WEBVTT 00:00:00.000 --> 00:00:03.381 align:middle line:90% [MUSIC PLAYING] 00:00:03.381 --> 00:00:13.005 align:middle line:90% 00:00:13.005 --> 00:00:15.130 align:middle line:84% It's been more than a decade since the Hubble Space 00:00:15.130 --> 00:00:19.030 align:middle line:84% Telescope gave us this iconic image of a small slice 00:00:19.030 --> 00:00:20.140 align:middle line:90% of the universe. 00:00:20.140 --> 00:00:22.570 align:middle line:84% With a seemingly countless number of galaxies 00:00:22.570 --> 00:00:24.730 align:middle line:84% and other celestial objects to study, 00:00:24.730 --> 00:00:27.970 align:middle line:84% one of Webb's instruments, NIRSpec, or Near-Inrared 00:00:27.970 --> 00:00:30.190 align:middle line:84% Spectrograph, is uniquely designed 00:00:30.190 --> 00:00:32.409 align:middle line:90% to overcome this challenge. 00:00:32.409 --> 00:00:35.560 align:middle line:84% Joining us now is the James Webb Space Telescope project 00:00:35.560 --> 00:00:37.540 align:middle line:84% scientist for the European Space Agency, 00:00:37.540 --> 00:00:40.427 align:middle line:84% and he's here in Greenbelt, Maryland at the NASA Goddard 00:00:40.427 --> 00:00:41.260 align:middle line:90% Space Flight Center. 00:00:41.260 --> 00:00:42.680 align:middle line:90% Thanks for joining us. 00:00:42.680 --> 00:00:45.220 align:middle line:84% First of all, what exactly is a spectrograph? 00:00:45.220 --> 00:00:48.670 align:middle line:84% A spectrograph can take light of one of its objects 00:00:48.670 --> 00:00:50.740 align:middle line:90% and divide it in its colors. 00:00:50.740 --> 00:00:54.860 align:middle line:84% An astronomer can study how much light is present in each color. 00:00:54.860 --> 00:00:57.040 align:middle line:84% This is what we call a spectrum, and this 00:00:57.040 --> 00:00:59.170 align:middle line:84% is why NIRSpec is called a spectrograph. 00:00:59.170 --> 00:01:00.610 align:middle line:90% So, what do colors tell us? 00:01:00.610 --> 00:01:03.370 align:middle line:84% The colors tell us a lot of things about the object. 00:01:03.370 --> 00:01:06.640 align:middle line:84% It can tell us what it is made of, 00:01:06.640 --> 00:01:09.640 align:middle line:84% how it moves, how far it is from us, 00:01:09.640 --> 00:01:11.540 align:middle line:90% all this type of information. 00:01:11.540 --> 00:01:13.120 align:middle line:84% So, what makes NIRSpec so special? 00:01:13.120 --> 00:01:15.580 align:middle line:84% I'm sure there are other spectrographs up in space. 00:01:15.580 --> 00:01:17.980 align:middle line:84% NIRSpec was the first multi-object spectrograph 00:01:17.980 --> 00:01:19.030 align:middle line:90% in space. 00:01:19.030 --> 00:01:21.490 align:middle line:84% It's able to obtain spectra of multiple objects 00:01:21.490 --> 00:01:22.840 align:middle line:90% at the same time. 00:01:22.840 --> 00:01:25.480 align:middle line:84% How far along are you in building NIRSpec? 00:01:25.480 --> 00:01:28.330 align:middle line:84% We are assembling it, and this is done in Germany 00:01:28.330 --> 00:01:32.050 align:middle line:84% at Astrium, our main contractor, and in fact, it 00:01:32.050 --> 00:01:34.780 align:middle line:84% would be a very good time to go there to see it before we 00:01:34.780 --> 00:01:36.287 align:middle line:90% put the protective cover on it. 00:01:36.287 --> 00:01:38.620 align:middle line:84% Well, thanks a lot for your time and telling us a little 00:01:38.620 --> 00:01:40.270 align:middle line:84% bit about the science of NIRSpec. 00:01:40.270 --> 00:01:41.710 align:middle line:90% Thanks a lot. 00:01:41.710 --> 00:01:42.400 align:middle line:90% Hi, Ralf. 00:01:42.400 --> 00:01:43.600 align:middle line:90% Hi, Mary. 00:01:43.600 --> 00:01:46.240 align:middle line:84% Pierre just gave us a rundown about the science of NIRSpec, 00:01:46.240 --> 00:01:48.820 align:middle line:84% and I was hoping you could tell me more about NIRSpec, 00:01:48.820 --> 00:01:49.600 align:middle line:90% the instrument. 00:01:49.600 --> 00:01:50.830 align:middle line:90% Yes, for sure. 00:01:50.830 --> 00:01:53.210 align:middle line:84% The NIRSpec development is, for the Astrium team, 00:01:53.210 --> 00:01:56.830 align:middle line:84% really fascinating stuff because we have the unique opportunity 00:01:56.830 --> 00:01:59.720 align:middle line:84% to apply new technologies in space. 00:01:59.720 --> 00:02:02.380 align:middle line:84% Is that instrument back there NIRSpec? 00:02:02.380 --> 00:02:04.330 align:middle line:84% This is the first model for NIRSpec, 00:02:04.330 --> 00:02:06.010 align:middle line:84% which we have developed to learn all 00:02:06.010 --> 00:02:09.070 align:middle line:84% about the feasibility of this technology, 00:02:09.070 --> 00:02:10.750 align:middle line:84% but it's not yet the flight model. 00:02:10.750 --> 00:02:13.250 align:middle line:84% The flight model is over here, and we can have a look on it. 00:02:13.250 --> 00:02:14.170 align:middle line:90% Sounds good. 00:02:14.170 --> 00:02:17.350 align:middle line:84% Mary, now here, you see the flight instrument. 00:02:17.350 --> 00:02:18.820 align:middle line:90% The cover is not yet on. 00:02:18.820 --> 00:02:21.910 align:middle line:84% You can do a slight flight through the instrument starting 00:02:21.910 --> 00:02:25.960 align:middle line:84% from the light, which comes from an intermediate focus 00:02:25.960 --> 00:02:26.870 align:middle line:90% from the telescope. 00:02:26.870 --> 00:02:27.370 align:middle line:90% OK. 00:02:27.370 --> 00:02:31.272 align:middle line:84% Goes up there in a periscope, like the submarines. 00:02:31.272 --> 00:02:32.730 align:middle line:84% Yeah, that's what it reminds me of. 00:02:32.730 --> 00:02:33.230 align:middle line:90% Yeah. 00:02:33.230 --> 00:02:35.110 align:middle line:84% Then we are on the other side of the plate, 00:02:35.110 --> 00:02:37.780 align:middle line:84% and then we have another telescope. 00:02:37.780 --> 00:02:40.390 align:middle line:84% And this telescope prepares the image 00:02:40.390 --> 00:02:43.480 align:middle line:84% for the entrance of the spectrograph. 00:02:43.480 --> 00:02:46.630 align:middle line:84% Spectrograph is the area where the light is split up 00:02:46.630 --> 00:02:48.490 align:middle line:90% in its colors. 00:02:48.490 --> 00:02:52.730 align:middle line:84% We should move around and see it from the other side. 00:02:52.730 --> 00:02:55.120 align:middle line:84% So, now we are on the spectrographic part 00:02:55.120 --> 00:02:56.770 align:middle line:90% of the instrument. 00:02:56.770 --> 00:02:58.660 align:middle line:84% The light is spread up in these colors. 00:02:58.660 --> 00:03:02.080 align:middle line:84% These beams are then focused on the detector 00:03:02.080 --> 00:03:04.930 align:middle line:84% with another telescope, which is another three mirrors. 00:03:04.930 --> 00:03:07.630 align:middle line:84% And then we have the colors on the detectors 00:03:07.630 --> 00:03:11.055 align:middle line:84% and can evaluate them further downstream electronically. 00:03:11.055 --> 00:03:13.180 align:middle line:84% Well, thank you so much for showing us or giving us 00:03:13.180 --> 00:03:14.410 align:middle line:90% a guided tour of NIRSpec. 00:03:14.410 --> 00:03:16.150 align:middle line:90% You're welcome. 00:03:16.150 --> 00:03:20.350 align:middle line:84% As you can see, NIRSpec gives astronomers a powerful tool, 00:03:20.350 --> 00:03:24.910 align:middle line:84% a tool that will let astronomers study as many as 100 objects 00:03:24.910 --> 00:03:26.270 align:middle line:90% at the same time. 00:03:26.270 --> 00:03:29.080 align:middle line:84% Thanks for joining us for this edition of Behind the Webb. 00:03:29.080 --> 00:03:32.430 align:middle line:90% [MUSIC PLAYING] 00:03:32.430 --> 00:03:40.000 align:middle line:90%