Millimetre-wave emission from an intermediate-mass black hole candidate in the Milky Way

Abstract: It is widely accepted that black holes (BHs) with masses greater than a million solar masses (M ⊙ ) lurk at the centres of massive galaxies. The origins of such 'supermassive' black holes (SMBHs) remain unknown 1 , while those of stellar-mass BHs are well-understood. One possible scenario is that intermediate-mass black holes (IMBHs), which are formed by the runaway coalescence of stars in young compact star clusters 2 , merge at the centre of a galaxy to form an SMBH 3 . Although many candidates for IMBHs hav… Show more

“…This value is much smaller than that of their simulated cloud, with Msim = 10 3 M . In particular, in Oka et al (2017) the authors distribute their particles with a Gaussian radial mass distribution with dispersion of σr = 0.2 pc and internal velocity dispersion of σv = 1.43km s −1 , claiming that this leads to an initially virialized cloud. However, in this case, GMsim/σr ≈ 10σ 2 v , hence this setup is actually strongly subvirial.…”

“…3 A virial equilibrium would require a σv ≈ 5km s −1 . If the molecular gas has a temperature of 60 K, as estimated by Oka et al (2017), this means that the turbulence has a Mach number M ≈ 10, which is probably too high for clouds with that size (e.g., Larson 1981).…”

“…Nonetheless, the cloud size and its distance from the putative IMBH are of the same order. In this case, from a simple "Roche limit" argument, the self-gravity of the 1 22 arcsec = 0.9 pc (Oka et al 2017).…”

“…Detections of the upper end of the IMBH mass distribution have also been claimed for dwarf galaxies (see Kormendy & Ho 2013;Reines & Volonteri 2015;Mezcua 2017, and references therein). Tanaka et al (2014), Oka et al (2016) and Oka et al (2017) have reported the detection, by means of molecular emission lines, of a high velocity compact cloud, CO-0.40-0.22, with internal velocity gradient of several tens of km s −1 . In particular, through high resolution ALMA observations, Oka et al (2017) set its size, 1 pc, and its internal line of sight velocity, possibly ranging from -80 to -40 km s −1 with respect to us.…”

Weighing the IMBH candidate CO-0.40-0.22* in the Galactic Centre

“…This value is much smaller than that of their simulated cloud, with Msim = 10 3 M . In particular, in Oka et al (2017) the authors distribute their particles with a Gaussian radial mass distribution with dispersion of σr = 0.2 pc and internal velocity dispersion of σv = 1.43km s −1 , claiming that this leads to an initially virialized cloud. However, in this case, GMsim/σr ≈ 10σ 2 v , hence this setup is actually strongly subvirial.…”

“…3 A virial equilibrium would require a σv ≈ 5km s −1 . If the molecular gas has a temperature of 60 K, as estimated by Oka et al (2017), this means that the turbulence has a Mach number M ≈ 10, which is probably too high for clouds with that size (e.g., Larson 1981).…”

“…Nonetheless, the cloud size and its distance from the putative IMBH are of the same order. In this case, from a simple "Roche limit" argument, the self-gravity of the 1 22 arcsec = 0.9 pc (Oka et al 2017).…”

“…Detections of the upper end of the IMBH mass distribution have also been claimed for dwarf galaxies (see Kormendy & Ho 2013;Reines & Volonteri 2015;Mezcua 2017, and references therein). Tanaka et al (2014), Oka et al (2016) and Oka et al (2017) have reported the detection, by means of molecular emission lines, of a high velocity compact cloud, CO-0.40-0.22, with internal velocity gradient of several tens of km s −1 . In particular, through high resolution ALMA observations, Oka et al (2017) set its size, 1 pc, and its internal line of sight velocity, possibly ranging from -80 to -40 km s −1 with respect to us.…”

Weighing the IMBH candidate CO-0.40-0.22* in the Galactic Centre

“…On the one hand we have an observational BH process that ionizes neutral matter into charged particles resulting in transformation from visibility to invisibility and on the other we have an unknown invisible process that emits radio waves and neutral atomic and molecular matter from invisible to visible space, Donley et al (2002), Yale (2006), Tombesi et al (2015), Leroy et al (2015), Pan et al (2015), Das et al (2015), Dasyra et al (2015), Whitney (2015), Gallimore et al (2016), Sanders et al (2016), Oka et al (2017). Usually, the emission is through galactic nuclei, Richings and Faucher-Giguere (2018), however, off-nucleus evidences exist, Pinto et al (2016).…”

A Field Concept of the Black Hole

Aspects of GRMHD in high-energy astrophysics: geometrically thick disks and tori agglomerates around spinning black holes