A Technical Description of my Webpage Feature Image Everybody knows that at the center of a quasar lies a supermassive Black Hole. Everybody except me, because my observations with large optical, radio, and spacecraft X-ray telescopes, show that in fact, the central object is a close relative, called a MECO (Massive Eternally Collapsing Object). This MECO is also a collapsed object with 3 billion suns mass, but unlike a black hole it is surrounded by a strong magnetic field anchored to the rotating core, and is a solution of the General Relativistic Einstein-Maxwell equations in which Quantum Electrodynamic and Dark Energy forces prevent the formation of a true event horizon. The illustration answers the long-standing puzzle: if Black Holes have an Event Horizon beyond which nothing, not even light, can escape, how can it be that they are the most luminous objects in the universe at optical, X-ray, and radio wavelengths? My telescopic studies of these objects at centers of gravitationally lensed quasars have shown thet the strong emissions are caused by the sweeping magnetic fields acting on infalling matter to produce the structure shown. My challenge here was to show the relationship between the structures emitting at X-ray, Ultraviolet, Optical, and Radio wavelengths (what "color" are X-rays? Radio waves?). The tiny central collapsed object is just a dull ruddy glow at the center. A short distance away, the inner edge of an accretion disc reveals the magnetic fields working on the infalling orbiting matter and glowing at half a million degrees. The accretion disc itself is barely evident as a dark shading by absorbing solid matter just outside its bright inner edge. The sweeping magnetic fields generate an outward flow, or wind, of ionized gases, whose electrons are naturally swept to the center and become trapped by tangled inner magnetic fields, to explosively squirt out as jets. They carry along scraps of magnetic field in the twisted jet region to create intense radio emission, shown as the ruddy squiggles. Because a rigidly rotating magnetic field with its trapped particles cannot rotate faster than the speed of light, a different kind of outer structure must form where the magnetic fields must bend into a different (circular) direction. This causes the outer wind of ionized particles to bend upward away from the accretion disc, and ultimately to a region where the magnetic forces no longer dominate over electrical attraction. Thus the positively charged ions flowing outward and upward can begin to feel the intense electrical fields of the central jetting electrons, and the ions curve back toward the central axis. The X-ray emission, shown in ultra-blue, is taken from observations of a nearby young neutron star object whose magnetic properties mimic the MECO's, as shown in published calculations. This powerful X-ray emission occurs as the relativistic streaming positive ions combine with the relativistic electrons. Small gradients in color of the bulbous X-ray structures imply locally different energies of the emitted X-rays. Long streamers of gas along the length of the light cylinder show where the winds of now neutral gas are gradually calming down to their ground state as they continue to recede from the central object. If this MECO object were located where our Sun is, these outer streamers would be 100 times farther away than our outermost planet Pluto. Notice that faint plumes are seen outside of the light cylinder that encases most of the streamers. These are probably infalling matter that becomes ionized by the intense X-ray field experienced everywhere around this formidable monster. This surmise has not yet been backed by data. The purpose of the illustration is to show the relationships of the different particle streams and radiation fields to each other. These relationships have been discovered by comparing physical models from elaborate computer simulations, with microlensing studies of the powerful emissions, as can be further studied in the accompanying texts, and references to my published technical reports. The size scales and relative locations of these structures are inferred from the timing of the reverberations (echos) discovered with the different telescopes. An important conclusion of this complex analysis is in the form of a prediction; because of the slight asymmetry in the rotational coupling of infalling matter to the central rotation, the outer structure in these objects should ordinarily be asymmetrical. In other words, the left side structure should be significantly different from the right side structure. This should be an important discriminant between MECO and Black Hole central objects. I thank Barbara Williams for help constructing this image, and for expertly applying the LUCIS enhancement software.