Probing standard model-like di-Higgs production at photon-photon colliders in the I(1+2)HDM Type-I
Probing standard model-like di-Higgs production at photon-photon colliders in the I(1+2)HDM Type-I
In this paper, pair production of Standard Model (SM)-like Higgs bosons, hh, is studied through γγ scattering at future electron-positron colliders, in the framework of the Inert Doublet Model with two Active Doublets, i.e., the I(1+2)HDM for short. The relevance of the process γγ → hh for such a Beyond the SM (BSM) scenario stems from the fact that it is a one-loop process at lowest order, wherein inert charged states χ± contribute alongside with W±, H± and heavy fermions (primarily, bottom and top quarks), crucially, at the same perturbative order. Given that χ±/H± masses and hS+S− (S± = χ±, H±) couplings are very mildly constrained, there exist regions of the parameter space of the I(1+2)HDM where the former can be rather light and the latter rather large. After imposing up-to-date theoretical and experimental constraints on the I(1+2)HDM, it is found that the production rates of such process at future γγ machines can be enhanced up to a factor of ≈ 50 with respect to the SM, significantly exceeding typical yields of conventional 2-Higgs Doublet Models (2HDMs).Further, thanks to the level of control that one can attain at such facilities on the photon kinematics, leading to excellent invariant mass resolution of the incoming photon pairs, we show how it is possible to extract from this process the value of the χ± mass (along that of the active H± states) with high precision, whichever the decays of the hh pair, both with and without beam polarization.
hep-ph
Arhrib, Abdesslam
372178a6-f7a9-43ba-ad54-e4a025135fbe
Hmissou, Ayoub
e60e6785-d847-4960-8693-63226addb8db
Moretti, Stefano
b57cf0f0-4bc3-4e02-96e3-071255366614
Rahili, Larbi
7b67b916-b30f-481f-84f2-6015f93dd252
Arhrib, Abdesslam
372178a6-f7a9-43ba-ad54-e4a025135fbe
Hmissou, Ayoub
e60e6785-d847-4960-8693-63226addb8db
Moretti, Stefano
b57cf0f0-4bc3-4e02-96e3-071255366614
Rahili, Larbi
7b67b916-b30f-481f-84f2-6015f93dd252
[Unknown type: UNSPECIFIED]
Abstract
In this paper, pair production of Standard Model (SM)-like Higgs bosons, hh, is studied through γγ scattering at future electron-positron colliders, in the framework of the Inert Doublet Model with two Active Doublets, i.e., the I(1+2)HDM for short. The relevance of the process γγ → hh for such a Beyond the SM (BSM) scenario stems from the fact that it is a one-loop process at lowest order, wherein inert charged states χ± contribute alongside with W±, H± and heavy fermions (primarily, bottom and top quarks), crucially, at the same perturbative order. Given that χ±/H± masses and hS+S− (S± = χ±, H±) couplings are very mildly constrained, there exist regions of the parameter space of the I(1+2)HDM where the former can be rather light and the latter rather large. After imposing up-to-date theoretical and experimental constraints on the I(1+2)HDM, it is found that the production rates of such process at future γγ machines can be enhanced up to a factor of ≈ 50 with respect to the SM, significantly exceeding typical yields of conventional 2-Higgs Doublet Models (2HDMs).Further, thanks to the level of control that one can attain at such facilities on the photon kinematics, leading to excellent invariant mass resolution of the incoming photon pairs, we show how it is possible to extract from this process the value of the χ± mass (along that of the active H± states) with high precision, whichever the decays of the hh pair, both with and without beam polarization.
Text
2511.03902v1
- Author's Original
Available under License Other.
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Accepted/In Press date: 5 November 2025
Additional Information:
24 pages, 9 figures, 3 tables
Keywords:
hep-ph
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Local EPrints ID: 508645
URI: http://eprints.soton.ac.uk/id/eprint/508645
PURE UUID: 6bc308f6-b46f-41b5-922c-59b02b7d25f8
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Date deposited: 28 Jan 2026 18:02
Last modified: 29 Jan 2026 02:55
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Author:
Abdesslam Arhrib
Author:
Ayoub Hmissou
Author:
Larbi Rahili
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