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Torog
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If we run two identical lasers and put one at sea level and one on top of a high mountain, will they operate at different frequencies?
All of the above still applies. It will be slower than normal for any clock above it, faster for any clock below it, and unaltered for a clock right next to it.Torog said:Shouldn't the clock (laser) on the mountain be slower?
The second and third are the same.Torog said:First is a red shift given by the recession velocity (or general expansion of the Universe) second by the red shift caused by light having to make its way out of the gravitational field and third by the light having come from a star, quasar or other with a strong gravitational field where time and chemical processes run slower (redder) due to time being slower in the heavy gravitational field.
We can combine redshift and gravitational time dilation like this:Torog said:Excuse me if I shift to cosmology. From what I understand the observed red shift of stars should come from three factors - according to the present model - First is a red shift given by the recession velocity (or general expansion of the Universe) second by the red shift caused by light having to make its way out of the gravitational field and third by the light having come from a star, quasar or other with a strong gravitational field where time and chemical processes run slower (redder) due to time being slower in the heavy gravitational field.
Gravitational redshift is a phenomenon in which light (or other forms of electromagnetic radiation) is observed to have a longer wavelength and lower frequency when it is emitted from a source located in a strong gravitational field, such as near a massive object like a black hole or a neutron star.
In the context of lasers, gravitational redshift can cause a difference in the operating frequency of two lasers that are located at different distances from a massive object. The laser closer to the object will experience a greater redshift and therefore operate at a lower frequency compared to the laser further away.
Gravitational redshift occurs because of the bending of spacetime by a massive object. This bending causes the wavelength of light to stretch as it travels through the gravitational field, resulting in a longer wavelength and lower frequency.
Gravitational redshift is a direct consequence of Einstein's theory of general relativity, which describes how gravity affects the curvature of spacetime. According to this theory, the strength of a gravitational field is directly related to the amount of spacetime curvature, which in turn affects the wavelength of light.
While gravitational redshift is most commonly observed in extreme environments like near black holes, it can also be observed in more subtle ways on Earth. For example, clocks at higher altitudes experience a slightly lower gravitational pull and therefore run at a slightly faster rate compared to clocks at sea level, a phenomenon known as gravitational time dilation.