Cosmological expansion and uncertainty

In summary, the conversation discusses the possibility of particle/antiparticle pairs being carried away from each other at speeds greater than the speed of light due to the acceleration of expansion in the universe. However, it is clarified that the term "acceleration" refers to the increase in rate at which objects recede from each other, not their actual speed. It is also mentioned that the concept of Hawking radiation at the cosmological horizon is based on the prediction that objects permanently separated will eventually recede from each other at superluminal speeds. However, this is only true for the cosmological horizon and not for a classical black hole, where Hawking radiation is not observer dependent.
  • #1
T S Bailey
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Firstly, I assume that I'm correct in assuming that since expansion is accelerating it will increase to any arbitrarily large value at some point in the future. If this is true, there must be some point at which particle/antiparticle pairs (due to uncertainty) are carried away from one another at greater than the speed of light, analogous to the way in which hawking radiation is created at a BH's event horizon. Is there anything wrong with this thought experiment?
 
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  • #2
That won't happen, because that's not what the 'acceleration' means. The rate at which particles move apart is proportional to the distance between them, and that constant of proportionality - the Hubble Parameter - is actually declining over time.

The use of the word 'acceleration' is to signify that a particular object that is currently receding at rate R m/s will in a billion years be receding at a greater rate (expressed in m/s), unless local gravitational irregularities interfere with that. It will be receding faster simply because it is farther away.

However if a pair were able to remain permanently separated, they would end up receding from one another superluminally once they were far enough separated.
 
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  • #4
For a classical black hole, Hawking raditation is not observer dependent. This is untrue for the cosmological horizon. Every observer in the universe will disagree on the location of the cosmological horizon, whereas they will all agree on the location of the event horizon of a black hole
 
  • #5
Chronos said:
For a classical black hole, Hawking raditation is not observer dependent. This is untrue for the cosmological horizon. Every observer in the universe will disagree on the location of the cosmological horizon, whereas they will all agree on the location of the event horizon of a black hole

Thanks, good catch!

Though I don't think that is essential for the derivation [but I didn't check]. Everyone at rest agrees on the vacuum temperature, so the relative CH location is what counts.
 

Related to Cosmological expansion and uncertainty

1. What is cosmological expansion?

Cosmological expansion refers to the observed phenomenon in which the universe is continuously expanding. This means that the distance between galaxies, clusters of galaxies, and other celestial objects is increasing over time.

2. How does cosmological expansion affect the universe?

Cosmological expansion has several effects on the universe. It causes the redshift of light from distant objects, making them appear to be moving away from us. It also leads to the cooling and dilution of matter in the universe, resulting in a decrease in the overall density of the universe.

3. What is the role of dark energy in cosmological expansion?

Dark energy is a hypothetical form of energy that is believed to be responsible for the accelerating expansion of the universe. It is thought to make up about 68% of the total energy content of the universe and its exact nature is still unknown.

4. What is the uncertainty principle and how does it relate to cosmological expansion?

The uncertainty principle is a fundamental principle in quantum mechanics that states that it is impossible to know both the position and momentum of a particle with absolute certainty. This principle also applies to the expansion of the universe, as the exact rate of expansion and the properties of dark energy are still uncertain and subject to ongoing research and study.

5. How do scientists measure and study cosmological expansion and uncertainty?

Scientists use a variety of methods to study cosmological expansion, including measuring the redshift of light from distant galaxies, studying the cosmic microwave background radiation, and using computer simulations to model the evolution of the universe. They also use advanced instruments and telescopes, such as the Hubble Space Telescope, to observe and gather data on the expansion of the universe.

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