1 00:00:01,920 --> 00:00:06,400 Speaker 1: Welcome to brain Stuff production of I Heart Radio. Hey 2 00:00:06,440 --> 00:00:09,200 Speaker 1: brain Stuff, Lauren Volk bomb here with a classic episode 3 00:00:09,240 --> 00:00:12,159 Speaker 1: from the brain Stuff archives. This one has to do 4 00:00:12,240 --> 00:00:15,240 Speaker 1: with one of the amazing discoveries made in recent years 5 00:00:15,480 --> 00:00:20,160 Speaker 1: about one of our neighboring planets in the Solar System. 6 00:00:20,160 --> 00:00:23,680 Speaker 1: Hey brain Stuff, Lauren vog O bomb here. Urinus stinks 7 00:00:24,160 --> 00:00:28,360 Speaker 1: and I'm not joking. This enigmatic Outer Solar System planet 8 00:00:28,480 --> 00:00:31,440 Speaker 1: has long had a credibility problem, with it being the 9 00:00:31,480 --> 00:00:35,839 Speaker 1: butt of countless immature jokes. Now astronomers have discovered a 10 00:00:35,920 --> 00:00:39,440 Speaker 1: gas in Urinas's clouds that does nothing to curtail this 11 00:00:39,760 --> 00:00:45,000 Speaker 1: humor at all. Thanks science, The newest study published in 12 00:00:45,040 --> 00:00:48,320 Speaker 1: the journal Nature Astronomy has discovered the chemical signature of 13 00:00:48,400 --> 00:00:51,720 Speaker 1: hydrogen sulfide in the planet's clouds, a compound that gives 14 00:00:51,760 --> 00:00:55,560 Speaker 1: rotten eggs their distinctive stench. Besides launching a bevy of 15 00:00:55,600 --> 00:00:59,400 Speaker 1: new puns, this finding could transform or understanding of how 16 00:00:59,440 --> 00:01:02,120 Speaker 1: our Solar System evolved. It may also help us to 17 00:01:02,200 --> 00:01:06,160 Speaker 1: understand the atmospheres of massive planets orbiting other stars. A 18 00:01:06,240 --> 00:01:09,640 Speaker 1: first a bit of background. Uranus has only been visited 19 00:01:09,640 --> 00:01:13,120 Speaker 1: by a spacecraft once, when NASA's voyager to zipped past 20 00:01:13,200 --> 00:01:17,440 Speaker 1: the planet in the fly by produced many beautiful and 21 00:01:17,640 --> 00:01:21,520 Speaker 1: iconic views of this almost featureless, light blue world, and 22 00:01:21,600 --> 00:01:25,200 Speaker 1: astronomers have made countless ground based observations of Uranus in 23 00:01:25,280 --> 00:01:29,400 Speaker 1: hopes of better understanding the composition of its atmosphere. Despite 24 00:01:29,400 --> 00:01:32,680 Speaker 1: these efforts, however, we know little about this far away planet, 25 00:01:33,120 --> 00:01:36,360 Speaker 1: but the discovery of hydrogen sulfide is a big step forward, 26 00:01:36,600 --> 00:01:38,360 Speaker 1: and it could only be done using one of our 27 00:01:38,400 --> 00:01:43,520 Speaker 1: planets most powerful observatories. Using the near infrared integral field 28 00:01:43,560 --> 00:01:47,160 Speaker 1: spectrometer that's attached to the Gemini North telescope in Hawaii, 29 00:01:47,400 --> 00:01:51,400 Speaker 1: astronomers were able to detect the very slight spectroscopic signature 30 00:01:51,440 --> 00:01:55,480 Speaker 1: of hydrogen sulfide in the uppermost layers of uranus is clouds. 31 00:01:55,760 --> 00:01:58,480 Speaker 1: This whiff of hydrogen sulfide is only the tip of 32 00:01:58,560 --> 00:02:02,040 Speaker 1: the ode differous iceberg. However, the presence of this gas 33 00:02:02,080 --> 00:02:05,880 Speaker 1: is indicative of a huge reservoir below the obscuring cloud deck. 34 00:02:07,000 --> 00:02:10,280 Speaker 1: Co investigator Lee Fletcher of the University of Leicester, UK, 35 00:02:10,760 --> 00:02:14,160 Speaker 1: in a Gemini North statement, said only a tiny amount 36 00:02:14,200 --> 00:02:17,600 Speaker 1: of hydrogen sulfide remains above the clouds as saturated vapor, 37 00:02:18,040 --> 00:02:20,320 Speaker 1: and this is why it's so challenging to capture the 38 00:02:20,320 --> 00:02:24,280 Speaker 1: signatures of ammonia and hydrogen sulfide above cloud decks of Uranus. 39 00:02:25,000 --> 00:02:28,720 Speaker 1: The superior capabilities of Gemini finally gave us that lucky break. 40 00:02:29,480 --> 00:02:33,119 Speaker 1: Astronomers have long argued over whether hydrogen sulfide or ammonia 41 00:02:33,360 --> 00:02:37,120 Speaker 1: dominate Uranus's clouds. It's well known that the inner massive 42 00:02:37,160 --> 00:02:41,000 Speaker 1: planets Jupiter and Saturn have atmospheres dominated by ammonia ice, 43 00:02:41,400 --> 00:02:45,679 Speaker 1: whereas Urinus and presumably Neptune do not. It's those very 44 00:02:45,680 --> 00:02:49,040 Speaker 1: differences in atmospheric conditions that place Jupiter and Saturn in 45 00:02:49,080 --> 00:02:52,600 Speaker 1: the gas giant category and Uranus and Neptune in the 46 00:02:52,680 --> 00:02:56,560 Speaker 1: ice giant category, and these differences reveal an insight as 47 00:02:56,560 --> 00:03:00,519 Speaker 1: to where the planets formed. As Fletcher said, during our 48 00:03:00,560 --> 00:03:04,400 Speaker 1: Solar System's formation, the balance between nitrogen and sulfur, and 49 00:03:04,440 --> 00:03:08,440 Speaker 1: hence ammonia and Uranus is newly detected. Hydrogen sulfide was 50 00:03:08,480 --> 00:03:12,600 Speaker 1: determined by the temperature and location of the planet's formation. 51 00:03:13,919 --> 00:03:16,600 Speaker 1: The thought is that early in our Solar System's history, 52 00:03:16,880 --> 00:03:21,120 Speaker 1: the massive planets migrated from where they initially formed, eventually 53 00:03:21,160 --> 00:03:24,680 Speaker 1: setting into stable orbits where we see them today. Through 54 00:03:24,720 --> 00:03:28,160 Speaker 1: the analysis of chemicals in their clouds, Astronomers can now 55 00:03:28,240 --> 00:03:30,959 Speaker 1: formulate theories as to how far away from the Sun 56 00:03:31,160 --> 00:03:35,040 Speaker 1: these giant worlds formed and where they migrated from. With 57 00:03:35,120 --> 00:03:38,160 Speaker 1: this information in mind, astronomers can then look to other 58 00:03:38,240 --> 00:03:41,320 Speaker 1: stars and gain an insight as to how and where 59 00:03:41,600 --> 00:03:46,120 Speaker 1: giant exoplanets formed. This is all very interesting, but a 60 00:03:46,160 --> 00:03:49,120 Speaker 1: big question that scientists are likely answering right now is 61 00:03:49,680 --> 00:03:53,440 Speaker 1: if we could inhale Uranus's atmosphere, would it kill us? 62 00:03:54,200 --> 00:03:57,000 Speaker 1: The smell would certainly be unpleasant, but it's not the 63 00:03:57,040 --> 00:03:59,960 Speaker 1: stench that would kill you. A lead study author Patrick 64 00:04:00,040 --> 00:04:03,360 Speaker 1: Irwin of the University of Oxford, UK explained in the 65 00:04:03,360 --> 00:04:07,680 Speaker 1: press release Suffocation and exposure in the negative two hundred 66 00:04:07,720 --> 00:04:11,840 Speaker 1: degrees Celsie's atmosphere, made mostly of hydrogen, helium and methane, 67 00:04:12,080 --> 00:04:16,159 Speaker 1: would take its toll along before the smell. So we'll 68 00:04:16,160 --> 00:04:18,960 Speaker 1: skip the vacation plans, but still keep an eye on 69 00:04:18,960 --> 00:04:29,600 Speaker 1: this fascinating, if stinky planet. Today's episode is based on 70 00:04:29,640 --> 00:04:33,120 Speaker 1: the article Scientists Confirm Uranus Stinks on how stuff Works 71 00:04:33,120 --> 00:04:36,599 Speaker 1: dot com, written by Ian O'Neill. Brain Stuff is production 72 00:04:36,600 --> 00:04:38,520 Speaker 1: of I Heart Radio in partnership with How Stuff Works. 73 00:04:38,560 --> 00:04:41,240 Speaker 1: Dot com and it's produced by Tyler Klang. Four more 74 00:04:41,240 --> 00:04:44,880 Speaker 1: podcasts My heart Radio, visit the iHeart Radio app, Apple podcasts, 75 00:04:44,920 --> 00:04:46,719 Speaker 1: or wherever you listen into your favorite shows.