Addressing leakage and mode suppression in angular power spectrum estimation for gravitational-wave backgrounds using pulsar timing arrays

Abstract

Mapping gravitational-wave background (GWB) anisotropy with pulsar timing arrays (PTAs) is affected by harmonic-space mode suppression and mode coupling arising from an array's nonuniform sky response. Spherical harmonic expansions must be truncated at finite multipole lmaxrec, often set to lmaxNpair int[Npair-1], where Npair is the number of distinct pulsar pairs in an array. This choice is motivated by the counting argument that cross-correlations provide at most Npair independent constraints. We obtain the multipole lmaxres corresponding to the maximum informative angular scale of a PTA. It is defined such that expansions to lmaxres (approximately) span the space of "observable skies" encoded in the Npair eigenmaps of the Fisher information matrix, and therefore depends on the array configuration. We explicitly show that GWB power contained in multipoles lmaxres do not significantly affect analyses that use expansions out to lmaxres, because the PTA response acts as a low-pass filter. In contrast, truncating at lmaxrec< lmaxres leads to leakage of small-scale angular power from lmaxrec<l≤lmaxres. Even choosing lmaxrec=lmaxres, the standard frequentist estimator of the angular power spectrum Cl remains biased by the modes unobservable by the array. Although we can (partially) debias the standard estimator -- improving its agreement with an injected spectrum -- this reduction in bias comes at the expense of an increase in variance, particularly for poorly constrained modes with leff. We therefore recommend: (i) using lmaxres for PTA analyses involving spherical harmonic expansions, and (ii) using the debiased standard estimator for Cl recovery, but only out to multipoles l<leff (maxres) corresponding to sufficiently constrained modes.