Cooling of Neutron Stars and Urca-process

In summary, the direct Urca process cannot cool neutron stars due to the Pauli exclusion principle. However, the modified Urca process, which involves an additional neutron catalyzing the reaction, is allowed as a means of cooling the star. This process may be related to cooper pairing and has been studied in many-body theory. While it is not the only solution, it has been shown to potentially provide rapid cooling of the star. Ultimately, the cooling of neutron stars remains a hot topic in theoretical physics and further research is needed to fully understand the process.
  • #1
Orbb
82
0
Hi,

in a lecture I was told that the cooling of neutron stars cannot happen via the 'direct' Urca process (beta decay and inverse beta decay), because the created particles cannot go into occupied states (Pauli exclusion). The 'modified' Urca process was introduced, with an additional neutron catalysing the reaction. Now what is the crucial difference here, that makes the modified Urca process an allowed one as opposed to the direct Urca?

Thank you for your answers.
 
Astronomy news on Phys.org
  • #2
That is a hot topic [pardon the pun] in theoretical physics. The direct urca process cannot work on a neutron star for reasons as stated. But, neutron stars must eventually cool to remain in conformance with the laws of thermodynamics. The modified urca process is an attempt to satisfy this demand. I don't particularly care for the additional neutron thing as a solution. Quark soup is a messy affair.
 
  • #3
Okay, but why is the modified Urca allowed? Has it to do with cooper pairing leading to different statistics?
 
  • #4
That is one possibility. See, for example:
Neutrino Emission from Cooper Pairs and Minimal Cooling of Neutron Stars
http://arxiv.org/abs/0906.1621
 
  • #5
I think that arguments and estimates based on fundamental relations of many-body theory show that one realization of this phenomenon could produce very rapid cooling of the star via a direct nucleon Urca process displaying a T5 dependence on temperature.
_____________________
Good resource when teaching sight words
 
  • #6
What we see appears to suggest neutron stars cool very near the low limit required by thermodynamics. I believe that rules out the URCA process. I am guessing here, as are most theorists.
 

Related to Cooling of Neutron Stars and Urca-process

1. What is the Urca process and how does it relate to the cooling of neutron stars?

The Urca process is a type of neutrino emission that occurs in the core of a neutron star, in which protons and neutrons combine to form a neutron and a proton, releasing energy in the form of neutrinos. This process is important for the cooling of neutron stars because it allows the star to lose thermal energy and cool down.

2. How do neutron stars cool down and how long does it take?

Neutron stars cool down through a combination of processes such as neutrino emission, photon emission, and conduction. The exact timescale for cooling varies depending on the initial temperature and composition of the neutron star, but it can take anywhere from a few hundred thousand years to several million years.

3. What is the role of superfluidity in the cooling of neutron stars?

Superfluidity is the property of certain particles, such as neutrons, to flow without any resistance. In neutron stars, superfluidity plays a crucial role in cooling by allowing the neutrons to move more freely and carry away thermal energy more efficiently.

4. Can the Urca process be observed in other astronomical objects?

Yes, the Urca process can also occur in other dense, compact objects such as white dwarfs and certain types of supernovae. However, it is most commonly observed in neutron stars due to their extremely high densities.

5. How does the cooling of neutron stars affect their magnetic fields?

The cooling of neutron stars can have a significant impact on their magnetic fields. As the star cools, the magnetic field strength may increase due to the conservation of magnetic flux. However, at very low temperatures, the magnetic field may decay due to the effects of superconductivity. The exact evolution of the magnetic field during cooling is still a topic of ongoing research.

Similar threads

What happens when a neutron star collapses into a black hole?
    • Astronomy and Astrophysics
2
Replies
58
Views
16K
I How Does Beta Decay Relate to the Role of W Bosons in Weak Nuclear Force?
    • High Energy, Nuclear, Particle Physics
Replies
4
Views
2K
What prevents a star from collapsing after stellar death?
    • Astronomy and Astrophysics
2
Replies
51
Views
8K
I Black Hole Formation: Fermion Pressure & Neutron Stars
    • Other Physics Topics
Replies
14
Views
2K
Prompt neutrons, delayed neutrons, chain reaction control
    • Nuclear Engineering
2
Replies
36
Views
6K
Are there widespread misconceptions about degeneracy pressure?
    • Astronomy and Astrophysics
2
Replies
63
Views
23K
What is the ultimate fate of a massive star in space?
    • Cosmology
Replies
1
Views
3K
Magnetic Fields of Neutron Stars
    • Astronomy and Astrophysics
Replies
6
Views
5K
A MOND Theory Primer: Stacy McGaugh's Research Program Explored
    • Beyond the Standard Models
Replies
11
Views
2K
Is my summary of these subjects correct?
    • Other Physics Topics
Replies
0
Views
780

Hot Threads

Recent Insights

Back
Top