Версия от 01:59, 26 декабря 2023; EducationBot(обсуждение | вклад)(Новая страница: «{{Английская Википедия/Панель перехода}} {{Short description|Quasar in the Hercules constellation}} {{Infobox quasar | name = 3C 345 | image = 3C 345 Color cutout hst 05235 03 wfpc2 f814w f555w pc sci.jpg | caption= Image of 3C 345 by the Hubble Space Telescope | epoch = J2000 | ra = {{RA|16|42|58.8}}<ref name="ned"/> | dec = {{DEC|+39|48|37}}<ref name="ned">{{cite web...»)
(разн.) ← Предыдущая версия | Текущая версия (разн.) | Следующая версия → (разн.)
When observed in radio waves, 3C 345 features a compact region with a radio jet emanating from it for 3 arcseconds and ending at a hot spot.[2] The jet appears straight for 4 milliarcseconds (mas)[2] but then curves northwards. Hot spots are visible at the counterjet direction in radio images.[4] There is also a faint halo.[2] The jet has been found to emit X-rays, up until 0.2 arcseconds from a radio hot spot, which could be in reality a bend of the jet.[4]
The components of the jet have been found to move by about 0.25–0.42 mas, which at the distance of the jet represent apparent speeds that are 5 to 15 times faster than the speed of light.[5] The radio jet exhibits superluminal motion for 0.12 to 12 mas, with apparent speeds that accelerate from ~5c to ~15c within 0.3 mas. Within the jet lies a stationary feature ~0.1 mas (with corresponds to about 0.7 pc at the distance of 3C 345) from the core, which has also been found in other blazars.[5] The viewing angle between the jet axis and the line of sight is calculated to be about 5°.[5]
Variability
3C 345 has been known to fluctuate in brightness. For example, it brightened from magnitude 17.2 to 16.0 between 10 April 2018 and 8 May 2018 when observed in R band.[6] A bright GeV gamma-ray flare was observed by the Fermi Gamma-ray Space Telescope on 31 May 2017, as the flux increased by 40 times above average.[7] The flares in 2009 were observed simultaneously in γ-rays, X-rays and optical/UV, while there was a lag before they were observed in radiowaves.[8] A long term variability study indicates flares every 3.5 to 4 years, coinciding with the appearance of new features in the radio jets.[9]
It has been suggested that the source of the fluctuation is the presence of a binary supermassive black hole, with the two similar black holes with masses about Шаблон:Val which are separated by around 0.33 pc and orbit each other with a period of 480 years. The second black hole pertubates the accretion disk, resulting to fluctuations in activity.[10] The X-rays observations indicate that the nuclear region is hidden behind a compton thick absorber with a column density of NH ≃ 1025 cm−2 that covers 75% to 85% of the X-rays source.[11]