Nuclear Processes in Other Universes: Varying the Strength of the Weak Force

In summary: We explore a universe where the weak force is either stronger or weaker than observed and find that the difference in nuclear composition can have a significant impact on the structure and evolution of stars.
  • #1
jeffery_winkler
14
6
This relates to the anthropic principle and the multiverse.

Nuclear Processes in Other Universes: Varying the Strength of the Weak Force

https://journals.aps.org/prd/pdf/10.1103/PhysRevD.98.063014

Nuclear processes in other universes: Varying the strength of the weak force
Alex R. Howe, Evan Grohs, and Fred C. Adams
Phys. Rev. D 98, 063014 (2018) – Published 20 September 2018

Motivated by the possibility that the laws of physics could be different in other regions of space-time, we consider nuclear processes in universes where the weak interaction is either stronger or weaker than observed. We focus on the physics of both big bang nucleosynthesis (BBN) and stellar evolution. For sufficiently ineffective weak interactions, neutrons do not decay during BBN, and the baryon-to-photon ratio η must be smaller in order for protons to survive without becoming incorporated into larger nuclei. For stronger weak interactions, neutrons decay before the onset of BBN, and the early Universe is left with nearly a pure hydrogen composition. We then consider stellar structure and evolution for the different nuclear compositions resulting from BBN, a wide range of weak force strengths, and the full range of stellar masses for a given universe. We delineate the range of this parameter space that supports working stars, along with a determination of the dominant nuclear reactions over the different regimes. Deuterium burning dominates the energy generation in stars when the weak force is sufficiently weak, whereas proton-proton burning into helium-3 dominates for the regime where the weak force is much stronger than in our Universe. Although stars in these universes are somewhat different, they have comparable surface temperatures, luminosities, radii, and lifetimes so that a wide range of such universes remain potentially habitable.
 
  • Like
Likes mfb and ohwilleke
Physics news on Phys.org
  • #2
A related publication (from different authors) is Phys.Rev.D74:035006,2006: A Universe Without Weak Interactions

While we clearly do not live in these universes it is still an interesting exercise to explore how fine-tuned (if at all) our physics is.
 

FAQ: Nuclear Processes in Other Universes: Varying the Strength of the Weak Force

What is the weak force and how does it affect nuclear processes in other universes?

The weak force is one of the four fundamental forces of nature, along with gravity, electromagnetism, and the strong nuclear force. It is responsible for the decay of subatomic particles and plays a crucial role in nuclear processes. In other universes, the strength of the weak force may vary, which can significantly impact the behavior of nuclear particles and reactions.

Can the weak force be manipulated in other universes?

There is currently no evidence to suggest that the strength of the weak force can be manipulated in our own universe. However, in the theory of parallel universes, it is possible that the laws of physics, including the strength of the weak force, may differ in other universes. This could potentially be manipulated in those universes through advanced technology or natural processes.

How does varying the strength of the weak force impact the stability of atoms in other universes?

The stability of atoms in other universes is heavily dependent on the strength of the weak force. In our universe, the weak force is responsible for nuclear decay, which keeps atoms from becoming too large and unstable. In other universes where the weak force is stronger, atoms may be more likely to decay, leading to a different distribution of elements and potentially different physical properties.

Are there any potential consequences of altering the strength of the weak force in other universes?

Changing the strength of the weak force in other universes could have significant consequences on the formation and evolution of stars, galaxies, and even life. The physical laws of the universe are finely tuned to allow for the existence of complex structures like stars and planets. Altering the strength of the weak force could disrupt this delicate balance, resulting in vastly different universes.

How can we study the effects of varying the strength of the weak force in other universes?

Currently, we can only theorize about the potential effects of varying the strength of the weak force in other universes. However, with advancements in technology and our understanding of the laws of physics, we may one day be able to detect and study parallel universes. This could potentially give us insight into the consequences of varying the strength of the weak force and how it shapes different universes.

Back
Top