The First-Order Velocity Memory Effect from Compact Binary Coalescing Sources

TL;DR

This paper reveals a new velocity memory effect caused by gravitational waves from binary mergers, which adds to the known displacement memory, and discusses its potential observability with LISA.

Contribution

It introduces the first-order velocity memory effect from compact binary coalescing sources, expanding understanding of gravitational wave memory phenomena.

Findings

Velocity memory effect exists alongside displacement memory.

Magnitude of velocity memory effect is significant for supermassive black hole mergers.

Potential detectability with LISA discussed.

Abstract

It has long been known that gravitational waves from compact binary coalescing sources are responsible for a first-order displacement memory effect experienced by a pair of freely falling test masses. This constant displacement is sourced from the non-vanishing final gravitational-wave strain present in the wave's after-zone, often referred to as the non-linear memory effect, and is of the same order of magnitude as the strain from the outgoing quadrupole radiation. Hence, this prediction of general relativity is verifiable experimentally by measurement of the final relative separation between test masses that comprise gravitational-wave detectors. In a separate context, independent calculations have demonstrated that exact, sandwich, plane wave spacetimes exhibit a velocity memory effect: a non-zero relative velocity, gained by a pair of test masses in free fall, after the passage of a gravitational wave. In this paper, we find that in addition to the known constant displacement memory effect test masses experience, a velocity memory effect at leading order arises due to the non-linear nature of gravitational waves from compact binary sources. We discuss the magnitude of the first-order velocity memory effect in the context of observing gravitational-wave radiation from super massive binary black hole mergers in LISA.