Chirp mass explained
In astrophysics, the chirp mass of a compact binary system determines the leading-order orbital evolution of the system as a result of energy loss from emitting gravitational waves. Because the gravitational wave frequency is determined by orbital frequency, the chirp mass also determines the frequency evolution of the gravitational wave signal emitted during a binary's inspiral phase. In gravitational wave data analysis, it is easier to measure the chirp mass than the two component masses alone.
Definition from component masses
A two-body system with component masses
and
has a chirp mass of
[1] [2] [3] The chirp mass may also be expressed in terms of the total mass of the system
and other common mass parameters:
:
:
or
:
The symmetric mass ratio reaches its maximum value
when
, and thus
- the geometric mean of the component masses
:
l{M}=m\rm\left(
\right)1/5,
If the two component masses are roughly similar, then the latter factor is close to
so
. This multiplier decreases for unequal component masses but quite slowly. E.g. for a 3:1 mass ratio it becomes
, while for a 10:1 mass ratio it is
Orbital evolution
In general relativity, the phase evolution of a binary orbit can be computed using a post-Newtonian expansion, a perturbative expansion in powers of the orbital velocity
. The first order gravitational wave frequency,
, evolution is described by the
differential equation
}\right)^f^,
[1] where
and
are the
speed of light and
Newton's gravitational constant, respectively.
If one is able to measure both the frequency
and frequency derivative
of a gravitational wave signal, the chirp mass can be determined.
[4] [5] To disentangle the individual component masses in the system one must additionally measure higher order terms in the post-Newtonian expansion.[1]
Mass-redshift degeneracy
One limitation of the chirp mass is that it is affected by redshift; what is actually derived from the observed gravitational waveform is the product
where
is the redshift.
[6] [7] This redshifted chirp mass is larger than the source chirp mass, and can only be converted to a source chirp mass by finding the redshift
.
This is usually resolved by using the observed amplitude to find the chirp mass divided by distance, and solving both equations using Hubble's law to compute the relationship between distance and redshift.
Xian Chen has pointed out that this assumes non-cosmological redshifts (peculiar velocity and gravitational redshift) are negligible, and questions this assumption.[8] [9] If a binary pair of stellar-mass black holes merge while closely orbiting a supermassive black hole (an extreme mass ratio inspiral), the observed gravitational wave would experience significant gravitational and doppler redshift, leading to a falsely low redshift estimate, and therefore a falsely high mass. He suggests that there are plausible reasons to suspect that the SMBH's accretion disc and tidal forces would enhance the merger rate of black hole binaries near it, and the consequent falsely high mass estimates would explain the unexpectedly large masses of observed black hole mergers. (The question would be best resolved by a lower-frequency gravitational wave detector such as LISA which could observe the extreme mass ratio inspiral waveform.)
See also
Notes and References
- Gravitational waves from merging compact binaries: How accurately can one extract the binary's parameters from the inspiral waveform? . Curt . Cutler . Éanna E. . Flanagan . Physical Review D . 49 . 6 . 2658–2697 . 15 March 1994 . 10.1103/PhysRevD.49.2658 . 10017261 . gr-qc/9402014 . 1994PhRvD..49.2658C. 5808548 .
- L. Blanchet . T. Damour . B. R. Iyer . C. M. Will . A. G. Wiseman . Phys. Rev. Lett. . 74 . 18 . 1 May 1995 . Gravitational-Radiation Damping of Compact Binary Systems to Second Post-Newtonian order . 10.1103/PhysRevLett.74.3515 . 10058225 . gr-qc/9501027 . 1995PhRvL..74.3515B . 3515–3518 . 14265300 .
- Luc . Blanchet . Bala R. . Iyerddag . Clifford M. . Will . Alan G. . Wiseman . Classical and Quantum Gravity . 13 . 4 . April 1996 . 10.1088/0264-9381/13/4/002 . gr-qc/9602024 . Gravitational waveforms from inspiralling compact binaries to second-post-Newtonian order . 1996CQGra..13..575B . 575–584. 14677428 .
- Properties of the Binary Black Hole Merger GW150914 . B. P. . Abbott . LIGO Scientific Collaboration and Virgo Collaboration . Physical Review Letters . 2016 . 116 . 24 . 241102 . 10.1103/PhysRevLett.116.241102 . 27367378 . 2016PhRvL.116x1102A . 1602.03840. 217406416 .
- Properties of the binary neutron star merger GW170817 . B. P. . Abbott . Physical Review X . LIGO Scientific Collaboration and Virgo Collaboration . 2019 . 9 . 1 . 011001 . 10.1103/PhysRevX.9.011001 . 2019PhRvX...9a1001A . 1805.11579. 106401868 .
- 25 September 1986 . Determining the Hubble constant from gravitational wave observations . Bernard F. . Schutz . Nature . 323 . 6086 . 310–311 . 10.1038/323310a0 . 1986Natur.323..310S. 11858/00-001M-0000-0013-73C1-2. 4327285 . free.
- Source Redshifts from Gravitational-Wave Observations of Binary Neutron Star Mergers . Chris . Messenger . Kentaro . Takami . Sarah . Gossan . Luciano . Rezzolla . B. S. . Sathyaprakash . . 4 . 4 . 041004 . 8 October 2014 . 10.1103/PhysRevX.4.041004 . free . 1312.1862 . 2014PhRvX...4d1004M .
- Mass-redshift degeneracy for the gravitational-wave sources in the vicinity of supermassive black holes . Xian . Chen . Shuo . Li . Zhoujian . Cao . . 485 . 1 . L141–L145 . May 2019 . 10.1093/mnrasl/slz046 . free . 1703.10543 . 2019MNRAS.485L.141C .
- Book: Chen
, Xian . Handbook of Gravitational Wave Astronomy . Distortion of Gravitational-Wave Signals by Astrophysical Environments . 2021 . 1–22 . 2009.07626 . 10.1007/978-981-15-4702-7_39-1 . 978-981-15-4702-7 . 221739217 .