with Prof. Eliot Quataert (University of California, Berkeley)
In the previous decade, one third of the world's astronomers became involved in a single project -- observing a distant and violent event, when two "star corpses" called neutron stars collided and exploded. This represented the first time in the history of astronomy that a cosmic event was observed with both gravity waves (first predicted by Einstein) and light. We now call this event the birth of "multi-messenger astronomy." Dr. Quataert gives a non-technical history of how we are now able to find gravity waves, what happens during such a merger, and why we now believe that much of the gold, platinum, uranium and other heavy elements in the universe is assembled in such "star corpse" mergers. Recorded Jan. 24, 2018.
with Prof. Eliot Quataert (University of California, Berkeley)
In the previous decade, one third of the world's astronomers became involved in a single project -- observing a distant and violent event, when two "star corpses" called neutron stars collided and exploded. This represented the first time in the history of astronomy that a cosmic event was observed with both gravity waves (first predicted by Einstein) and light. We now call this event the birth of "multi-messenger astronomy." Dr. Quataert gives a non-technical history of how we are now able to find gravity waves, what happens during such a merger, and why we now believe that much of the gold, platinum, uranium and other heavy elements in the universe is assembled in such "star corpse" mergers. Recorded Jan. 24, 2018.