WEBVTT 00:00:01.131 --> 00:00:04.432 My first love was for the night sky. 00:00:04.432 --> 00:00:05.998 Love is complicated. NOTE Paragraph 00:00:05.998 --> 00:00:10.527 You're looking at a fly-through of the Hubble Space Telescope Ultra-Deep Field, 00:00:10.527 --> 00:00:14.639 one of the most distant images of our universe ever observed. 00:00:14.639 --> 00:00:17.153 Everything you see here is a galaxy, 00:00:17.153 --> 00:00:20.160 comprised of billions of stars each. 00:00:20.160 --> 00:00:24.901 And the the farthest galaxy is a trillion, trillion kilometers away. NOTE Paragraph 00:00:25.881 --> 00:00:28.805 As an astrophysicist, I have the awesome privilege of studying 00:00:28.805 --> 00:00:32.252 some of the most exotic objects in our universe. 00:00:32.252 --> 00:00:36.064 The objects that have captivated me from first crush, throughout my career 00:00:36.064 --> 00:00:40.473 are supermassive, hyperactive blackholes. 00:00:41.813 --> 00:00:45.931 Weighing 1 to 10 billion times the mass of our own sun, 00:00:45.931 --> 00:00:48.825 these galactic black holes are devouring material, 00:00:48.825 --> 00:00:52.145 at a rate of upwards of a thousand times more 00:00:52.145 --> 00:00:55.512 than your "average" supermassive black hole. 00:00:55.512 --> 00:00:57.640 (Laughter) NOTE Paragraph 00:00:57.640 --> 00:00:59.334 These two characteristics, 00:00:59.334 --> 00:01:02.548 with a few others, make them quasars. 00:01:02.548 --> 00:01:05.465 At the same time, the objects I study 00:01:05.465 --> 00:01:08.242 are producing some of the most powerful particle streams 00:01:08.242 --> 00:01:09.937 ever observed. 00:01:09.937 --> 00:01:12.777 These narrow streams, called jets, 00:01:12.777 --> 00:01:17.385 are moving at 99.99 percent of the speed of light, 00:01:17.385 --> 00:01:21.368 and are pointed directly at the earth. NOTE Paragraph 00:01:21.368 --> 00:01:27.257 These jetted, earth-pointed, hyperactive and supermassive black holes 00:01:27.257 --> 00:01:31.801 are called blazars, or blazing quasars. 00:01:31.801 --> 00:01:35.282 What makes blazars so special is that they're some of the universe's 00:01:35.282 --> 00:01:37.802 most efficient particle accelerators, 00:01:37.802 --> 00:01:42.720 transporting incredible amounts of energy throughout a galaxy. NOTE Paragraph 00:01:42.720 --> 00:01:45.469 Here, I'm showing an artist's conception of a blazar. 00:01:45.469 --> 00:01:48.669 The dinner plate by which the material falls unto the black hole 00:01:48.669 --> 00:01:50.256 is called the accretion disc, 00:01:50.256 --> 00:01:52.082 shown here in blue. 00:01:52.082 --> 00:01:55.061 Some of that material is sling-shotted around the blackhole 00:01:55.061 --> 00:01:57.085 and accelerated to insanely high speeds 00:01:57.085 --> 00:01:59.912 in the jet, shown here in white. 00:01:59.912 --> 00:02:02.599 Although the blazar system is rare, 00:02:02.599 --> 00:02:05.606 the process by which nature pulls the material via a disk, 00:02:05.606 --> 00:02:08.883 and then flings some of it out via a jet, is more common. 00:02:09.647 --> 00:02:12.091 We'll eventually zoom out of the blazar system 00:02:12.091 --> 00:02:17.180 to show its approximate relationship to the larger galactic context. NOTE Paragraph 00:02:21.890 --> 00:02:26.295 Beyond the cosmic accounting of what goes in to what goes out, 00:02:26.295 --> 00:02:29.342 one of the hot topics in blazar astrophysics right now 00:02:29.342 --> 00:02:33.053 is where the highest energy jet emission comes from. 00:02:33.053 --> 00:02:36.974 In this image, I'm interested in where in where this white blob forms 00:02:36.974 --> 00:02:40.617 and if, as a result, there's any relationship between the jet 00:02:40.617 --> 00:02:43.483 and the accretion disc material. NOTE Paragraph 00:02:43.483 --> 00:02:45.286 Clear answers to this question 00:02:45.286 --> 00:02:48.401 were almost completely inaccessible until 2008, 00:02:48.401 --> 00:02:52.675 when NASA launched a new telescope that better detects gamma ray light, 00:02:52.675 --> 00:02:55.387 that is, light with energies a million times higher 00:02:55.387 --> 00:02:58.934 than your standard x-ray scan. 00:02:58.934 --> 00:03:02.824 I simultaneously compare variations between the gamma-ray light data 00:03:02.824 --> 00:03:06.493 and the visible light data from day-to-day and year-to-year, 00:03:06.493 --> 00:03:09.767 to better localize these gamma-ray blobs. 00:03:09.767 --> 00:03:12.453 My research shows that in some instances, 00:03:12.453 --> 00:03:15.513 these blobs form much closer to the black hole 00:03:15.513 --> 00:03:17.873 than we initially thought. NOTE Paragraph 00:03:17.873 --> 00:03:19.764 As we more confidentially localize 00:03:19.764 --> 00:03:22.060 where these gamma ray blobs are forming, 00:03:22.060 --> 00:03:25.583 we can better understand how jets are being accelerated, 00:03:25.583 --> 00:03:28.191 and ultimately reveal the dynamic processes 00:03:28.191 --> 00:03:30.596 by which some of the most fascinating objects 00:03:30.596 --> 00:03:34.292 in our universe are formed. NOTE Paragraph 00:03:34.292 --> 00:03:37.501 This all started as a love story. 00:03:37.501 --> 00:03:39.414 And it still is. 00:03:39.414 --> 00:03:43.624 This love transformed me from a curious, stargazing young girl, 00:03:43.624 --> 00:03:45.445 to a professional astrophysicist, 00:03:45.445 --> 00:03:48.782 hot on the heels of celestial discovery. 00:03:48.782 --> 00:03:51.202 Who knew that chasing after the universe 00:03:51.202 --> 00:03:55.000 would ground me so deeply to my mission here on earth. 00:03:55.000 --> 00:03:58.468 Then again, when do we ever know where love's first flutter 00:03:58.468 --> 00:03:59.942 will truly take us. NOTE Paragraph 00:03:59.942 --> 00:04:01.171 Thank you. NOTE Paragraph 00:04:01.171 --> 00:04:04.471 (Applause)