The Laser Interferometer Space Antenna (LISA) has the potential to reveal wonders about the fundamental theory of nature at play in the extreme gravity regime, where the gravitational interaction is both strong and dynamical. In this white paper, the Fundamental Physics Working Group of the LISA Consortium summarizes the current topics in fundamental physics where LISA observations of gravitational waves can be expected to provide key input. We provide the briefest of reviews to then delineate avenues for future research directions and to discuss connections between this working group, other working groups and the consortium work package teams. These connections must be developed for LISA to live up to its science potential in these areas.
We study the cosmological propagation of gravitational waves
(GWs) beyond general relativity (GR) across homogeneous and
isotropic backgrounds. We consider scenarios in which GWs interact
with an additional tensor field and use a parametrized
phenomenological approach that generically describes their coupled
equations of motion. We analyze four distinct classes of derivative
and non-derivative interactions: mass, friction, velocity, and
chiral. We apply the WKB formalism to account for the cosmological
evolution and obtain analytical solutions to these equations. We
corroborate these results by analyzing numerically the propagation
of a toy GW signal. We then proceed to use the analytical results to
study the modified propagation of realistic GWs from merging compact
binaries, assuming that the GW signal emitted is the same as in GR.
We generically find that tensor interactions lead to copies of the
originally emitted GW signal, each one with its own possibly
modified dispersion relation. These copies can travel coherently
and interfere with each other leading to a scrambled GW signal, or
propagate decoherently and lead to echoes arriving at different
times at the observer that could be misidentified as independent GW
events. Depending on the type of tensor interaction, the detected
GW signal may exhibit amplitude and phase distortions with respect
to a GW waveform in GR, as well as birefringence effects. We
discuss observational probes of these tensor interactions with both
individual GW events, as well as population studies for both ground-
and space-based detectors.
Low-energy alternatives to General Relativity (GR) generically modify the phase of gravitational waves (GWs) during their propagation.
As detector sensitivities increase, it becomes key to understand how these modifications affect the GW higher modes and to disentangle possible degeneracies with astrophysical phenomena.
We apply a general formalism — the WKB approach — for solving analytically wave propagation in the spatial domain with a modified dispersion relation (MDR).
We compare this WKB approach to applying a stationary phase approximation (SPA) in the temporal domain with time delays associated to the group or particle velocity.
To this end, we extend the SPA to generic signals with higher modes, keeping careful track of reference phases and arrival times.
We find that the WKB approach coincides with the SPA using the group velocity, in agreement with the principles of wave propagation.
We then explore the degeneracies between a GW propagation with an MDR and a strongly-lensed GW in GR, since the latter can introduce a frequency-independent phase shift which is not degenerate with source parameters in the presence of higher modes.
We find that for a particular MDR there is an exact degeneracy for wave propagation, unlike with the SPA for particle propagation.
For the other cases, we search for the values of the MDR parameters that minimize the χ2 and conclude that strongly-lensed GR GWs could be misinterpreted as GWs in modified gravity.
Future MDR constraints with higher mode GWs should include the possibility of frequency-independent phase shifts, allowing for the identification of modified gravity and strong lensing distortions at the same time.
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