We study the dynamical evolution of eccentric massive black hole binaries (MBHBs) interacting with unbound stars by means of an extensive set of three-body scattering experiments. Compared to previous studies, we extend the investigation down to a MBHB massratio of q=m2/m1 =10−4,wherem1 andm2 arethemassesoftheprimaryandsecondary hole, respectively. Contrary to a simple extrapolation from higher mass ratios, we find that for q≲10−3theeccentricitygrowthratebecomesnegative,i.e.thebinarycircularizesasitshrinks. This behaviour is due to the subset of interacting stars captured in metastable counter-rotating orbits; those stars tend to extract angular momentum from the binary, promoting eccentricity growth for q > 10−3, but tend to inject angular momentum into the binary driving it towards circularization for q < 10−3. The physical origin of this behaviour requires a detailed study of the orbits of this subset of stars and is currently under investigation. Our findings might have important consequences for intermediate massive black holes (IMBHs) inspiralling on to MBHs (e.g. a putative 103 Mblack hole inspiralling on to Sgr A∗).

On the eccentricity evolution of massive black hole binaries in stellar backgrounds

Haardt, Francesco;
2020-01-01

Abstract

We study the dynamical evolution of eccentric massive black hole binaries (MBHBs) interacting with unbound stars by means of an extensive set of three-body scattering experiments. Compared to previous studies, we extend the investigation down to a MBHB massratio of q=m2/m1 =10−4,wherem1 andm2 arethemassesoftheprimaryandsecondary hole, respectively. Contrary to a simple extrapolation from higher mass ratios, we find that for q≲10−3theeccentricitygrowthratebecomesnegative,i.e.thebinarycircularizesasitshrinks. This behaviour is due to the subset of interacting stars captured in metastable counter-rotating orbits; those stars tend to extract angular momentum from the binary, promoting eccentricity growth for q > 10−3, but tend to inject angular momentum into the binary driving it towards circularization for q < 10−3. The physical origin of this behaviour requires a detailed study of the orbits of this subset of stars and is currently under investigation. Our findings might have important consequences for intermediate massive black holes (IMBHs) inspiralling on to MBHs (e.g. a putative 103 Mblack hole inspiralling on to Sgr A∗).
2020
black hole physics–gravitational waves–stars: kinematics and dynamicsgalaxies: nuclei
Rossi, Elena; Fragione, Giacomo; Arca , ; Sedda, Manuel; Leigh, Nathan W C; Haardt, Francesco; Dotti, Massimo; Sesana, Alberto; Rasskazov, Alexan...espandi
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11383/2087694
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