Edward Hardy

Bracketing the soliton-halo relation of ultralight dark matter

(2025)

Authors:

Kfir Blum, Marco Gorghetto, Edward Hardy, Luca Teodori

Supernova bounds on new scalars from resonant and soft emission

Journal of High Energy Physics Springer 2025:4 (2025) 13

Authors:

Edward Hardy, Anton Sokolov, Henry Stubbs

Abstract:

We study supernova cooling constraints on new light scalars that mix with the Higgs, couple only to nucleons, or couple only to leptons. We show that in all these cases scalars with masses smaller than the plasma frequency in the supernova core are efficiently produced by resonant mixing with the in-medium longitudinal degree of freedom of the photon. The resulting bounds are free from uncertainties associated to the rate of emission of the scalar in nucleon-nucleon scatterings, which would otherwise badly affect the Higgs-mixed and nucleophilic scenarios. Heavier scalars that mix with the Higgs or couple only to nucleons are mostly produced by nucleon bremsstrahlung, and we obtain a conservative approximation for the corresponding rate using a soft theorem. We also analyse the impact of different supernova profiles, nucleon degeneracy, trapping and scalar decays on the constraints.

Searching for a dark matter induced galactic axion gradient

Physical Review D American Physical Society (APS) 111:1 (2025) 015006

Authors:

Edward Hardy, Mario Reig, Juri Smirnov

Searching for heavy millicharged particles from the atmosphere

Physical Review D American Physical Society (APS) 110:11 (2024) 115037

Authors:

Han Wu, Edward Hardy, Ningqiang Song

Percolating cosmic string networks from kination

Physical Review D: Particles, Fields, Gravitation and Cosmology American Physical Society 110 (2024) 083537

Authors:

Joseph Conlon, EJ Copeland, Edward Hardy, Noelia Sánchez González

Abstract:

We describe a new mechanism, whose ingredients are realised in string compactifications, for the formation of cosmic (super)string networks. Oscillating string loops grow when their tension µ decreases with time. If 2H + ˙µ/µ < 0, where H is the Hubble parameter, loops grow faster than the scale factor and an initial population of isolated small loops (for example, produced by nucleation) can grow, percolate and form a network. This condition is satisfied for fundamental strings in the background of a kinating volume modulus rolling towards the asymptotic large volume region of moduli space. Such long kination epochs are motivated in string cosmology by both the electroweak hierarchy problem and the need to solve the overshoot problem. The tension of such a network today is set by the final vacuum; for phenomenologically appealing Large Volume Scenario (LVS) vacua, this would lead to a fundamental string network with Gµ ∼ 10−10.