WEBVTT FILE 1 00:00:00.010 --> 00:00:04.030 [Music] 2 00:00:04.050 --> 00:00:08.080 [Music] 3 00:00:08.100 --> 00:00:12.090 [Music] 4 00:00:12.110 --> 00:00:16.120 Narrator: When it comes to finding planets outside our 5 00:00:16.140 --> 00:00:20.170 solar system, no space mission to date can beat NASA's Kepler 6 00:00:20.190 --> 00:00:24.180 in 5 years it has found more than a thousand confirmed exoplanets, 7 00:00:24.200 --> 00:00:28.220 with thousands more awaiting confirmation. Kepler finds 8 00:00:28.240 --> 00:00:32.260 exoplanets by carefully watching starlight, looking for slight dips in 9 00:00:32.280 --> 00:00:36.300 brightness as a planet passes in front of, or transits, its star. This 10 00:00:36.320 --> 00:00:40.340 technique, called time-series transit photometry, is most effective 11 00:00:40.360 --> 00:00:44.370 for large planets in close orbits. This both maximizes the light 12 00:00:44.390 --> 00:00:48.380 loss during a given transit and the number of transits we observe. 13 00:00:48.400 --> 00:00:52.400 But how far can astronomers go with this technique? Can we 14 00:00:52.420 --> 00:00:56.410 find a twin of Earth? Or even identify whether a planet has moons? 15 00:00:56.430 --> 00:01:00.450 With two transit photometry missions on the horizon--NASA's 16 00:01:00.470 --> 00:01:04.490 TESS and ESA's PLATO--some astronomers have examined the limits 17 00:01:04.510 --> 00:01:08.500 of this technique, with surprising results. Daniel Angerhausen: For our study, 18 00:01:08.520 --> 00:01:12.530 Michael Hippke and I combined the knowledge of the 19 00:01:12.550 --> 00:01:16.580 lessons learned from Kepler with what we know about the future missions like 20 00:01:16.600 --> 00:01:20.610 TESS and PLATO, and we asked ourself the question 'what would we be able 21 00:01:20.630 --> 00:01:24.630 to see if we put these observatories outside our solar system and observed 22 00:01:24.650 --> 00:01:28.650 our solar system.' And the results are that we 23 00:01:28.670 --> 00:01:32.670 probably won't be able to see Mars, or Mercury, but 24 00:01:32.690 --> 00:01:36.690 everything else in our solar system we definitely get a solid detection of 25 00:01:36.710 --> 00:01:40.700 Earth, a solid detection of Venus. Also of the outer planets. 26 00:01:40.720 --> 00:01:44.730 We might even be able to see ring structures like the one around 27 00:01:44.750 --> 00:01:48.750 Saturn, and maybe even moons, Jupiter's moons. 28 00:01:48.770 --> 00:01:52.790 Narrator: In another study, they pushed Kepler to the limit by cleverly 29 00:01:52.810 --> 00:01:56.850 combining almost all extrasolar planet data collected by the telescope 30 00:01:56.870 --> 00:02:00.880 using an understanding of orbital mechanics. Daniel: For example, Jupiter 31 00:02:00.900 --> 00:02:04.930 has so-called trojan asteroids that collect in two 32 00:02:04.950 --> 00:02:08.950 specific areas on its orbit, pretty symmetrically to its orbit. 33 00:02:08.970 --> 00:02:12.990 And in the study that we did on the Kepler data, where we added up 34 00:02:13.010 --> 00:02:17.030 all the phase curves of all 4,000 planets in the Kepler data set, we were even 35 00:02:17.050 --> 00:02:21.050 able to see signatures of asteroids in extrasolar 36 00:02:21.070 --> 00:02:25.090 systems. And with the future missions we might even be able to find that 37 00:02:25.110 --> 00:02:29.130 in individual systems and not just by putting all the data together. 38 00:02:29.150 --> 00:02:33.150 We wanted to figure out what the ultimate limit 39 00:02:33.170 --> 00:02:37.200 is that we can do photometry with, and it turns out 40 00:02:37.220 --> 00:02:41.220 with the next generation of instruments we're already hitting the technical limit and are 41 00:02:41.240 --> 00:02:45.260 mostly limited by the variation of the host stars themselves, 42 00:02:45.280 --> 00:02:49.340 by the huge noise that's coming from the host stars. Narrator: The way to push down 43 00:02:49.360 --> 00:02:53.370 this noise is by observing stars for longer periods to improve 44 00:02:53.390 --> 00:02:57.430 models of the star's behavior, allowing astronomers to tease out the smallest transits. 45 00:02:57.450 --> 00:03:01.440 The work of Hippke and Angerhausen shows 46 00:03:01.460 --> 00:03:05.470 that future missions will be able to detect Earth-size planets orbiting 47 00:03:05.490 --> 00:03:09.510 sun-like stars at distances that would allow liquid water. 48 00:03:09.530 --> 00:03:13.530 These systems will become prime targets for more detailed study, using other 49 00:03:13.550 --> 00:03:17.580 missions, such as NASA's James Webb Space Telescope. Will we 50 00:03:17.600 --> 00:03:21.670 find a copy of our solar system? How common are habitable 51 00:03:21.690 --> 00:03:25.700 worlds, and particularly twins of Earth? The thousands of exoplanets 52 00:03:25.720 --> 00:03:29.740 to be discovered by TESS and PLATO will go a long way to providing answers. 53 00:03:29.760 --> 00:03:33.790 [Music][Beeping] 54 00:03:33.810 --> 00:03:37.810 [Beeping] 55 00:03:37.830 --> 00:00:20.220 [Beeping] 56 00:00:20.240 --> 00:03:45.672