LISA test-mass charging. Particle flux modeling, Monte Carlo simulations and induced effects on the sensitivity of the observatory

TL;DR

This paper models the particle flux and charge accumulation on LISA's test masses using Monte Carlo simulations to assess how these effects impact the observatory's sensitivity to gravitational waves.

Contribution

It introduces a comprehensive toolkit for predicting test mass charging and induced forces, aiding in the design of counter-measures for space missions like LISA.

Findings

Charge fluctuations can produce noise forces affecting LISA's sensitivity.

Different space environment conditions influence the magnitude of charging effects.

The toolkit enables accurate prediction of charge-induced disturbances.

Abstract

Context. The LISA space observatory will explore the sub-Hz spectrum of gravitational wave emission from the Universe. The space environment, where will be immersed in, is responsible for charge accumulation on its free falling test masses (TMs) due to the galactic cosmic rays (GCRs) and solar energetic particles (SEP) impinging on the spacecraft. Primary and secondary particles produced in the spacecraft material eventually reach the TMs by depositing a net positive charge fluctuating in time. This work is relevant for any present and future space missions that, like LISA, host free-falling TMs as inertial reference. Aims. The coupling of the TM charge with native stray electrostatic field produces noise forces on the TMs, which can limit the performance of the LISA mission. A precise knowledge of the charging process allows us to predict the intensity of these charge-induced disturbances and to design specific counter-measures. Methods. We present a comprehensive toolkit that allows us to calculate the TM charging time-series in a geometry representative of LISA mission, and the associated induced forces under different conditions of the space environment by considering the effects of short, long GCR flux modulations and SEPs. Results. We study, for each of the previously mentioned conditions, the impact of spurious forces associated with the TM charging process on the mission sensitivity for gravitational wave detection.