The Low-Energy Frontier of Particle Physics (1002.0329v1)

Abstract: Most embeddings of the Standard Model into a more unified theory, in particular the ones based on supergravity or superstrings, predict the existence of a hidden sector of particles which have only very weak interactions with the visible sector Standard Model particles. Some of these exotic particle candidates (such as e.g. "axions", "axion-like particles" and "hidden U(1) gauge bosons") may be very light, with masses in the sub-eV range, and have very weak interactions with photons. Correspondingly, these very weakly interacting sub-eV particles (WISPs) may lead to observable effects in experiments (as well as in astrophysical and cosmological observations) searching for light shining through a wall, for changes in laser polarisation, for non-linear processes in large electromagnetic fields and for deviations from Coulomb's law. We present the physics case and a status report of this emerging low-energy frontier of fundamental physics.

• The paper demonstrates that extensions of the Standard Model predict weakly interacting sub-eV particles (WISPs) with rich low-energy phenomenology.
• It employs astrophysical and cosmological constraints, including data from white dwarfs and SN1987A, to bound the properties of these elusive particles.
• The study highlights innovative experimental searches such as light-shining-through-a-wall and laser polarization techniques to detect axions and axion-like particles.

Insights into the Low-Energy Frontier of Particle Physics

The reviewed paper, authored by J. Jaeckel and A. Ringwald, presents a comprehensive analysis of the low-energy frontier of particle physics, focusing on the potential existence and implications of very weakly interacting sub-eV particles (WISPs). The exploration centers around the hypothesis that extensions of the Standard Model, notably those embedded into supergravity and string theory frameworks, predict the presence of hidden sector particles marginally interacting with the visible sector, suggesting a rich low-energy phenomenology that could provide insights into fundamental physics.

Key Concepts and Context

Acknowledging the precedent set by the high-energy exploration at facilities like the Large Hadron Collider (LHC), the paper pivots to the less examined low-energy domain, where WISPs are hypothesized to exist. These particles, which exhibit interactions weaker than those described by the Standard Model, include candidates such as axions, axion-like particles (ALPs), and hidden U(1) gauge bosons—each arising naturally in various theoretical frameworks like string compactifications.

A significant portion of the discourse is dedicated to axions and ALPs, both linked to the resolution of the strong CP problem inherent in quantum chromodynamics (QCD). Axions, posited as a solution via the Peccei-Quinn symmetry, present detectable effects despite their inherently weak interactions, proposing a pivotal experimental challenge and opportunity.

Astrophysical and Cosmological Constraints

A substantial body of the paper reviews astrophysical and cosmological constraints on WISPs, relying on observations that rule out or support their existence without invoking strong interactions observable in colliders. Constraints from stellar evolution provide stringent bounds due to the increased energy loss rates induced by WISP production in stellar interiors. For axions, observational evidence from white dwarfs and the neutrino burst from SN1987A offer pivotal insights. Furthermore, Big Bang Nucleosynthesis (BBN) constrains the thermalization of WISPs during key phases of the universe’s evolution.

Observations from the Cosmic Microwave Background (CMB) further restrict the impacts WISPs could have had on historical cosmic radiation, defining an upper limit on their abundance and interaction rates. The paper highlights that upcoming observational data should refine these constraints, potentially tightening them.

Experimental Searches and Implications

The discourse progresses to groundbreaking implications of potential WISP detection through laboratory experiments. The methodologies probed include light-shining-through-a-wall (LSW) experiments, laser polarization experiments, and the strong electromagnetic field exploitation in vacuum environments. These experiments, particularly LSW, where photons oscillate into WISPs and back, represent an innovative means to probe WISPs’ elusive interactions.

Enhancements in experimental design, including the employment of optical cavities to refine signal detection, underscore the intersection of theoretical aspirations with tangible investigational advancements. Notably, direct searches for axion dark matter establish a link between theoretical particle candidates and cosmological phenomena.

Conclusion and Future Prospects

The paper by Jaeckel and Ringwald highlights a compelling domain of inquiry within particle physics—one where low-energy phenomena may reveal new physics beyond the Standard Model. This exploration not only offers a path to address existing cosmological puzzles but also beckons the scientific community to harness and innovate experimental techniques that sharpen the sensitivity to these potential signals.

As experimental techniques advance and astrophysical observations grow increasingly precise, the pursuit of understanding WISPs stands as a testament to the synergy of theoretical predictions with empirical exploration. Continued investigations may not only substantiate the existence of WISPs but also enhance our understanding of the universe’s fundamental forces, drawing from insights at both the high and low-energy fronts.