WEBVTT FILE 1 00:00:00.020 --> 00:00:04.060 Astronomers have found thousands 2 00:00:04.080 --> 00:00:08.090 of planets orbiting distant stars, and the discoveries keep coming. 3 00:00:08.110 --> 00:00:12.160 Yet many techniques detect only the planets closest to their host stars, 4 00:00:12.180 --> 00:00:16.200 and within a few hundred light-years of Earth, leaving us to wonder what worlds 5 00:00:16.220 --> 00:00:20.260 we're missing. A technique called microlensing promises to 6 00:00:20.280 --> 00:00:24.440 clarify the picture. A recent analysis of six years of data 7 00:00:24.460 --> 00:00:28.570 from the MOA-II ground-based survey concludes that exoplanets similar 8 00:00:28.590 --> 00:00:32.690 in mass and, probably, composition, to Neptune are likely the most common 9 00:00:32.710 --> 00:00:36.860 worlds in the outer reaches of planetary systems. 10 00:00:36.880 --> 00:00:40.910 When a star passes directly between us and a more distant star, 11 00:00:40.930 --> 00:00:44.940 its gravity can act like a lens, magnifying the background star's 12 00:00:44.960 --> 00:00:49.000 brightness significantly for a few weeks. If the lensing star hosts 13 00:00:49.020 --> 00:00:53.040 a planet, the planets gravity can produce a noticeable change in brightness over 14 00:00:53.060 --> 00:00:57.100 a hours or days. This spike signals not only the planet's 15 00:00:57.120 --> 00:01:01.170 presence, but tells us its mass and distance from the star. 16 00:01:01.190 --> 00:01:05.250 Each method of finding exoplanets 17 00:01:05.270 --> 00:01:09.330 has different strengths. Radial velocity measurements reveal planets by 18 00:01:09.350 --> 00:01:13.380 detecting how they cause the star to move. Transit measurements reveal dips in 19 00:01:13.400 --> 00:01:17.580 starlight caused by planets passing in front of their stars. 20 00:01:17.600 --> 00:01:21.710 Both work best for massive planets in close orbits, and for stars up to hundreds of 21 00:01:21.730 --> 00:01:25.880 lgiht-years away. Microlensing opens a 22 00:01:25.900 --> 00:01:30.070 planetary window onto a larger part of the galaxy, reaching thousands of light-years. 23 00:01:30.090 --> 00:01:34.110 And because microlensing is more sensitive to smaller planets farther from their stars, 24 00:01:34.130 --> 00:01:38.170 it can reveal new planetary populations. 25 00:01:38.190 --> 00:01:42.220 In the MOA-II study, researchers discovered that planets beyond a certain 26 00:01:42.240 --> 00:01:46.290 distance from their star tend to be roughly 20 Earth masses, or 27 00:01:46.310 --> 00:01:50.360 about the same as Neptune. That distance is what astronomers call 28 00:01:50.380 --> 00:01:54.430 the "snow line," where water would be frozen during the formation of a 29 00:01:54.450 --> 00:01:58.510 planetary system. For our system, that location is roughly 30 00:01:58.530 --> 00:02:02.650 2.7 times farther from the sun than Earth. Beyond the snow line. 31 00:02:02.670 --> 00:02:06.680 where there is more solid material to coagulate and initiate the planet formation 32 00:02:06.700 --> 00:02:10.750 process, planetary formation is thought to be most efficient. 33 00:02:10.770 --> 00:02:14.820 In fact, worlds formed in this frozen hinterland 34 00:02:14.840 --> 00:02:18.940 may play an important role in making habitable planets closer to their star. 35 00:02:18.960 --> 00:02:23.070 The gravity of planets beyond the snow line can help send water-rich 36 00:02:23.090 --> 00:02:27.150 asteroids inward, where they can deliver water to young rocky worlds. 37 00:02:27.170 --> 00:02:31.190 WFIRST, an upcoming NASA mission, 38 00:02:31.210 --> 00:02:35.220 which combines high-resolution with a huge field of view, will watch for 39 00:02:35.240 --> 00:02:39.380 microlensing events toward the central part of our galaxy, the Milky Way. 40 00:02:39.400 --> 00:02:43.560 It will expand on the exoplanet survey started by NASA's Kepler mission, 41 00:02:43.580 --> 00:02:47.590 and should reveal exoplanets down to Mars mass in orbits around their 42 00:02:47.610 --> 00:02:51.650 stars as close as Earth's to more distant than Neptune's. 43 00:02:51.670 --> 00:02:55.690 When combined with Kepler's discoveries, WFIRST will give us a complete 44 00:02:55.710 --> 00:02:59.710 picture of exoplanetary systems. Stay tuned. 45 00:02:59.730 --> 00:03:03.760 [Music] 46 00:03:03.780 --> 00:03:07.780 [Music] 47 00:03:07.800 --> 00:03:11.860 [Music] 48 00:03:11.880 --> 00:03:15.940 [Beeping] 49 00:03:15.960 --> 00:03:24.050 [Beeping]