational pull of massive objects.

2. How does gravity affect the path of light?

Gravity bends the path of light, causing it to follow a curved trajectory. This is known as gravitational lensing. The more massive the object, the greater the bending of light.

3. Does gravity slow down light?

No, gravity does not slow down light. According to Einstein's theory of general relativity, the speed of light in a vacuum is constant, regardless of the gravitational field it is passing through. However, gravity can change the wavelength of light, which can make it appear to have slowed down.

4. Can gravity affect the color of light?

Yes, gravity can affect the color of light. When light travels through a strong gravitational field, the wavelength of the light can be stretched or compressed, causing a shift in the color of the light. This is known as gravitational redshift or blueshift, depending on the direction of the shift.

5. How does gravity affect the speed of light?

Gravity does not affect the speed of light. As mentioned before, the speed of light in a vacuum is constant, regardless of the gravitational field it is passing through. However, gravity can affect the path and properties of light, such as its wavelength and frequency, but not its speed.

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