English

Testing strong-field gravity with tidal Love numbers

General Relativity and Quantum Cosmology 2017-04-13 v4 High Energy Astrophysical Phenomena High Energy Physics - Phenomenology High Energy Physics - Theory

Abstract

The tidal Love numbers (TLNs) encode the deformability of a self-gravitating object immersed in a tidal environment and depend significantly both on the object's internal structure and on the dynamics of the gravitational field. An intriguing result in classical general relativity is the vanishing of the TLNs of black holes. We extend this result in three ways, aiming at testing the nature of compact objects: (i) we compute the TLNs of exotic compact objects, including different families of boson stars, gravastars, wormholes, and other toy models for quantum corrections at the horizon scale. In the black-hole limit, we find a universal logarithmic dependence of the TLNs on the location of the surface; (ii) we compute the TLNs of black holes beyond vacuum general relativity, including Einstein-Maxwell, Brans-Dicke and Chern-Simons gravity; (iii) We assess the ability of present and future gravitational-wave detectors to measure the TLNs of these objects, including the first analysis of TLNs with LISA. Both LIGO, ET and LISA can impose interesting constraints on boson stars, while LISA is able to probe even extremely compact objects. We argue that the TLNs provide a smoking gun of new physics at the horizon scale, and that future gravitational-wave measurements of the TLNs in a binary inspiral provide a novel way to test black holes and general relativity in the strong-field regime.

Keywords

Cite

@article{arxiv.1701.01116,
  title  = {Testing strong-field gravity with tidal Love numbers},
  author = {Vitor Cardoso and Edgardo Franzin and Andrea Maselli and Paolo Pani and Guilherme Raposo},
  journal= {arXiv preprint arXiv:1701.01116},
  year   = {2017}
}

Comments

18 pages + appendices; 9 figures. v2: references updated and legend of Fig.7 corrected; v3: clarifications and improvements in the discussion; v4: minor changes to match the PRD version (selected as Editors' Suggestion)

R2 v1 2026-06-22T17:41:18.757Z