By engaging with all the videos within this series, you will effectively complete a full undergraduate course in astronomy, equipping yourself with the knowledge and skills necessary to navigate the night sky with confidence, learning all the basics and many advanced topics! Here, I discuss active galaxies and quasars. In previous discussions, we examined galaxy types and distribution. Our exploration starts with active galaxies. Carl Siefert first identified these extraordinary objects in 1943, noting their strong, broad emission lines from their compact, brilliant nuclei. He called them Siefert galaxies. In the 1950s, radio telescopes revealed another category of active galaxies, called radio galaxies, which emit large quantities of radio waves. By examining optical spectra, we observe that active galactic nuclei (AGN) have distinctive characteristics, including broad emission lines from gas moving at extreme velocities. Doppler broadening reveals these high-velocity motions. I’ll present examples of these captivating galaxies, including those with exceptionally bright nuclei and rapid motions. You’ll see images of Siefert galaxies like NGC 4151 and NGC 1097, while I’ll discuss their potential connection to massive binary systems. Next, we’ll delve into radio galaxies, which emit strongly in the radio spectrum and often have vast radio lobes extending beyond the visible parts of the galaxy. Centaurus A is an iconic example, revealing these colossal radio structures that provide insights into the processes occurring within these galaxies. Finally, I’ll explain the underlying mechanics of these phenomena. The synchrotron radiation process, where high-speed electrons spiral within magnetic fields, generates the radio emissions characteristic of these galaxies. As we progress, I’ll introduce you to quasars, or quasi-stellar radio sources, the most luminous entities in the universe. Discovered in the 1960s, quasars appear star-like but have broad emission lines and significant redshifts, indicating their extreme distance and luminosity. The Hubble Space Telescope and other surveys have provided high-resolution spectra, revealing their tremendous energy across the electromagnetic spectrum. Observations from telescopes like the Very Large Array and Chandra X-ray Observatory have advanced our understanding of the immense jets and lobes accompanying these luminous cores. These jets extend for millions of light-years and are composed of particles accelerated to near light-speed. Finally, we’ll examine the spectral energy distribution of quasars, which includes contributions from synchrotron radiation, thermal emission from stars, and high-energy processes. This combined emission makes quasars a thousand times more luminous than entire galaxies like the Milky Way. This is part of my complete intro Astronomy class that I taught at Willam Paterson University and CUNY Hunter. Active galactic nucleus: Quasar: Messier 87: Gamma Rays in Active Galactic Nuclei: Bremsstrahlung X-Rays: Synchrotron Radiation: Synchrotron Radiation: ActiveGalaxies Quasars CosmicPhenomena AstronomyLecture RadioGalaxies SiefertGalaxies HubbleSpaceTelescope Astrophysics GalacticNuclei SupermassiveBlackHoles Key themes and topics emphasized include: ActiveGalaxies, Quasars, CosmicPhenomena, AstronomyLecture, RadioGalaxies, SiefertGalaxies, HubbleSpaceTelescope, Astrophysics, GalacticNuclei, SupermassiveBlackHoles.