Unveiling the Graviton Mass Bounds through Analysis of 2023 Pulsar Timing Array Data Releases

TL;DR

This paper sets new upper limits on the graviton mass using 2023 pulsar timing array data, providing the most stringent constraints to date and discussing implications for ultralight tensor dark matter.

Contribution

It introduces state-of-the-art graviton mass bounds from recent PTA data and analyzes cosmic-variance limits, advancing the understanding of gravitational wave properties.

Findings

Upper limit on graviton mass from NANOGrav data: 8.6×10⁻²⁴ eV

Upper limit from CPTA data: 3.8×10⁻²³ eV

Cosmic-variance limit on graviton mass: 4.8×10⁻²⁴ eV at 10-year observation

Abstract

Strong evidence for the Helling-Downs correlation curves have been reported by multiple pulsar timing array (PTA) collaborations in middle 2023. In this work, we investigate the graviton mass bounds by analyzing the observational data of the overlap ruduction functions from the NANOGrav 15-year data release and CPTA first data release. The results from our data analysis display the state-of-the-art upper limits on the graviton mass at 90\% confidence level, namely, $m_{g}\lesssim8.6\times10^{-24}\mathrm{eV}$ from NANOGrav and $m_{g}\lesssim3.8\times10^{-23}\mathrm{eV}$ from CPTA. We also study the cosmic-variance limit on the graviton mass bounds, i.e., $\sigma_{m_{g}}^{\mathrm{CV}}=4.8\times10^{-24}\mathrm{eV}\times f/(10~\mathrm{year})^{-1}$, with $f$ being a typical frequency band of PTA observations. This is equivalent to the cosmic-variance limit on the speed of gravitational waves, i.e., $\sigma_{v_{g}}^{\mathrm{CV}}=0.07c$, with $c$ being the speed of light. Moreover, we discuss potential implications of these results for scenarios of ultralight tensor dark matter.