Astronomy:Neutrino decoupling

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In Big Bang cosmology, neutrino decoupling was the epoch at which neutrinos ceased interacting with other types of matter,[1] and thereby ceased influencing the dynamics of the universe at early times.[2] Prior to decoupling, neutrinos were in thermal equilibrium with protons, neutrons and electrons, which was maintained through the weak interaction. Decoupling occurred approximately at the time when the rate of those weak interactions was slower than the rate of expansion of the universe. Alternatively, it was the time when the time scale for weak interactions became greater than the age of the universe at that time. Neutrino decoupling took place approximately one second after the Big Bang, when the temperature of the universe was approximately 10 billion kelvin, or 1 MeV.[3] As neutrinos rarely interact with matter, these neutrinos still exist today, analogous to the much later cosmic microwave background emitted during recombination, around 377,000 years after the Big Bang. They form the cosmic neutrino background (abbreviated CνB or CNB). The neutrinos from this event have a very low energy, around 10−10 times smaller than is possible with present-day direct detection.[4] Even high energy neutrinos are notoriously difficult to detect, so the CNB may not be directly observed in detail for many years, if at all.[4] However, Big Bang cosmology makes many predictions about the CNB, and there is very strong indirect evidence that the CNB exists.

Derivation of decoupling time

Neutrinos are scattered (interfering with free streaming) by their interactions with electrons and positrons, such as the reaction

[math]\displaystyle{ e^- + e^+ \longleftrightarrow \nu_e + \bar{\nu}_e }[/math].

The approximate rate of these interactions is set by the number density of electrons and positrons, the averaged product of the cross section for interaction and the velocity of the particles. The number density [math]\displaystyle{ n }[/math] of the relativistic electrons and positrons depends on the cube of the temperature [math]\displaystyle{ T }[/math], so that [math]\displaystyle{ n \propto T^3 }[/math]. The product of the cross section and velocity for weak interactions for temperatures (energies) below W/Z boson masses (~100 GeV) is given approximately by [math]\displaystyle{ \langle \sigma v \rangle \sim G_F^2 T^2 }[/math], where [math]\displaystyle{ G_F }[/math] is Fermi's constant (as is standard in particle physics calculations, factors of the speed of light [math]\displaystyle{ c }[/math] are set equal to 1). Putting it all together, the rate of weak interactions [math]\displaystyle{ \Gamma }[/math] is

[math]\displaystyle{ \Gamma = n \langle \sigma v \rangle \sim G_F^2 T^5 }[/math].

This can be compared to the expansion rate which is given by the Hubble parameter [math]\displaystyle{ H }[/math], with

[math]\displaystyle{ H = \sqrt{\frac{8\pi}{3}G \rho} }[/math],

where [math]\displaystyle{ G }[/math] is the gravitational constant and [math]\displaystyle{ \rho }[/math] is the energy density of the universe. At this point in cosmic history, the energy density is dominated by radiation, so that [math]\displaystyle{ \rho \propto T^4 }[/math]. As the rate of weak interaction depends more strongly on temperature, it will fall more quickly as the universe cools. Thus when the two rates are approximately equal (dropping terms of order unity, including an effective degeneracy term which counts the number of states of particles which are interacting) gives the approximate temperature at which neutrinos decouple:

[math]\displaystyle{ G_F^2 T^5 \sim \sqrt{G T^4} }[/math].

Solving for temperature gives

[math]\displaystyle{ T \sim \left( \frac{\sqrt{G}}{G_F^2} \right) ^{1/3} \sim 1~\textrm{MeV} }[/math].[5]

While this is a very rough derivation, it illustrates the important physical phenomena which determined when neutrinos decoupled.

Observational evidence

While neutrino decoupling can not be observed directly, it is expected to have left behind a cosmic neutrino background, analogous to the cosmic microwave background radiation of electromagnetic radiation which was emitted at a much later epoch. "The detection of the neutrino background is far beyond the capabilities of the present generation of neutrino detectors."[6] There is data, however, which indirectly indicates the presence of a neutrino background. One piece of evidence is damping of the angular power spectrum of the CMB, which results from anisotropies in the neutrino background.[7]

Another indirect measurement of neutrino decoupling is allowed by the role that neutrino decoupling plays in setting the ratio of neutrons to protons. Before decoupling, the number of neutrons and protons are maintained in their equilibrium abundances by weak interactions, specifically beta decay and electron capture (or inverse beta decay) according to

[math]\displaystyle{ n \leftrightarrow p + e^- + \bar{\nu}_e }[/math]

and

[math]\displaystyle{ p + e^- \leftrightarrow \nu_e + n }[/math].

Once the rate of weak interactions is slower than the characteristic rate of the expansion of the universe, this equilibrium cannot be maintained, and the abundance of neutrons to protons "freezes in," at a value

[math]\displaystyle{ \left[\frac{n}{n + p}\right] = 0.21 }[/math].[8]

This value is simply found by evaluating the Boltzmann factor for neutrons and protons at decoupling time, according to

[math]\displaystyle{ \frac{n_n(T)}{n_p(T)} = \exp\left(\frac{-\Delta m}{T}\right) }[/math],

where [math]\displaystyle{ \Delta m }[/math] is the mass difference between neutrons and protons and [math]\displaystyle{ T }[/math] is the temperature at decoupling.[5] This ratio is critical to the synthesis of atoms during Big Bang nucleosynthesis, the process which formed the majority of helium atoms in the universe, as it "is the dominant factor in determining the amount of helium produced."[9] As helium atoms are stable, the neutrons are locked in, and beta decay of neutrons into protons, electrons, and neutrinos can no longer occur. Thus the abundance of neutrons in the primordial matter can be measured by astronomers, and, as it was determined by the ratio of neutrons to protons at neutrino decoupling, the helium abundance indirectly measures the temperature at which neutrino decoupling took place, and is in agreement with the figure derived above.[10]

Indirect evidence from phase changes to the Cosmic Microwave Background (CMB)

Big Bang cosmology makes many predictions about the CNB, and there is very strong indirect evidence that the cosmic neutrino background exists, both from Big Bang nucleosynthesis predictions of the helium abundance, and from anisotropies in the cosmic microwave background. One of these predictions is that neutrinos will have left a subtle imprint on the cosmic microwave background (CMB). It is well known that the CMB has irregularities. Some of the CMB fluctuations were roughly regularly spaced, because of the effect of baryon acoustic oscillations. In theory, the decoupled neutrinos should have had a very slight effect on the phase of the various CMB fluctuations.[4]

In 2015, it was reported that such shifts had been detected in the CMB. Moreover, the fluctuations corresponded to neutrinos of almost exactly the temperature predicted by Big Bang theory (1.96 ± 0.02 K compared to a prediction of 1.95 K), and exactly three types of neutrino, the same number of neutrino flavours currently predicted by the Standard Model.[4]

See also

References

  1. Rubakov, Gorbunov (2018), p.23
  2. Longair (2006), p. 290
  3. Longair (2006), p. 291
  4. 4.0 4.1 4.2 4.3 Cosmic Neutrinos Detected, Confirming The Big Bang's Last Great Prediction - Forbes coverage of original paper: Follin, Brent; Knox, Lloyd; Millea, Marius; Pan, Zhen (2015-08-26). "First Detection of the Acoustic Oscillation Phase Shift Expected from the Cosmic Neutrino Background". Physical Review Letters 115 (9): 091301. doi:10.1103/physrevlett.115.091301. ISSN 0031-9007. PMID 26371637. Bibcode2015PhRvL.115i1301F. 
  5. 5.0 5.1 Bernstein (1989), p. 27.
  6. Longair (2006), p. 302.
  7. Trotta (2005), p. 1.
  8. Longair (2006), p. 291–292.
  9. Grupen (2005), p. 218.
  10. Longair (2006), p. 293.

Bibliography

External links