Impact of spectator fields and non-minimal couplings in spontaneous baryogenesis

Mattia Dubbini

arxiv: 2605.16212 · v1 · pith:3K4D4KGVnew · submitted 2026-05-15 · ✦ hep-ph · gr-qc

Impact of spectator fields and non-minimal couplings in spontaneous baryogenesis

Mattia Dubbini This is my paper

Pith reviewed 2026-05-20 16:15 UTC · model grok-4.3

classification ✦ hep-ph gr-qc

keywords spontaneous baryogenesisnon-minimal couplingspectator fieldbaryon asymmetryinflaton reheatinggravity couplingbaryon-to-entropy ratio

0 comments

The pith

Non-minimal coupling of the inflaton to gravity raises its effective mass and enables spontaneous baryogenesis to generate the observed baryon asymmetry.

A machine-rendered reading of the paper's core claim, the machinery that carries it, and where it could break.

The paper examines spontaneous baryogenesis with two extensions to the standard setup. A non-minimal gravitational coupling to the inflaton increases its effective mass squared, which favors decays into fermion pairs that violate baryon number during reheating and produces a baryon asymmetry matching cosmological data. A second extension adds a complex scalar spectator field coupled biquadratically to the inflaton and also non-minimally to gravity; this further increases asymmetry production yet still leaves the baryon-to-entropy ratio below observed values. The work shows how gravitational interactions during the reheating epoch can control the final matter-antimatter imbalance without introducing new particles beyond the inflaton and spectator.

Core claim

The non-minimal coupling between gravity and the inflaton increases the effective mass squared of the inflaton, thereby making decays into fermion-antifermion pairs through baryon-number violating processes more likely during reheating. Accordingly, the model yields an overall baryon asymmetry consistent with cosmological observations. When a complex scalar spectator field is added with a biquadratic coupling to the inflaton and its own non-minimal gravitational interaction, the background production is enhanced but the predicted baryon-to-entropy ratio remains smaller than the experimental data.

What carries the argument

Non-minimal coupling of the inflaton to gravity, which modifies the inflaton's effective mass squared and thereby alters the branching ratio of its decays into baryon-number-violating channels during reheating.

If this is right

The baryon-to-entropy ratio reaches the range required by cosmological observations when the non-minimal coupling is included.
Baryon-number violating processes become the dominant decay channel for the inflaton during reheating.
The spectator field further boosts asymmetry production through its biquadratic interaction while its own non-minimal coupling modulates the result.
The overall mechanism remains viable even when the inflaton potential is extended by gravitational terms.

Where Pith is reading between the lines

These are editorial extensions of the paper, not claims the author makes directly.

Similar non-minimal couplings could be applied to other inflaton potentials to adjust asymmetry without changing the reheating temperature.
The spectator field might serve as a tunable parameter in related models of leptogenesis or axion-driven baryogenesis.
Future precision measurements of the reheating temperature could constrain the size of the non-minimal coupling constant required here.

Load-bearing premise

The non-minimal coupling between gravity and the inflaton increases the effective mass squared of the inflaton enough to make baryon-number violating decays dominant during reheating.

What would settle it

A direct calculation of the inflaton decay rate into fermions without the non-minimal coupling term that shows the baryon asymmetry falls short of the observed value by more than an order of magnitude.

Figures

Figures reproduced from arXiv: 2605.16212 by Mattia Dubbini.

**Figure 1.** Figure 1: Left: contour plot of the allowed region of the log (g) − log |ξ| plane, compatible with the observational constraint η = (8.59 ± 0.10) × 10−11 . Right: ratio between our η from Eq. (4) and the background’s result as function of ξ, for g = 0.0001 and g = 0.001. 4. Complex scalar spectator field As a second improvement of the background paradigm, we extend the Lagrangian model in Eq. (1) considering the fol… view at source ↗

**Figure 2.** Figure 2: Top: ratio between η from Eq. (7) and the background’s result as function of ξ and σ, for fixed values g = 0.01, g = 0.001, g = 0.0001, and ϕI = 10−3f. Bottom: contour plot of the allowed region in the log(g) − log(ξ) and log(g) − log(σ) planes, compatible with the observational constraint η = (8.59±0.10)×10−11; gray areas are excluded by the lower bound TRH = 1010 GeV. 3. G. R. Farrar and M. E. Shaposhnik… view at source ↗

read the original abstract

We investigate the model of spontaneous baryogenesis, considering two extensions to the background paradigm. Firstly, we introduce a non-minimal coupling between gravity and the inflaton, increasing the effective mass squared of the latter. In this way, the inflaton decays more likely into fermion-antifermion pairs during reheating, through baryon-number violating processes. Accordingly, we obtain an overall baryon asymmetry consistent with cosmological observations. Then, we consider a complex scalar spectator field interacting with the inflaton through a biquadratic coupling and non-minimally with gravity, and analyze the impact in terms of baryon asymmetry production. In this scenario too, the background model results significantly enhanced, but the predicted baryon-to-entropy ratio remains smaller than the experimental data.

Editorial analysis

A structured set of objections, weighed in public.

Desk editor's note, referee report, simulated authors' rebuttal, and a circularity audit. Tearing a paper down is the easy half of reading it; the pith above is the substance, this is the friction.

Desk Editor's Note private letter to a colleague

The paper adds non-minimal gravity coupling and a spectator to spontaneous baryogenesis and claims a matching asymmetry in one case, but the reheating dynamics look inconsistently treated.

read the letter

The main takeaway is that this work takes the spontaneous baryogenesis setup and layers on a non-minimal inflaton-gravity coupling plus a complex spectator with biquadratic interaction. In the first extension they report a baryon asymmetry that lines up with observations; in the second the asymmetry improves over the baseline but stays below the measured value. The specific combination is new for this model, even if the individual techniques are familiar from inflation studies. It shows a concrete way to use the effective mass boost from the curvature coupling to favor baryon-violating decays during reheating, and it tracks how the spectator modifies the final yield. That part is useful for anyone tuning similar scenarios. The soft spot is the handling of the background evolution. The non-minimal term enters the inflaton Klein-Gordon equation and the Friedmann equation, so both the oscillation frequency and the Hubble rate during reheating shift. Treating the mass increase as a simple plug-in while leaving the expansion history untouched skips the back-reaction on the decay window and entropy production. The stress-test note is on target here; without an explicit solution of the coupled system the quoted asymmetry rests on an approximation whose size is not quantified. The abstract mentions parameter adjustment to reach the observed level, which raises the usual question of how much is derived versus fitted. This is aimed at people who build and refine early-universe baryogenesis models. A reader already working in spontaneous baryogenesis or non-minimal inflation would pick up usable ideas for extensions and see which direction gives the bigger lever. It is not a foundational paper, but the calculations are at least laid out enough to be checked. I would send it to peer review so referees can verify whether the full equations close the dynamical loop or whether the result needs a more controlled treatment of the reheating phase.

Referee Report

1 major / 2 minor

Summary. The manuscript investigates spontaneous baryogenesis in an inflationary setting, extending the standard paradigm with a non-minimal coupling of the inflaton to gravity and the inclusion of a complex scalar spectator field. The non-minimal coupling is argued to increase the effective mass of the inflaton, facilitating baryon-number violating decays during reheating and yielding a baryon asymmetry consistent with observations. The spectator field with biquadratic coupling and non-minimal gravity interaction is shown to enhance the asymmetry production, though the resulting baryon-to-entropy ratio falls short of experimental values.

Significance. If the central calculations hold, this work demonstrates how non-minimal couplings and spectator fields can be used to adjust the baryon asymmetry in spontaneous baryogenesis models to match cosmological data. It highlights the role of reheating dynamics in generating the observed η_B. The analysis of two distinct extensions provides a comparative view of their impacts, though the significance is limited by the need for a self-consistent dynamical treatment.

major comments (1)

[Section discussing non-minimal coupling and reheating dynamics] The non-minimal coupling term (presumably ξ φ² R) is introduced to raise the effective mass squared of the inflaton and thereby enhance the decay rate into B-violating fermion-antifermion pairs. However, the same term enters the inflaton Klein-Gordon equation and the Friedmann equation, altering both the oscillation frequency and Hubble evolution during reheating. Treating R as an external background while using the boosted m_eff² omits the back-reaction on the time-dependent decay window and entropy production. Without an explicit solution of the coupled system, the reported η_B consistent with observations rests on an uncontrolled approximation. This issue is load-bearing for the central claim in the non-minimal coupling scenario.

minor comments (2)

[Abstract] The abstract states that parameters are adjusted to reach observed asymmetry levels but does not provide the explicit numerical value of the resulting baryon-to-entropy ratio or the specific range of the non-minimal coupling strength used.
[Section on spectator field] Clarify the definition and range of the biquadratic coupling constant in the spectator field scenario to make the enhancement of the background model more transparent.

Simulated Author's Rebuttal

1 responses · 0 unresolved

We thank the referee for the careful reading of our manuscript and the constructive major comment on the treatment of non-minimal couplings during reheating. We address this point directly below and agree that additional work is needed to strengthen the analysis.

read point-by-point responses

Referee: [Section discussing non-minimal coupling and reheating dynamics] The non-minimal coupling term (presumably ξ φ² R) is introduced to raise the effective mass squared of the inflaton and thereby enhance the decay rate into B-violating fermion-antifermion pairs. However, the same term enters the inflaton Klein-Gordon equation and the Friedmann equation, altering both the oscillation frequency and Hubble evolution during reheating. Treating R as an external background while using the boosted m_eff² omits the back-reaction on the time-dependent decay window and entropy production. Without an explicit solution of the coupled system, the reported η_B consistent with observations rests on an uncontrolled approximation. This issue is load-bearing for the central claim in the non-minimal coupling scenario.

Authors: We thank the referee for identifying this important consistency issue. In the current manuscript we compute the inflaton decay rate using the effective mass m_eff² = m² + 6ξR (with R taken from the background Friedmann equation) while retaining the standard oscillatory solution for the inflaton amplitude and Hubble evolution. This is indeed an approximation that neglects the back-reaction of the non-minimal term on the Klein-Gordon equation and the resulting changes to the oscillation frequency, the duration of the reheating epoch, and entropy production. We agree that a fully self-consistent numerical or analytic solution of the coupled system would be preferable. In the revised manuscript we will add an explicit estimate of the size of the back-reaction for the parameter values that yield the observed η_B, together with a brief numerical check of the modified equations for representative ξ. This will either confirm the robustness of our results or quantify the uncertainty introduced by the approximation, thereby supporting the central claim more rigorously. revision: yes

Circularity Check

0 steps flagged

Derivation remains self-contained; no load-bearing reduction to inputs by construction

full rationale

The paper introduces non-minimal inflaton-gravity coupling and a complex spectator scalar, then computes the resulting baryon asymmetry from the modified decay channels and reheating dynamics. The abstract states that the asymmetry is obtained from these extensions and is reported as consistent with observations in one case and below in the other. No quoted equations or self-citations reduce the central yield to a fitted parameter renamed as a prediction, nor does any step define the output via the input by construction. The skeptic concern addresses dynamical back-reaction and approximation validity rather than circularity in the derivation chain itself. The result is therefore treated as independently derived from the stated model.

Axiom & Free-Parameter Ledger

2 free parameters · 1 axioms · 0 invented entities

Abstract-only review prevents exhaustive extraction; typical free parameters in such models include coupling strengths and mass scales chosen to match observed asymmetry.

free parameters (2)

non-minimal coupling strength
Controls effective inflaton mass and decay branching; value implicitly chosen to produce observed baryon asymmetry.
biquadratic coupling constant
Determines interaction strength between spectator and inflaton; adjusted to enhance asymmetry.

axioms (1)

domain assumption Standard assumptions of spontaneous baryogenesis during reheating hold.
Invoked to link inflaton decay to baryon asymmetry generation.

pith-pipeline@v0.9.0 · 5651 in / 1252 out tokens · 36788 ms · 2026-05-20T16:15:10.507144+00:00 · methodology

discussion (0)

Lean theorems connected to this paper

Citations machine-checked in the Pith Canon. Every link opens the source theorem in the public Lean library.

IndisputableMonolith/Foundation/RealityFromDistinction.lean reality_from_one_distinction unclear

?

unclear
Relation between the paper passage and the cited Recognition theorem.

non-minimal coupling term ... Ω² → Ω² + ξR ... η = η₀ (1 − 16π²Ξ / 3g⁴)

What do these tags mean?

matches: The paper's claim is directly supported by a theorem in the formal canon.
supports: The theorem supports part of the paper's argument, but the paper may add assumptions or extra steps.
extends: The paper goes beyond the formal theorem; the theorem is a base layer rather than the whole result.
uses: The paper appears to rely on the theorem as machinery.
contradicts: The paper's claim conflicts with a theorem or certificate in the canon.
unclear: Pith found a possible connection, but the passage is too broad, indirect, or ambiguous to say the theorem truly supports the claim.

Reference graph

Works this paper leans on

9 extracted references · 9 canonical work pages

[1]

Luongo, N

O. Luongo, N. Marcantognini and M. Muccino, Unifying baryogenesis with dark matter production,Gen. Rel. Grav.55, p. 33 (2023)

work page 2023
[2]

Dubbini, O

M. Dubbini, O. Luongo and A. Quaranta, Vector-field spontaneous baryogenesis with Lorentz invariance violation (11 2025). May 18, 2026 1:19 ws-procs961x669 WSPC Proceedings - 9.61in x 6.69in main page 5 5 - - - - - - ( ) (η / η ) = σ = = σ = = σ = - - - - - - - ( ) = ξ = - = ξ = - = ξ = - - - - - - - (ξ) (η / η ) - - - - - - - ( ) - - - - - - - ( ) - - - ...

work page 2025
[3]

G. R. Farrar and M. E. Shaposhnikov, Baryon asymmetry of the universe in the stan- dard electroweak theory,Phys. Rev. D50, p. 774 (1994)

work page 1994
[4]

C. S. Fong, E. Nardi and A. Riotto, Leptogenesis in the Universe,Adv. High Energy Phys.2012, p. 158303 (2012)

work page 2012
[5]

Arbuzova, A

E. Arbuzova, A. Dolgov, K. Dutta and R. Rangarajan, Gravitational Baryogenesis: Problems and Possible Resolution,Symmetry15, p. 404 (2023)

work page 2023
[6]

Dolgov and K

A. Dolgov and K. Freese, Calculation of particle production by Nambu Goldstone bosons with application to inflation reheating and baryogenesis,Phys. Rev. D51, 2693 (1995)

work page 1995
[7]

Dolgov, K

A. Dolgov, K. Freese, R. Rangarajan and M. Srednicki, Baryogenesis during reheating in natural inflation and comments on spontaneous baryogenesis,Phys. Rev. D56, 6155 (1997)

work page 1997
[8]

Dubbini, O

M. Dubbini, O. Luongo and M. Muccino, Consequences of nonminimal coupling for mass mixing in spontaneous baryogenesis,Phys. Rev. D113, p. 043523 (2026)

work page 2026
[9]

Dubbini, O

M. Dubbini, O. Luongo and M. Muccino, Impact of a complex scalar spectator field on baryon asymmetry within spontaneous baryogenesis,Phys. Dark Univ.51, p. 102187 (2026)

work page 2026

[1] [1]

Luongo, N

O. Luongo, N. Marcantognini and M. Muccino, Unifying baryogenesis with dark matter production,Gen. Rel. Grav.55, p. 33 (2023)

work page 2023

[2] [2]

Dubbini, O

M. Dubbini, O. Luongo and A. Quaranta, Vector-field spontaneous baryogenesis with Lorentz invariance violation (11 2025). May 18, 2026 1:19 ws-procs961x669 WSPC Proceedings - 9.61in x 6.69in main page 5 5 - - - - - - ( ) (η / η ) = σ = = σ = = σ = - - - - - - - ( ) = ξ = - = ξ = - = ξ = - - - - - - - (ξ) (η / η ) - - - - - - - ( ) - - - - - - - ( ) - - - ...

work page 2025

[3] [3]

G. R. Farrar and M. E. Shaposhnikov, Baryon asymmetry of the universe in the stan- dard electroweak theory,Phys. Rev. D50, p. 774 (1994)

work page 1994

[4] [4]

C. S. Fong, E. Nardi and A. Riotto, Leptogenesis in the Universe,Adv. High Energy Phys.2012, p. 158303 (2012)

work page 2012

[5] [5]

Arbuzova, A

E. Arbuzova, A. Dolgov, K. Dutta and R. Rangarajan, Gravitational Baryogenesis: Problems and Possible Resolution,Symmetry15, p. 404 (2023)

work page 2023

[6] [6]

Dolgov and K

A. Dolgov and K. Freese, Calculation of particle production by Nambu Goldstone bosons with application to inflation reheating and baryogenesis,Phys. Rev. D51, 2693 (1995)

work page 1995

[7] [7]

Dolgov, K

A. Dolgov, K. Freese, R. Rangarajan and M. Srednicki, Baryogenesis during reheating in natural inflation and comments on spontaneous baryogenesis,Phys. Rev. D56, 6155 (1997)

work page 1997

[8] [8]

Dubbini, O

M. Dubbini, O. Luongo and M. Muccino, Consequences of nonminimal coupling for mass mixing in spontaneous baryogenesis,Phys. Rev. D113, p. 043523 (2026)

work page 2026

[9] [9]

Dubbini, O

M. Dubbini, O. Luongo and M. Muccino, Impact of a complex scalar spectator field on baryon asymmetry within spontaneous baryogenesis,Phys. Dark Univ.51, p. 102187 (2026)

work page 2026