Positronium from vacuum fluctuations ?

In summary: however, due to the strong correlations between the virtual positronium and the atoms it is actually quite easy for these virtual particles to recombine and so the final result would be an electron and positron pair rather than positronium. so does this mean that we currently don't have any way of observing this process happening in nature?
  • #1
xortdsc
98
0
Hi,

I wondered if it is theoretically possible that the vacuum energy produces an electron/positron pair which then bonds into positronium instead of directly annihilating again. And if it is theoretically possible has this ever been observed ?

Thanks and cheers.
 
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  • #2
No. This would violate energy conservation.
 
  • #3
I see. So how could I visualize this ? The electron/positron pair which can be spontanously produced by vacuum fluctuations (which should be possible, causing the casimir effect) do not separate far enough to escape each other (to produce a "real" electron/positron pair) nor to separate enough to create a positronium system ? Is that right ?
 
  • #4
xortdsc said:
Hi,

I wondered if it is theoretically possible that the vacuum energy produces an electron/positron pair which then bonds into positronium instead of directly annihilating again. And if it is theoretically possible has this ever been observed ?

Thanks and cheers.

It's a really new paper.

http://arxiv.org/pdf/1404.5243v1.pdf

Submitted on 21 Apr 2014

Abstract:

Positron scattering and annihilation on noble gas atoms below the positronium formation threshold is studied ab initio using many-body theory methods. The many-body theory provides a near-complete understanding of the positron-noble-gas-atom system at these energies and yields accurate numerical results. It accounts for positron-atom and electron-positron correlations, e.g., polarization of the atom by the incident positron and the non-perturbative process of virtual positronium formation. These correlations have a large effect on the scattering dynamics and result in a strong enhancement of the annihilation rates compared to the independent-particle mean-field description. Computed elastic scattering cross sections are found to be in good agreement with recent experimental results and Kohn variational and convergent close-coupling calculations. The calculated values of the annihilation rate parameter Zeff (effective number of electrons participating in annihilation) rise steeply along the sequence of noble gas atoms due to the increasing strength of the correlation effects, and agree well with experimental data.
 
Last edited:
  • #5
ah thank you. so if i understand it correctly this article seems to suggest that spontaneous creation of virtual positronium is indeed a possibility.
 

Related to Positronium from vacuum fluctuations ?

1. What is positronium?

Positronium is a unique atom-like system composed of an electron and a positron (the antiparticle of an electron) bound together by electrostatic forces. It is a temporary state of matter that can only exist for a very short amount of time before the electron and positron annihilate each other.

2. How is positronium formed from vacuum fluctuations?

Positronium is formed through a process called vacuum fluctuation, which occurs when particles and antiparticles spontaneously appear and annihilate each other in empty space. In the case of positronium, an electron and a positron are created out of the vacuum fluctuations and are temporarily bound together before annihilation.

3. What is the significance of positronium in physics?

Positronium is significant in physics because it is a unique system that allows scientists to study the behavior of matter and antimatter interactions. It also provides insights into the fundamental properties of particles and the quantum world.

4. How is positronium detected and measured?

Positronium can be detected and measured using various techniques such as positron annihilation spectroscopy, which detects the gamma rays produced during the annihilation of positronium. Another method is laser spectroscopy, which uses a laser to excite the positronium atoms and measure their energy levels.

5. Can positronium be used in practical applications?

Currently, positronium does not have any practical applications. However, studies on positronium can provide valuable insights into antimatter and quantum physics, which can potentially lead to future technological advancements in areas such as quantum computing and energy production.

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