Does any gravitating body emit Hawking radiation?

In summary, the Hawking-Unruh temperature is an expression that represents the temperature at which a black hole emits Hawking radiation. It is given by the formula T = (hbar * g) / (2 * pi * c * k), where g is the gravitational acceleration at the surface of the black hole. This does not necessarily mean that any gravitating body will emit Hawking radiation, as it requires an event horizon to produce such radiation. However, any body with an event horizon, such as a black hole, should emit Hawking radiation at this temperature.
  • #1
johne1618
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The Hawking-Unruh temperature is given by the expression:

[itex] \large T = \frac{\hbar g}{2 \pi c k} [/itex]

where g is the gravitational acceleration at the surface of a black hole.

Does this expression imply that any gravitating body will emit Hawking radiation?

For example if we take the acceleration due to gravity at the Earth's surface to be [itex]g = 10 \ m/s^2[/itex] does that mean that the Earth emits Hawking radiation at a temperature [itex]T = 10^{-20} K[/itex]?

John
 
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  • #2
No. You have to have an event horizon to produce hawking radiation; but anybody with an event horizon should do that (few examples besides black-holes).
 

1. What is Hawking radiation?

Hawking radiation is a theoretical phenomenon proposed by physicist Stephen Hawking in 1974. It suggests that black holes emit radiation due to quantum effects near the event horizon.

2. Do all gravitating bodies emit Hawking radiation?

No, according to current understanding, only black holes emit Hawking radiation. Other gravitating bodies, such as planets and stars, do not have strong enough gravitational forces to generate this type of radiation.

3. How is Hawking radiation different from regular radiation?

Hawking radiation is different from regular radiation because it is not caused by the thermal emission of particles, but rather by quantum effects near the event horizon of a black hole. It is also unique in that it causes black holes to slowly lose mass over time.

4. Has Hawking radiation been observed?

No, Hawking radiation has not been directly observed yet. It is a highly theoretical concept and requires extremely precise measurements to detect. However, there is evidence of its existence through various indirect observations and experiments.

5. What are the implications of Hawking radiation?

The discovery of Hawking radiation would have significant implications for our understanding of black holes and the laws of physics. It could also have practical applications, such as providing a potential source of energy in the distant future.

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