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Special Colloquium |
Dr. Leonid Gurvits
| ORATED |
JIVE and TU Delft
In this impromptu presentation I will cover two VLBI topics pursued merely 240 km NW of Bonn. The first one deals with the initiative to build a next generation spaceborne VLBI system. I will start from a brief (and known to many in the audience) concept called TeraHertz Exploration and Zooming-in for Astrophysics (THEZA) as it stands now, five years after proposing it to ESA. I will then review a (much) scaled down version of THEZA called Black Hole Explorer (BHEX), also known to some people in the audience. BHEX is aiming to address a truly transformative science of the phenomenon of photon rings surrounding black holes. BHEX is led by a joint team of two major US establishments, Harvard CfA and NASA Goddard Space Flight Center, supported by other US research organisations, but has representatives from Europe and Japan too. Both initiatives, THEZA and BHEX can be seen as spaceborne extensions of global VLBI, EVN, VLBA, GMVA, EHT, ngEHT, ngVLA, etc. (cross out what you find irrelevant). My main take-home message from this part of the presentation is simple: spaceborne VLBI is inevitable. We better start thinking and working on this before too long. In the second part of this presentation, I will show results of the ongoing study of two newly suspected systems containing supermassive black hole binaries (SMBHBs). According to all reasonable scenarios of astrophysical evolution of galactic systems SMBHBs must exist and be abundant. They are expected to be major contributors to the gravitation wave background in the range of frequencies 0.1 mHz – 1 Hz which is to be covered by the Laser Interferometer Space Antenna (LISA) once it is up and running in the 2030s. Yet, as a class, SMBHBs remain rather elusive. There are several famous and rather likely suspects (e.g., OJ 287 – an object very well known in this audience, and several others). There is a number of much less known and sure cases, like those several I will present here. However, the overall statistics of more or less known suspected cases of SMBHB looks quite problematic from many astrophysical and cosmological standpoints. I will present our view on possible evolution of two new SMBHB suspects and present estimates of their inspiralling toward final coalescence accompanied by a gravitational wave outburst. Such outbursts are being assumed as potentially valuable cosmological probes called “standard sirens”. They will join the club of other standard objects (rods, candles), and together they will mark the birth of multimessenger observational cosmology.