WEBVTT 00:00:00.000 --> 00:00:13.400 align:middle line:90% [MUSIC PLAYING] 00:00:13.400 --> 00:00:15.770 align:middle line:84% At the Johnson Space Center in Houston, Texas, 00:00:15.770 --> 00:00:17.900 align:middle line:84% you can walk along a Saturn V rocket 00:00:17.900 --> 00:00:20.630 align:middle line:84% that was designed to help humans get to the moon. 00:00:20.630 --> 00:00:22.460 align:middle line:84% But now this center is helping NASA 00:00:22.460 --> 00:00:24.290 align:middle line:84% prepare for our next great adventure 00:00:24.290 --> 00:00:26.540 align:middle line:84% in astronomy, a telescope that will 00:00:26.540 --> 00:00:29.720 align:middle line:84% look way past the moon out to the universe's farthest 00:00:29.720 --> 00:00:31.490 align:middle line:90% horizons. 00:00:31.490 --> 00:00:34.100 align:middle line:84% Here is the vacuum chamber that was used to test spacecraft 00:00:34.100 --> 00:00:35.630 align:middle line:90% during the Apollo era. 00:00:35.630 --> 00:00:38.360 align:middle line:84% So Lee, I understand it's being used for the James Webb Space 00:00:38.360 --> 00:00:39.110 align:middle line:90% Telescope too. 00:00:39.110 --> 00:00:41.450 align:middle line:84% Yes, this is where we're going to be doing a full scale 00:00:41.450 --> 00:00:44.210 align:middle line:84% test of the James Webb Space Telescope, 00:00:44.210 --> 00:00:46.438 align:middle line:84% including the telescope and the instruments. 00:00:46.438 --> 00:00:48.230 align:middle line:84% And we're going to be doing optical testing 00:00:48.230 --> 00:00:51.170 align:middle line:84% and thermal testing of those components. 00:00:51.170 --> 00:00:54.590 align:middle line:84% We've seen tests before, but this is the largest scale 00:00:54.590 --> 00:00:56.210 align:middle line:84% that we've done so far on Webb, right? 00:00:56.210 --> 00:00:56.832 align:middle line:90% Yeah. 00:00:56.832 --> 00:00:58.790 align:middle line:84% In fact, it's probably the largest optical test 00:00:58.790 --> 00:00:59.960 align:middle line:90% that NASA has ever done. 00:00:59.960 --> 00:01:02.210 align:middle line:84% And that's because Webb is the largest Space Telescope 00:01:02.210 --> 00:01:04.127 align:middle line:84% we've ever built. So we're going to be testing 00:01:04.127 --> 00:01:06.738 align:middle line:84% the full primary mirror which is 6 and 1/2 meters in diameter, 00:01:06.738 --> 00:01:08.780 align:middle line:84% and we're going to be testing the whole telescope 00:01:08.780 --> 00:01:10.240 align:middle line:90% and the instruments with it. 00:01:10.240 --> 00:01:10.740 align:middle line:90% OK. 00:01:10.740 --> 00:01:12.410 align:middle line:84% So before we get in there, give us 00:01:12.410 --> 00:01:15.260 align:middle line:84% a preview of what's been done to prepare for this test 00:01:15.260 --> 00:01:15.760 align:middle line:90% right now. 00:01:15.760 --> 00:01:18.260 align:middle line:84% Well, first of all, this is the first test where we actually 00:01:18.260 --> 00:01:19.230 align:middle line:90% have flight hardware. 00:01:19.230 --> 00:01:21.050 align:middle line:84% It's the aft optics system, which is 00:01:21.050 --> 00:01:22.640 align:middle line:90% part of the telescope itself. 00:01:22.640 --> 00:01:25.700 align:middle line:84% We put the aft optics system onto the pathfinder telescope, 00:01:25.700 --> 00:01:27.620 align:middle line:84% which is a model of the telescope 00:01:27.620 --> 00:01:30.758 align:middle line:84% and includes primary mirror segments on it. 00:01:30.758 --> 00:01:32.300 align:middle line:84% We then put that Pathfinder telescope 00:01:32.300 --> 00:01:34.820 align:middle line:84% with the aft optics system onto a large structure 00:01:34.820 --> 00:01:38.570 align:middle line:84% and a rail system that allowed us to put it in the chamber. 00:01:38.570 --> 00:01:40.940 align:middle line:84% So what's the real purpose of the test? 00:01:40.940 --> 00:01:43.400 align:middle line:84% We're going to be cooling the telescope down 00:01:43.400 --> 00:01:45.860 align:middle line:84% and we're going to be making sure that all of the mirrors 00:01:45.860 --> 00:01:48.290 align:middle line:84% are aligned the way they're supposed to be. 00:01:48.290 --> 00:01:51.440 align:middle line:84% And also that the system as a telescope really works the way 00:01:51.440 --> 00:01:53.750 align:middle line:84% we expect at the very cold temperatures 00:01:53.750 --> 00:01:55.323 align:middle line:90% that it'll be out in space. 00:01:55.323 --> 00:01:57.240 align:middle line:84% It looks like they're all set up for the test, 00:01:57.240 --> 00:01:59.390 align:middle line:84% so let's get out of the chamber now. 00:01:59.390 --> 00:02:02.390 align:middle line:84% Now they're going to be closing the chamber door. 00:02:02.390 --> 00:02:05.750 align:middle line:84% Liquid nitrogen is used to cool the inside of the vacuum shell 00:02:05.750 --> 00:02:08.210 align:middle line:84% to about 70 degrees above absolute zero. 00:02:08.210 --> 00:02:10.520 align:middle line:84% But inside of that is a helium shell. 00:02:10.520 --> 00:02:12.020 align:middle line:84% The helium shell is what cools us 00:02:12.020 --> 00:02:14.660 align:middle line:84% to even colder temperatures to the 30 to 50 degrees 00:02:14.660 --> 00:02:16.370 align:middle line:90% above absolute zero. 00:02:16.370 --> 00:02:19.170 align:middle line:84% We're now well into the optical testing. 00:02:19.170 --> 00:02:21.020 align:middle line:84% So what do you mean by optical testing? 00:02:21.020 --> 00:02:23.580 align:middle line:84% We actually put light through the entire telescope chain, 00:02:23.580 --> 00:02:26.150 align:middle line:84% including the tertiary mirror and the fine steering mirror. 00:02:26.150 --> 00:02:28.932 align:middle line:84% Do you want to see some real images that's gone 00:02:28.932 --> 00:02:30.140 align:middle line:90% through the entire telescope? 00:02:30.140 --> 00:02:30.560 align:middle line:90% Oh, yeah. 00:02:30.560 --> 00:02:31.435 align:middle line:90% Let me show you that. 00:02:31.435 --> 00:02:32.370 align:middle line:90% Great. 00:02:32.370 --> 00:02:35.000 align:middle line:84% We actually simulate what looks like little stars running 00:02:35.000 --> 00:02:37.160 align:middle line:84% through the entire end to end telescope. 00:02:37.160 --> 00:02:39.800 align:middle line:84% And by looking at how these stars go through focus, 00:02:39.800 --> 00:02:42.990 align:middle line:84% we can understand what the telescope is doing. 00:02:42.990 --> 00:02:45.020 align:middle line:84% So that's how you test the end-to-end telescope 00:02:45.020 --> 00:02:46.550 align:middle line:90% to the full light path. 00:02:46.550 --> 00:02:48.830 align:middle line:84% How about the primary mirror alone? 00:02:48.830 --> 00:02:50.630 align:middle line:84% We use special test equipment that 00:02:50.630 --> 00:02:53.600 align:middle line:84% lets us test the primary mirror just by itself. 00:02:53.600 --> 00:02:56.180 align:middle line:84% And by doing that, we can determine the alignment 00:02:56.180 --> 00:02:58.070 align:middle line:84% of each of the mirror segments individually 00:02:58.070 --> 00:03:00.650 align:middle line:84% but also how they relate to each other and to make sure 00:03:00.650 --> 00:03:02.208 align:middle line:90% that they're aligned properly. 00:03:02.208 --> 00:03:03.500 align:middle line:90% And we have the full telescope. 00:03:03.500 --> 00:03:06.290 align:middle line:90% We'll have 18 of these hexagons. 00:03:06.290 --> 00:03:08.360 align:middle line:84% Pathfinder only has two mirror segments, 00:03:08.360 --> 00:03:10.573 align:middle line:84% but it's enough to really let us practice 00:03:10.573 --> 00:03:11.990 align:middle line:84% all the things we need to practice 00:03:11.990 --> 00:03:13.740 align:middle line:84% in terms of the testing and the alignment. 00:03:13.740 --> 00:03:16.370 align:middle line:84% The images look like they have fingerprints on it? 00:03:16.370 --> 00:03:17.270 align:middle line:90% Yeah. 00:03:17.270 --> 00:03:20.270 align:middle line:84% So those fingerprints are really contour maps, 00:03:20.270 --> 00:03:22.550 align:middle line:84% like taking slices through a mountain. 00:03:22.550 --> 00:03:24.740 align:middle line:84% As we tilt the mirrors around, the contour maps 00:03:24.740 --> 00:03:27.050 align:middle line:84% tell us how much the mirrors are tilted. 00:03:27.050 --> 00:03:30.080 align:middle line:84% And we use that information as we align the primary mirror. 00:03:30.080 --> 00:03:33.288 align:middle line:84% What's the deal with this dark line right here through one 00:03:33.288 --> 00:03:34.580 align:middle line:90% of the primary mirror segments? 00:03:34.580 --> 00:03:37.700 align:middle line:84% Yes, that's just a shadow from the big strut that 00:03:37.700 --> 00:03:39.020 align:middle line:90% holds the secondary mirror. 00:03:39.020 --> 00:03:41.280 align:middle line:84% And the secondary mirror is on a tripod. 00:03:41.280 --> 00:03:43.160 align:middle line:84% And so the light that is hitting the mirrors 00:03:43.160 --> 00:03:46.200 align:middle line:84% is actually going and casting a shadow from that strut. 00:03:46.200 --> 00:03:48.200 align:middle line:84% And what we're trying to do is align the mirrors 00:03:48.200 --> 00:03:51.510 align:middle line:84% to create essentially a single mirror. 00:03:51.510 --> 00:03:54.000 align:middle line:84% So we're finishing up the test and what we're doing 00:03:54.000 --> 00:03:56.580 align:middle line:84% is reversing the process of getting it in. 00:03:56.580 --> 00:03:59.703 align:middle line:84% We have to be very careful with all the sensitive hardware, 00:03:59.703 --> 00:04:01.620 align:middle line:84% including flight hardware that we're removing. 00:04:01.620 --> 00:04:03.540 align:middle line:84% Well, thanks, Lee for your time and letting us 00:04:03.540 --> 00:04:06.720 align:middle line:84% see what the first large scale test on James Webb 00:04:06.720 --> 00:04:07.590 align:middle line:90% has been like. 00:04:07.590 --> 00:04:09.270 align:middle line:90% You're very welcome. 00:04:09.270 --> 00:04:12.510 align:middle line:84% The aft optics system has been removed from the test setup, 00:04:12.510 --> 00:04:14.490 align:middle line:84% and will be joining other flight hardware 00:04:14.490 --> 00:04:17.579 align:middle line:84% for more testing at NASA's Goddard Space Flight Center 00:04:17.579 --> 00:04:19.019 align:middle line:90% in Greenbelt, Maryland. 00:04:19.019 --> 00:04:22.050 align:middle line:84% Thanks for joining us for this edition of Behind the Webb. 00:04:22.050 --> 00:04:24.200 align:middle line:90% [MUSIC PLAYING] 00:04:24.200 --> 00:04:29.000 align:middle line:90%