WEBVTT 00:00:00.000 --> 00:00:01.494 align:middle line:90% [MUSIC PLAYING] 00:00:01.494 --> 00:00:13.460 align:middle line:90% 00:00:13.460 --> 00:00:15.440 align:middle line:84% We are here at the Marshall Space Flight 00:00:15.440 --> 00:00:19.160 align:middle line:84% Center in Huntsville, Alabama, known for its long history 00:00:19.160 --> 00:00:20.600 align:middle line:90% in propulsion research. 00:00:20.600 --> 00:00:23.420 align:middle line:84% But this NASA site is still a big player, 00:00:23.420 --> 00:00:26.810 align:middle line:84% this time for the James Webb Space Telescope. 00:00:26.810 --> 00:00:28.520 align:middle line:84% We're right outside the vacuum chamber 00:00:28.520 --> 00:00:30.680 align:middle line:84% where the mirrors for the Webb Space Telescope 00:00:30.680 --> 00:00:32.090 align:middle line:90% are being tested. 00:00:32.090 --> 00:00:33.800 align:middle line:84% Back in the '90s, this facility was 00:00:33.800 --> 00:00:36.890 align:middle line:84% used to test out one of NASA's great observatories, 00:00:36.890 --> 00:00:39.410 align:middle line:90% the Chandra X-ray Observatory. 00:00:39.410 --> 00:00:41.690 align:middle line:84% We have here the project scientist for Chandra, 00:00:41.690 --> 00:00:42.680 align:middle line:90% Martin Weisskopf. 00:00:42.680 --> 00:00:45.080 align:middle line:84% Can you tell us a little bit about the differences 00:00:45.080 --> 00:00:47.870 align:middle line:84% between Hubble, and Chandra, and James Webb? 00:00:47.870 --> 00:00:49.730 align:middle line:84% These are observatories that look 00:00:49.730 --> 00:00:51.620 align:middle line:84% at different parts of what we call 00:00:51.620 --> 00:00:53.330 align:middle line:90% the electromagnetic spectrum. 00:00:53.330 --> 00:00:57.650 align:middle line:84% That is light at various different energies, from x-rays 00:00:57.650 --> 00:00:59.900 align:middle line:84% where it takes a lot of energy to produce them, 00:00:59.900 --> 00:01:02.240 align:middle line:84% to visible light where the Hubble Space 00:01:02.240 --> 00:01:06.440 align:middle line:84% Telescope operates, and the near infrared where the James Webb 00:01:06.440 --> 00:01:08.090 align:middle line:90% Telescope will operate. 00:01:08.090 --> 00:01:11.030 align:middle line:84% In this way, by studying objects in the universe, 00:01:11.030 --> 00:01:13.430 align:middle line:84% we can learn a lot about them that we 00:01:13.430 --> 00:01:16.400 align:middle line:84% can't learn by just simply looking at one wavelength. 00:01:16.400 --> 00:01:20.210 align:middle line:84% What kind of information can we glean from x-rays? 00:01:20.210 --> 00:01:22.790 align:middle line:84% X-ray astronomy is the system that 00:01:22.790 --> 00:01:26.580 align:middle line:84% brought the first discoveries of black holes in the universe. 00:01:26.580 --> 00:01:30.080 align:middle line:84% So we look at very interesting astronomical objects 00:01:30.080 --> 00:01:31.880 align:middle line:90% at very great distances. 00:01:31.880 --> 00:01:34.940 align:middle line:84% In conjunction with Hubble, Webb will 00:01:34.940 --> 00:01:38.060 align:middle line:84% be looking to identify many Chandra sources that 00:01:38.060 --> 00:01:40.040 align:middle line:90% are not seen with Hubble. 00:01:40.040 --> 00:01:42.020 align:middle line:84% Now we're outside the facility where the mirror 00:01:42.020 --> 00:01:43.550 align:middle line:90% testing is being done. 00:01:43.550 --> 00:01:46.100 align:middle line:84% And you can't help but see this long tube 00:01:46.100 --> 00:01:48.380 align:middle line:84% that is connected to the building itself. 00:01:48.380 --> 00:01:51.770 align:middle line:84% I'm told it's almost six football fields long. 00:01:51.770 --> 00:01:54.440 align:middle line:84% Martin, what was this tube used for? 00:01:54.440 --> 00:01:59.180 align:middle line:84% This tube is very important for separating the telescope that 00:01:59.180 --> 00:02:01.790 align:middle line:84% was on the Chandra X-ray Observatory 00:02:01.790 --> 00:02:05.750 align:middle line:84% from x-ray sources located at the other end of the building. 00:02:05.750 --> 00:02:08.389 align:middle line:84% It has to be this length in order 00:02:08.389 --> 00:02:12.620 align:middle line:84% to make those x-ray sources appear like tiny stars 00:02:12.620 --> 00:02:16.070 align:middle line:84% so that we could determine whether our x-ray telescope 00:02:16.070 --> 00:02:19.160 align:middle line:84% could distinguish small objects in the sky. 00:02:19.160 --> 00:02:20.090 align:middle line:90% Why is it still here? 00:02:20.090 --> 00:02:23.120 align:middle line:84% Chandra was tested in the mid-'90s. 00:02:23.120 --> 00:02:26.000 align:middle line:84% It's still here because it's very, very useful 00:02:26.000 --> 00:02:27.350 align:middle line:90% for many programs. 00:02:27.350 --> 00:02:31.100 align:middle line:84% The vacuum chamber is being used to test the Webb optics. 00:02:31.100 --> 00:02:36.032 align:middle line:84% And we hope to be testing x-ray telescopes in future programs. 00:02:36.032 --> 00:02:37.490 align:middle line:84% Well, thanks for your time, Martin. 00:02:37.490 --> 00:02:39.050 align:middle line:90% You're quite welcome. 00:02:39.050 --> 00:02:41.300 align:middle line:84% The testing here for the Chandra Observatory 00:02:41.300 --> 00:02:44.960 align:middle line:84% ran about six months, from 1996 to 1997. 00:02:44.960 --> 00:02:47.000 align:middle line:84% Then the telescope was sent off to be 00:02:47.000 --> 00:02:49.430 align:middle line:84% integrated with the rest of the observatory. 00:02:49.430 --> 00:02:53.450 align:middle line:84% Chandra was launched on July 23, 1999. 00:02:53.450 --> 00:02:55.430 align:middle line:84% Thanks for joining us for another edition 00:02:55.430 --> 00:02:56.750 align:middle line:90% of Behind the Web. 00:02:56.750 --> 00:02:58.900 align:middle line:90% [MUSIC PLAYING] 00:02:58.900 --> 00:03:08.054 align:middle line:90%