photon epoch

In physical cosmology, the photon epoch was the period in the evolution of the early universe in which photons dominated the energy of the universe. The photon epoch started after most leptons and anti-leptons were annihilated at the end of the lepton epoch, about 10 seconds after the Big Bang.[1] Atomic nuclei were created in the process of nucleosynthesis, which occurred during the first few minutes of the photon epoch. For the remainder of the photon epoch, the universe contained a hot dense plasma of nuclei, electrons and photons.[2]

At the start of this period, many photons had sufficient energy to photodissociate deuterium, so those atomic nuclei that formed were quickly separated back into protons and neutrons. By the ten second mark, ever fewer high energy photons were available to photodissociate

11.1.1 deuterium

and thus the abundance of these nuclei began to increase.

Heavier atoms began to form through nuclear fusion processes:

11.1.2 tritium

11.1.3 tritium and helium-4

11.1.4 helium-3 en helium-4

Finally, trace amounts of

10.1.5 lithium and beryllium

Once the thermal energy dropped below 0.03 MeV, nucleosynthesis effectively came to an end. Primordial abundances were now set, with the measured amounts in the modern epoch providing checks on the physical models of this period.[3]

370,000 years after the Big Bang, the temperature of the universe fell to the point where nuclei could combine with electrons to create neutral atoms. As a result, photons no longer interacted frequently with matter, the universe became transparent and the cosmic microwave background radiation was created and then structure formation took place. This is referred to as the surface of last scattering, as it corresponds to a virtual outer surface of the spherical observable universe.[4]

Document

[1]

11.2 In-Depth Reading

Big Bang Nucleosynthesis. Evan Grohs, George M. Fuller (2023)
Big Bang nucleosynthesis as a probe of new physics. Carlos A. Bertulani, Francis W. Hall, Benjamin I. Santoyo (2022)
Revisiting big bang nucleosynthesis with a new particle species : effect of co-annihilation with neutrons. Deep Ghosh (2022)
Big Bang Nucleosynthesis Limits and Relic Gravitational Waves Detection Prospects. Tina Kahniashvili, Emma Clarke, Jonathan Stepp, Axel Brandenburg (2022)
Primordial Big Bang Nucleosynthesis and Generalized Uncertainty Principle. Giuseppe Gaetano Luciano (2021)
Big Bang Nucleosynthesis Initial Conditions: Revisiting Wagoner et al. (1967). Charlie Sharpe, Geraint F. Lewis, Luke A. Barnes (2021)
Theoretical calculation of nuclear reactions of interest for Big Bang Nucleosynthesis. Alex Gnech (2020)

11.3 Recent Developments

One recent development in our understanding of the photon epoch comes from the measurements of the cosmic microwave background (CMB) radiation. The CMB is the remnant radiation from the hot plasma of charged particles and photons that existed during the photon epoch. In 2020, the European Space Agency's Planck satellite released a new map of the CMB, which provides more precise measurements of the CMB's polarization. These measurements help us understand the early universe's magnetic fields and the physics of the photon epoch.

Another recent development comes from the detection of gravitational waves by the Laser Interferometer Gravitational-Wave Observatory (LIGO) and the Virgo Collaboration. In 2017, LIGO detected a neutron star merger that produced both gravitational waves and gamma-ray bursts. This event provided new insights into the physics of the photon epoch and the early universe's formation of heavy elements.

References

[1] The Timescale of Creation Archived 2009-07-28 at the Wayback Machine

[2] Narison, S. (2015). Particles and the Universe, From the Ionian School to the Higgs Boson and Beyond. World Scientific Publishing Company Pte Limited. p. 219. ISBN 9789814644709.

[3] Boesgaard, A. M.; Steigman, G. (1985). "Big Bang nucleosynthesis: theories and observations". Annual Review of Astronomy and Astrophysics. 23: 319–378. Bibcode:1985ARA&A..23..319B. doi:10.1146/annurev.aa.23.090185.001535.

[4] Sazhina, O. S.; et al. (May 2008). "Cosmic microwave background anisotropy induced by a moving straight cosmic string". Journal of Experimental and Theoretical Physics. 106 (5): 878–887. arXiv:0809.0992. Bibcode:2008JETP..106..878S. doi:10.1134/S1063776108050051. S2CID 15260246.

[5] Wikipedia

Advised Literature

"The Early Universe" by Edward Kolb and Michael Turner (1990)
"The First Three Minutes" by Steven Weinberg (1993) - A classic account of the early universe, including the photon epoch.
"Big Bang: The Origin of the Universe" by Simon Singh (2004) - A more accessible book that covers the development of our understanding of the Big Bang theory.
"Introduction to Cosmology" by Barbara Ryden (2002) - A good introductory textbook on cosmology, which includes a discussion on the photon epoch.
"Cosmology: A Very Short Introduction" by Peter Coles (2001) - A concise and accessible overview of the field of cosmology.
"Modern Cosmology" by Scott Dodelson and Fabian Schmidt (2019) - A more advanced textbook on cosmology, including detailed discussions on the early universe, including the photon epoch.
"Cosmological Inflation and Large-Scale Structure" by Andrew R. Liddle and David H. Lyth (2000) - This book delves into inflationary cosmology and large-scale structure formation in the universe, with some focus on the early universe phases like the photon epoch.