WEBVTT FILE 1 00:00:00.050 --> 00:00:03.080 2 00:00:03.080 --> 00:00:06.110 Hey Facebook, we're live from Goddard Space Flight Center. 3 00:00:06.110 --> 00:00:09.180 I'm Erin Kisliuk with the Hubble Space Telescope. 4 00:00:09.180 --> 00:00:12.310 Did you know that this weekend is the peak of the 5 00:00:12.310 --> 00:00:15.420 Orionid meteor shower? So if you go out and look up and happen 6 00:00:15.420 --> 00:00:18.460 to see a few shooting stars, which you're actually seeing is 7 00:00:18.460 --> 00:00:21.560 debris from Halley's Comet. 8 00:00:21.560 --> 00:00:24.590 In the mid 1700's there was an astronomer named Charles Messier 9 00:00:24.590 --> 00:00:27.690 and he studied comets, but sometimes when he'd go out and look 10 00:00:27.690 --> 00:00:30.810 up, he'd catch these fuzzy images 11 00:00:30.810 --> 00:00:33.960 so he decided to categorize them 12 00:00:33.960 --> 00:00:37.020 and make a list so he would never be 13 00:00:37.020 --> 00:00:40.140 distracted by them ever again. Thus began 14 00:00:40.140 --> 00:00:43.200 the Messier Catalog. Hubble just today released it's own 15 00:00:43.200 --> 00:00:45.320 album full of Messier objects 16 00:00:45.320 --> 00:00:47.600 taken by the space telescope and 17 00:00:47.600 --> 00:00:49.640 we're going to talk about them here today with you. 18 00:00:49.640 --> 00:00:51.690 Make sure to send in questions 19 00:00:51.690 --> 00:00:53.770 and we'll answer them at the end of the show. 20 00:00:53.770 --> 00:00:55.810 I'm going to introduce you to some very special guest. 21 00:00:55.810 --> 00:00:57.920 So today we're joined by Michelle Thaller 22 00:00:57.920 --> 00:01:00.020 and Kevin Hartnett and thank you both for being here today. 23 00:01:00.020 --> 00:01:02.180 Hey, it's great to be here. 24 00:01:02.180 --> 00:01:04.260 All right were are going to jump right on into it. 25 00:01:04.260 --> 00:01:07.330 Who is Charles Messier and why is catalog so cool? 26 00:01:07.330 --> 00:01:10.440 Well Erin you just said, Charles Messier was an astronomer who was active 27 00:01:10.440 --> 00:01:13.580 in the late 1700's and he was really interested in finding 28 00:01:13.580 --> 00:01:15.740 comets, he actually found many of them over 29 00:01:15.740 --> 00:01:17.760 the course of his career, but there was some fuzzy 30 00:01:17.760 --> 00:01:19.850 little blobs in the sky that looked like comets 31 00:01:19.850 --> 00:01:21.950 but he could tell that they weren't comets 32 00:01:21.950 --> 00:01:24.040 because the didn't move with respect to the stars. 33 00:01:24.040 --> 00:01:26.160 Comets appear and disappear 34 00:01:26.160 --> 00:01:28.290 and they actually move with respect to the background stars 35 00:01:28.290 --> 00:01:30.330 but these little fuzzy blobs stayed right 36 00:01:30.330 --> 00:01:32.400 where they were. So he made a catalog 37 00:01:32.400 --> 00:01:34.500 of basically things to avoid 38 00:01:34.500 --> 00:01:36.660 that weren't comets and the thing that is a 39 00:01:36.660 --> 00:01:38.780 wonderful irony is what he actually had 40 00:01:38.780 --> 00:01:40.840 discovered were some of the dramatic and beautiful 41 00:01:40.840 --> 00:01:42.890 objects in the entire universe. 42 00:01:42.890 --> 00:01:44.930 He discovered things like dead 43 00:01:44.930 --> 00:01:46.980 stars or stars being born 44 00:01:46.980 --> 00:01:49.080 or we know now are very distant galaxies. 45 00:01:49.080 --> 00:01:51.140 So in fact Messier found 46 00:01:51.140 --> 00:01:53.250 some of the most fascinating things in the sky. 47 00:01:53.250 --> 00:01:55.390 Yep, what's very 48 00:01:55.390 --> 00:01:57.440 interesting is the first object 49 00:01:57.440 --> 00:01:59.520 that we'll talk about, the Crab Nebula 50 00:01:59.520 --> 00:02:01.610 he was looking actually for the 51 00:02:01.610 --> 00:02:03.730 return of Halley's comet himself 52 00:02:03.730 --> 00:02:05.860 which was predicted to show up in the 53 00:02:05.860 --> 00:02:08.020 constellation of Taurus in that period 54 00:02:08.020 --> 00:02:10.080 and so he was scanning to find 55 00:02:10.080 --> 00:02:12.160 Halley's Comet and came across this object 56 00:02:12.160 --> 00:02:13.250 that we're going to talk about. 57 00:02:13.250 --> 00:02:14.290 So the catalog is 58 00:02:14.290 --> 00:02:16.420 numbered basically in the order that Messier 59 00:02:16.420 --> 00:02:18.540 discovered these things so we are going to 60 00:02:18.540 --> 00:02:20.580 start with M1 and just like Kevin 61 00:02:20.580 --> 00:02:22.700 said M1 is called the Crab Nebula. 62 00:02:22.700 --> 00:02:24.780 So we actually have a depiction here 63 00:02:24.780 --> 00:02:26.860 of where the Crab Nebula is in the sky 64 00:02:26.860 --> 00:02:28.970 and a little bit of what it looks like 65 00:02:28.970 --> 00:02:31.090 see it's actually in the constellation 66 00:02:31.090 --> 00:02:33.130 Taurus, it's going to be honing in on that 67 00:02:33.130 --> 00:02:35.190 and as this begins to pan in 68 00:02:35.190 --> 00:02:37.270 look there's a fuzzy little thing there 69 00:02:37.270 --> 00:02:38.370 and that is what he saw and that 70 00:02:38.370 --> 00:02:39.450 what he thought might me a comet. 71 00:02:39.450 --> 00:02:41.550 But as we pan into even more 72 00:02:41.550 --> 00:02:43.680 you see that there is wonderful dramatic 73 00:02:43.680 --> 00:02:45.750 structure and what this turns out to be 74 00:02:45.750 --> 00:02:47.810 is an exploded star. 75 00:02:47.810 --> 00:02:49.870 It's what we call a super nova ruminant 76 00:02:49.870 --> 00:02:51.920 so there was a star long ago 77 00:02:51.920 --> 00:02:53.950 that exploded and actually spread it's 78 00:02:53.950 --> 00:02:56.070 material over hundreds and hundreds of light years 79 00:02:56.070 --> 00:02:58.230 and in the middle there is the dead 80 00:02:58.230 --> 00:03:00.270 core of a star call a neutron star. 81 00:03:00.270 --> 00:03:02.340 Neutron stars are amazing 82 00:03:02.340 --> 00:03:04.430 they have the density of Mt. Everest 83 00:03:04.430 --> 00:03:06.520 pushed into every teaspoon full of 84 00:03:06.520 --> 00:03:08.740 material and they rotate hundreds 85 00:03:08.740 --> 00:03:10.880 of times a second and I remember 86 00:03:10.880 --> 00:03:12.940 you knew what year this star exploded. 87 00:03:12.940 --> 00:03:15.000 Yes. So historians 88 00:03:15.000 --> 00:03:17.100 have figured out that this 89 00:03:17.100 --> 00:03:19.200 is associated with 90 00:03:19.200 --> 00:03:21.300 the Chinese siting 91 00:03:21.300 --> 00:03:23.460 of a guest star they called it 92 00:03:23.460 --> 00:03:25.520 that was visible, so bright 93 00:03:25.520 --> 00:03:27.590 it could be seen during the day time and 94 00:03:27.590 --> 00:03:29.660 that was 1054 A.D. 95 00:03:29.660 --> 00:03:31.710 So we are very sure when this star actually exploded. 96 00:03:31.710 --> 00:03:33.760 Now Kevin is an amazing 97 00:03:33.760 --> 00:03:35.900 amateur astronomer, he actually takes pictures 98 00:03:35.900 --> 00:03:37.960 of these objects with his own telescope 99 00:03:37.960 --> 00:03:40.020 so should we go to some of the images that you 100 00:03:40.020 --> 00:03:42.110 taken yourself? 101 00:03:42.110 --> 00:03:44.170 Sure why not. In this case 102 00:03:44.170 --> 00:03:46.280 I don't have one of M1 103 00:03:46.280 --> 00:03:48.380 we'll see others but I wanted to show you 104 00:03:48.380 --> 00:03:50.420 both this chart and where M1 105 00:03:50.420 --> 00:03:52.480 can be found. Do you see 106 00:03:52.480 --> 00:03:54.550 the constellation of 107 00:03:54.550 --> 00:03:56.620 Taurus here? 108 00:03:56.620 --> 00:03:58.710 This little cluster of stars 109 00:03:58.710 --> 00:04:00.800 called the Hyades is V shaped 110 00:04:00.800 --> 00:04:02.920 and it marks the horns 111 00:04:02.920 --> 00:04:05.090 of the bull of Taurus. 112 00:04:05.090 --> 00:04:07.150 He's up and to the right of Orion. 113 00:04:07.150 --> 00:04:09.230 Very easily spotted in the winter sky 114 00:04:09.230 --> 00:04:11.320 and you take the 115 00:04:11.320 --> 00:04:13.410 lower horn and look at it 116 00:04:13.410 --> 00:04:15.550 with a telescope and your 117 00:04:15.550 --> 00:04:17.690 sure to find M1 118 00:04:17.690 --> 00:04:19.760 if you sweep around the field 119 00:04:19.760 --> 00:04:21.810 of view with that 120 00:04:21.810 --> 00:04:23.910 star in it because it's very close 121 00:04:23.910 --> 00:04:26.020 to that star named 122 00:04:26.020 --> 00:04:28.140 Zata Tauri. 123 00:04:28.140 --> 00:04:30.230 I want you to 124 00:04:30.230 --> 00:04:32.240 know that in the Hubble catalog 125 00:04:32.240 --> 00:04:34.320 that's been released 126 00:04:34.320 --> 00:04:36.360 we have a star chart like this 127 00:04:36.360 --> 00:04:38.460 for every Messier that's in the catalog. 128 00:04:38.460 --> 00:04:40.600 Even if you don't know 129 00:04:40.600 --> 00:04:42.730 anything about the Messier objects 130 00:04:42.730 --> 00:04:44.780 you'll know basically where to find them in the sky. 131 00:04:44.780 --> 00:04:47.820 What season to look for them in 132 00:04:47.820 --> 00:04:50.900 what constellation they're in and 133 00:04:50.900 --> 00:04:54.010 we also tell you in the album what 134 00:04:54.010 --> 00:04:57.140 telescope is a good one to look for this 135 00:04:57.140 --> 00:05:00.230 object and what time of the month 136 00:05:00.230 --> 00:05:02.290 or what month of the year you should be looking for it. 137 00:05:02.290 --> 00:05:04.370 So keeping with the theme of 138 00:05:04.370 --> 00:05:06.380 dead stars there's another one of my 139 00:05:06.380 --> 00:05:08.440 Messier objects, it's one of my favorites 140 00:05:08.440 --> 00:05:10.580 it's called the Ring Nebula. So we talked about M1 141 00:05:10.580 --> 00:05:12.730 being the first one, this is all the way M57 142 00:05:12.730 --> 00:05:14.770 Now the Ring Nebula is in the 143 00:05:14.770 --> 00:05:16.850 constellation Lyra and this is 144 00:05:16.850 --> 00:05:18.900 actually different, sort of dead star. 145 00:05:18.900 --> 00:05:20.990 The first on exploded violently 146 00:05:20.990 --> 00:05:23.090 in a super nova, this star is 147 00:05:23.090 --> 00:05:25.240 basically, generally unraveling itself 148 00:05:25.240 --> 00:05:27.300 into space. It was a star that was 149 00:05:27.300 --> 00:05:29.370 more about the mass the of sun 150 00:05:29.370 --> 00:05:31.440 it's dying and losing shells of gas 151 00:05:31.440 --> 00:05:33.520 around it. In the middle there's the 152 00:05:33.520 --> 00:05:35.620 remnant of this tiny little star, 153 00:05:35.620 --> 00:05:37.750 which is cooling off and basically dying. 154 00:05:37.750 --> 00:05:39.850 The Ring Nebula is a beautiful object 155 00:05:39.850 --> 00:05:41.900 and you can see some of the complexity 156 00:05:41.900 --> 00:05:43.940 that the Hubble Space Telescope discovered 157 00:05:43.940 --> 00:05:45.970 when it took many different visuals of 158 00:05:45.970 --> 00:05:48.080 this Ring Nebula. 159 00:05:48.080 --> 00:05:50.190 The thing that I really love about the Ring Nebula 160 00:05:50.190 --> 00:05:52.230 is it's not very easy to see 161 00:05:52.230 --> 00:05:54.390 in a telescope, you have to use a special technique 162 00:05:54.390 --> 00:05:56.420 to see it, so tell us a bit about your 163 00:05:56.420 --> 00:05:58.520 observation and how you see an object 164 00:05:58.520 --> 00:05:59.610 like this. 165 00:05:59.610 --> 00:06:01.710 Ok, sure be happy to. 166 00:06:01.710 --> 00:06:03.840 It's one of my favorites, it's a great 167 00:06:03.840 --> 00:06:06.000 summer favorite for amateur astronomer 168 00:06:06.000 --> 00:06:08.040 it's high in the sky and it's 169 00:06:08.040 --> 00:06:10.120 fairly easy to locate 170 00:06:10.120 --> 00:06:12.220 in the constellation of Lyra 171 00:06:12.220 --> 00:06:14.340 but as Michelle said 172 00:06:14.340 --> 00:06:16.470 it's small and a little bit hard to find 173 00:06:16.470 --> 00:06:18.630 and when you a 174 00:06:18.630 --> 00:06:20.690 put in an eye piece that has more 175 00:06:20.690 --> 00:06:22.760 magnification it dims 176 00:06:22.760 --> 00:06:25.850 It gets a little 177 00:06:25.850 --> 00:06:27.970 tricky to see especially the hole that's in 178 00:06:27.970 --> 00:06:30.110 the center. 179 00:06:30.110 --> 00:06:32.160 What you have to do and this a trick 180 00:06:32.160 --> 00:06:34.220 that we amateurs use 181 00:06:34.220 --> 00:06:36.290 is look to the side of the object 182 00:06:36.290 --> 00:06:38.380 because the edge of your eye 183 00:06:38.380 --> 00:06:40.500 is more sensitive to light then 184 00:06:40.500 --> 00:06:42.620 the center is, oddly enough. 185 00:06:42.620 --> 00:06:44.790 You have rods and cones in your eye 186 00:06:44.790 --> 00:06:46.850 and the rods are along 187 00:06:46.850 --> 00:06:48.960 the edge so at night 188 00:06:48.960 --> 00:06:51.000 your peripheral 189 00:06:51.000 --> 00:06:53.090 vision is better then your 190 00:06:53.090 --> 00:06:55.240 center vision and you can see things 191 00:06:55.240 --> 00:06:57.370 that move, so as a trick 192 00:06:57.370 --> 00:06:59.410 we get the object 193 00:06:59.410 --> 00:07:01.480 in the telescope and then 194 00:07:01.480 --> 00:07:03.590 look to the side of the object 195 00:07:03.590 --> 00:07:05.720 and wiggle the telescope a little bit 196 00:07:05.720 --> 00:07:07.870 and you can see it better when you do that. 197 00:07:07.870 --> 00:07:09.940 Especially the hole 198 00:07:09.940 --> 00:07:12.010 in the middle, it looks like a big smoke ring 199 00:07:12.010 --> 00:07:14.080 in sky when you use 200 00:07:14.080 --> 00:07:16.110 those tricks. Now you won't see the center 201 00:07:16.110 --> 00:07:18.170 star because that's pretty faint and 202 00:07:18.170 --> 00:07:20.210 although I took this 203 00:07:20.210 --> 00:07:22.340 photo with just a 204 00:07:22.340 --> 00:07:24.380 general DSLR and 205 00:07:24.380 --> 00:07:26.440 modest telescope 206 00:07:26.440 --> 00:07:28.520 the camera is more sensitive then your 207 00:07:28.520 --> 00:07:30.590 eye and so it can pick up on this star. 208 00:07:30.590 --> 00:07:32.720 You'd need probably 209 00:07:32.720 --> 00:07:34.840 a 14" telescope 210 00:07:34.840 --> 00:07:37.000 to see that star. 211 00:07:37.000 --> 00:07:39.060 So we are going from the theme of dead stars to something now 212 00:07:39.060 --> 00:07:41.110 very different and that is the birth of stars. 213 00:07:41.110 --> 00:07:43.210 Messier discovered things that represent all 214 00:07:43.210 --> 00:07:45.440 the different fazes of the life cycles of stars. 215 00:07:45.440 --> 00:07:48.580 So we're going to start talking about young stars. 216 00:07:48.580 --> 00:07:50.630 Yeah, while we walk over to talk about 217 00:07:50.630 --> 00:07:52.710 the young stars over here, I wanted to remind 218 00:07:52.710 --> 00:07:54.840 everybody to continue to send in questions 219 00:07:54.840 --> 00:07:56.960 we are really great ones. 220 00:07:56.960 --> 00:07:59.100 Were still here at Goddard Space Flight Center talking about 221 00:07:59.100 --> 00:08:01.120 Hubble Messier catalog 222 00:08:01.120 --> 00:08:03.180 and now we're going to be talking about young stars 223 00:08:03.180 --> 00:08:05.240 so take it away, I'll get out of your way. 224 00:08:05.240 --> 00:08:07.330 Well that's right, these are stars that are being born. 225 00:08:07.330 --> 00:08:09.400 The next object we're going to talk about is one of my 226 00:08:09.400 --> 00:08:11.510 favorites in the sky, it's like an old friend 227 00:08:11.510 --> 00:08:13.630 returning every time the fall sky rolls around. 228 00:08:13.630 --> 00:08:15.680 And that's M42, this is the 229 00:08:15.680 --> 00:08:17.760 Orion Nebula and as you can see in this 230 00:08:17.760 --> 00:08:19.790 wonderful animation with the Orion Nebula 231 00:08:19.790 --> 00:08:21.810 really is, is a giant 232 00:08:21.810 --> 00:08:23.890 cloud of dust and gas 233 00:08:23.890 --> 00:08:26.010 and inside it there are stars 234 00:08:26.010 --> 00:08:28.140 forming that are lighting us this cloud. 235 00:08:28.140 --> 00:08:30.180 There are 4 very bright 236 00:08:30.180 --> 00:08:32.220 stars at the very heart of the nebula called 237 00:08:32.220 --> 00:08:34.330 the Trapezium Cluster and these stars 238 00:08:34.330 --> 00:08:36.410 are larger then the Sun. 239 00:08:36.410 --> 00:08:38.430 More massive then the Sun and brighter 240 00:08:38.430 --> 00:08:40.600 and the light from them is lighting up the whole area 241 00:08:40.600 --> 00:08:42.680 that we know of as the Orion Nebula. 242 00:08:42.680 --> 00:08:44.720 To me this is one of the most beautiful images ever taken 243 00:08:44.720 --> 00:08:46.780 by Hubble. It's not only beautiful 244 00:08:46.780 --> 00:08:48.870 but it's very dramatic when you think about 245 00:08:48.870 --> 00:08:50.920 this is a cloud of dust and gas 246 00:08:50.920 --> 00:08:53.030 many, many hundreds of light years across 247 00:08:53.030 --> 00:08:55.080 and inside it there are 248 00:08:55.080 --> 00:08:57.260 dozens, if not hundreds of new stars 249 00:08:57.260 --> 00:08:59.310 forming right now. 250 00:08:59.310 --> 00:09:01.390 So this is a beautiful object and I have to say the image 251 00:09:01.390 --> 00:09:03.430 you took of this is spectacular. 252 00:09:03.430 --> 00:09:05.530 I mean you are an amazing astro-photographer. 253 00:09:05.530 --> 00:09:07.590 Let's take a look at what you got with this on. 254 00:09:07.590 --> 00:09:09.760 Well it is one of one of my 255 00:09:09.760 --> 00:09:11.810 better efforts, but they are all work 256 00:09:11.810 --> 00:09:13.820 and I want to really communicate 257 00:09:13.820 --> 00:09:16.900 that taking pictures 258 00:09:16.900 --> 00:09:19.990 is another aspect of astronomy that is 259 00:09:19.990 --> 00:09:22.000 enjoyable and has it's technical challenges 260 00:09:22.000 --> 00:09:24.140 but I've spent most of my life 261 00:09:24.140 --> 00:09:26.280 observing these things with binoculars or a telescope 262 00:09:26.280 --> 00:09:28.320 and it's as much fun 263 00:09:28.320 --> 00:09:30.380 it's probably more fun then 264 00:09:30.380 --> 00:09:32.440 trying to take pictures of them which is just hard. 265 00:09:32.440 --> 00:09:34.540 So here you see 266 00:09:34.540 --> 00:09:36.670 an image 267 00:09:36.670 --> 00:09:38.780 of Orion Nebula 268 00:09:38.780 --> 00:09:40.860 and I want to point out the contrast between this one 269 00:09:40.860 --> 00:09:42.910 and this one. It took Hubble 270 00:09:42.910 --> 00:09:44.960 about 500 271 00:09:44.960 --> 00:09:46.990 different pointing's 272 00:09:46.990 --> 00:09:49.050 mosaics stitched together to form 273 00:09:49.050 --> 00:09:51.110 this image because Hubble 274 00:09:51.110 --> 00:09:53.140 zooms in and has such 275 00:09:53.140 --> 00:09:55.210 high magnification, it zooms in to 276 00:09:55.210 --> 00:09:57.320 a smaller part of the 277 00:09:57.320 --> 00:09:59.400 object, this could all fit 278 00:09:59.400 --> 00:10:01.500 in the field of view of my telescope. 279 00:10:01.500 --> 00:10:03.610 When you are looking at this object 280 00:10:03.610 --> 00:10:05.760 just with a telescope 281 00:10:05.760 --> 00:10:07.780 and not worried about taking pictures 282 00:10:07.780 --> 00:10:09.940 you want to look for it beneath the 3 283 00:10:09.940 --> 00:10:11.980 stars that form Orion's belt 284 00:10:11.980 --> 00:10:14.110 the sheath for his sword 285 00:10:14.110 --> 00:10:16.200 if you will, right in that 286 00:10:16.200 --> 00:10:18.330 area from a dark spot 287 00:10:18.330 --> 00:10:20.380 you can see a faint cloud 288 00:10:20.380 --> 00:10:22.400 and put a telescope on it 289 00:10:22.400 --> 00:10:24.440 and you can see, right there 290 00:10:24.440 --> 00:10:26.480 is an image of where 291 00:10:26.480 --> 00:10:28.540 M42 is. 292 00:10:28.540 --> 00:10:30.630 Again, this is on our website 293 00:10:30.630 --> 00:10:32.720 so you can find 294 00:10:32.720 --> 00:10:34.900 these for all the Messier objects there. 295 00:10:34.900 --> 00:10:36.940 But you put a telescope 296 00:10:36.940 --> 00:10:38.980 on it and you can see this trapezium 297 00:10:38.980 --> 00:10:41.060 4 little stars in a 298 00:10:41.060 --> 00:10:43.130 trapezoid shape and 299 00:10:43.130 --> 00:10:45.230 enjoy the dark and light bands 300 00:10:45.230 --> 00:10:47.340 of this nebula. It's truly spectacular. 301 00:10:47.340 --> 00:10:49.530 Messier found a number of examples 302 00:10:49.530 --> 00:10:51.600 of young stars, in the case of the Orion 303 00:10:51.600 --> 00:10:53.660 Nebula the stars are still forming 304 00:10:53.660 --> 00:10:55.770 in this cloud of dust and gas 305 00:10:55.770 --> 00:10:57.870 but then there are other stars that are a little farther long 306 00:10:57.870 --> 00:11:00.020 that have moved out of the clouds they 307 00:11:00.020 --> 00:11:02.180 were born in. In many cases 308 00:11:02.180 --> 00:11:04.220 just the radiation and also the particle winds 309 00:11:04.220 --> 00:11:06.270 coming off these birth young stars 310 00:11:06.270 --> 00:11:08.340 blows away the cloud and so the next 311 00:11:08.340 --> 00:11:10.450 thing we are going to is an example of a young 312 00:11:10.450 --> 00:11:12.580 cluster of stars, stars that 313 00:11:12.580 --> 00:11:14.750 all formed probably in the least tens of millions of years. 314 00:11:14.750 --> 00:11:16.790 Doesn't sound very you to us but 315 00:11:16.790 --> 00:11:18.850 for stars that they are and this is a 316 00:11:18.850 --> 00:11:20.880 cluster called the Pleiades and the Pleiades 317 00:11:20.880 --> 00:11:22.970 is a wonderful thing to see to see in the 318 00:11:22.970 --> 00:11:25.090 autumn and winter sky it's always 319 00:11:25.090 --> 00:11:27.250 wonderful for me that wonderful, beautiful 320 00:11:27.250 --> 00:11:29.270 autumn sky is rolling around. 321 00:11:29.270 --> 00:11:31.350 These images look very different, so here's 322 00:11:31.350 --> 00:11:33.440 image that you took of this young cluster of stars 323 00:11:33.440 --> 00:11:35.520 and in fact the Hubble image 324 00:11:35.520 --> 00:11:37.630 has so much resolution 325 00:11:37.630 --> 00:11:39.660 and so much focus that it's only a tiny 326 00:11:39.660 --> 00:11:41.810 part of your image here. Right. 327 00:11:41.810 --> 00:11:43.940 So compare the Hubble image that we have here 328 00:11:43.940 --> 00:11:46.030 with what you were able to see with the Pleiades. 329 00:11:46.030 --> 00:11:48.110 So it's a very tiny portion, the Pleiades 330 00:11:48.110 --> 00:11:50.230 is a naked eye object 331 00:11:50.230 --> 00:11:52.360 and it's somewhat 332 00:11:52.360 --> 00:11:54.400 like 3 or 4 times 333 00:11:54.400 --> 00:11:56.470 the size of the full moon. 334 00:11:56.470 --> 00:11:58.520 It's very big on the sky. 335 00:11:58.520 --> 00:12:00.630 This image 336 00:12:00.630 --> 00:12:02.770 taken by Hubble 337 00:12:02.770 --> 00:12:04.830 of part of the gas and dust 338 00:12:04.830 --> 00:12:07.000 surrounding these stars 339 00:12:07.000 --> 00:12:09.130 is right in between this bright star 340 00:12:09.130 --> 00:12:11.220 called Merope and these two little stars 341 00:12:11.220 --> 00:12:13.310 next to it, so it's a very 342 00:12:13.310 --> 00:12:15.370 tiny portion of 343 00:12:15.370 --> 00:12:17.520 the actual Pleiades. 344 00:12:17.520 --> 00:12:19.570 Pleiades is also known as the 345 00:12:19.570 --> 00:12:21.620 Seven Sisters, a lot of people mistake it for 346 00:12:21.620 --> 00:12:23.690 the Little Dipper, cause it has this 347 00:12:23.690 --> 00:12:25.800 dipper shape. 348 00:12:25.800 --> 00:12:27.860 With your eye you really only see six, there's 349 00:12:27.860 --> 00:12:29.920 this legend of the 350 00:12:29.920 --> 00:12:31.970 missing Pleiad because you don't see 351 00:12:31.970 --> 00:12:34.030 seven but this 352 00:12:34.030 --> 00:12:36.100 cluster is also know in Japan 353 00:12:36.100 --> 00:12:38.170 as Subaru so when you look at the 354 00:12:38.170 --> 00:12:40.260 logo on the back of a Subaru 355 00:12:40.260 --> 00:12:42.350 you're looking at this star pattern, most people 356 00:12:42.350 --> 00:12:44.450 don't know that. 357 00:12:44.450 --> 00:12:46.610 It's a very, very beautiful cluster 358 00:12:46.610 --> 00:12:48.660 and best appreciated 359 00:12:48.660 --> 00:12:50.710 in binoculars or a small telescope 360 00:12:50.710 --> 00:12:52.750 where you can see just 361 00:12:52.750 --> 00:12:54.820 these diamonds 362 00:12:54.820 --> 00:12:56.960 on a black background. 363 00:12:56.960 --> 00:12:59.110 So we're talking about families of stars 364 00:12:59.110 --> 00:13:01.170 and the type of cluster that the Pleiades 365 00:13:01.170 --> 00:13:03.230 is something called an open cluster 366 00:13:03.230 --> 00:13:05.320 these are stars that form relatively close to each other 367 00:13:05.320 --> 00:13:07.410 in one of these big clouds 368 00:13:07.410 --> 00:13:09.510 but the sun was probably in a cluster like this billions 369 00:13:09.510 --> 00:13:11.630 of years ago, but over that time 370 00:13:11.630 --> 00:13:13.790 we've been around the galaxy so many times 371 00:13:13.790 --> 00:13:15.870 that just the gravitational interaction between 372 00:13:15.870 --> 00:13:17.940 the stars have peeled off all the other 373 00:13:17.940 --> 00:13:20.020 members of our star cluster, we don't really know 374 00:13:20.020 --> 00:13:22.180 where in the sky our brother and sister 375 00:13:22.180 --> 00:13:24.300 stars are. So an open cluster 376 00:13:24.300 --> 00:13:26.350 is a family of stars that all formed together 377 00:13:26.350 --> 00:13:28.380 and we're go over and talk a bit more 378 00:13:28.380 --> 00:13:30.490 about some different families of stars now. 379 00:13:30.490 --> 00:13:32.600 Yeah, once again while we're walking 380 00:13:32.600 --> 00:13:34.720 over, I just want to remind everyone to keep 381 00:13:34.720 --> 00:13:36.780 sending in your questions. I'm getting some really 382 00:13:36.780 --> 00:13:38.930 really great ones. 383 00:13:38.930 --> 00:13:40.980 We are here at Goddard Space Flight Center talking about 384 00:13:40.980 --> 00:13:43.070 Hubble's Messier catalog so continue 385 00:13:43.070 --> 00:13:45.150 sending in your question and I'll let you guys talk 386 00:13:45.150 --> 00:13:47.240 about clusters. 387 00:13:47.240 --> 00:13:49.360 Here's another example of an open cluster 388 00:13:49.360 --> 00:13:51.530 this is M11 Wild Duck Cluster. 389 00:13:51.530 --> 00:13:53.600 Open clusters are 390 00:13:53.600 --> 00:13:55.640 stars that form together relatively 391 00:13:55.640 --> 00:13:57.680 recently in the last millions or tens of millions 392 00:13:57.680 --> 00:13:59.800 of years and are slowly peeling apart 393 00:13:59.800 --> 00:14:01.830 over time so this is another one that 394 00:14:01.830 --> 00:14:03.980 you have a very different image 395 00:14:03.980 --> 00:14:06.140 Hubble is taking sort of picture here of the heart 396 00:14:06.140 --> 00:14:08.190 of this cluster and you have picture of the larger 397 00:14:08.190 --> 00:14:10.320 cluster so people can see that. 398 00:14:10.320 --> 00:14:12.450 Right, neither one looks much like a wild duck, do they? 399 00:14:12.450 --> 00:14:14.580 If you had a small 400 00:14:14.580 --> 00:14:16.620 telescope or a pair of binoculars 401 00:14:16.620 --> 00:14:18.630 and looked at this object which is in the summer 402 00:14:18.630 --> 00:14:20.670 sky in the Milky Way 403 00:14:20.670 --> 00:14:22.700 you'll see a V-shaped 404 00:14:22.700 --> 00:14:24.800 grouping of stars 405 00:14:24.800 --> 00:14:26.900 the brighter stars are V-shaped and 406 00:14:26.900 --> 00:14:29.060 reminded the early observers 407 00:14:29.060 --> 00:14:31.120 of a flight of ducks or geese that 408 00:14:31.120 --> 00:14:33.170 are characteristically flying in a V. 409 00:14:33.170 --> 00:14:35.250 When I look at this 410 00:14:35.250 --> 00:14:37.340 and this is one of my favorites too 411 00:14:37.340 --> 00:14:39.430 you notice right away and so did 412 00:14:39.430 --> 00:14:41.460 Messier, he wrote in his catalog 413 00:14:41.460 --> 00:14:43.580 about this that 414 00:14:43.580 --> 00:14:45.590 there is a very bright star 415 00:14:45.590 --> 00:14:47.640 in the center of the cluster. 416 00:14:47.640 --> 00:14:49.710 Hard to make out here because 417 00:14:49.710 --> 00:14:51.790 it just gets lost with all the others. 418 00:14:51.790 --> 00:14:53.920 It's very, very noticeable. 419 00:14:53.920 --> 00:14:55.960 When you look at it in a telescope 420 00:14:55.960 --> 00:14:57.980 this amazing 421 00:14:57.980 --> 00:15:00.020 grouping of stars 422 00:15:00.020 --> 00:15:02.040 and this one bright one 423 00:15:02.040 --> 00:15:04.090 in the middle. Now I found this 424 00:15:04.090 --> 00:15:06.160 cluster is particularly 425 00:15:06.160 --> 00:15:08.240 fun to look at 426 00:15:08.240 --> 00:15:10.340 in higher magnification 427 00:15:10.340 --> 00:15:12.350 and I like to use a zoom eye piece 428 00:15:12.350 --> 00:15:14.490 so I look at it 429 00:15:14.490 --> 00:15:16.650 at low magnification 430 00:15:16.650 --> 00:15:18.710 and the stars are really tight 431 00:15:18.710 --> 00:15:20.780 and then as you twist the eye 432 00:15:20.780 --> 00:15:22.820 piece it zooms in 433 00:15:22.820 --> 00:15:24.930 and you see hundreds more. 434 00:15:24.930 --> 00:15:27.050 It's a remarkable beautiful 435 00:15:27.050 --> 00:15:29.180 open cluster 436 00:15:29.180 --> 00:15:31.260 and there is 437 00:15:31.260 --> 00:15:33.310 something like, oh gee 438 00:15:33.310 --> 00:15:35.390 hundred of stars in the cluster. 439 00:15:35.390 --> 00:15:37.540 That's right an open cluster can have 440 00:15:37.540 --> 00:15:39.680 dozens or hundreds of stars but 441 00:15:39.680 --> 00:15:41.740 there are much larger star cluster as well. 442 00:15:41.740 --> 00:15:43.800 Certainly the largest ones that are in our own 443 00:15:43.800 --> 00:15:45.880 galaxy, the Milky Way, are called the globular clusters. 444 00:15:45.880 --> 00:15:48.050 We have an absolutely spectacular 445 00:15:48.050 --> 00:15:50.160 picture of a globular cluster here. 446 00:15:50.160 --> 00:15:52.190 This is the globular cluster M15 447 00:15:52.190 --> 00:15:54.230 the 15th thing on the list of things that where not comets. 448 00:15:54.230 --> 00:15:56.280 This is actually a cluster of 449 00:15:56.280 --> 00:15:58.340 stars that contains millions of stars. 450 00:15:58.340 --> 00:16:00.400 Now, astronomers believe 451 00:16:00.400 --> 00:16:02.490 that globular clusters are ancient clusters 452 00:16:02.490 --> 00:16:04.550 they probably formed very early on 453 00:16:04.550 --> 00:16:06.670 in the lifetime of our galaxy 454 00:16:06.670 --> 00:16:08.810 and if you think about the Milky Way galaxy 455 00:16:08.810 --> 00:16:10.850 we live in a spiral galaxy that is kind of shaped like a Frisbee. 456 00:16:10.850 --> 00:16:12.900 It's a disk of stars and gas 457 00:16:12.900 --> 00:16:14.950 and dust, but the globular clusters 458 00:16:14.950 --> 00:16:17.050 orbit around the entire 459 00:16:17.050 --> 00:16:19.150 galaxy almost like a swarm 460 00:16:19.150 --> 00:16:21.220 of angry bees. They are going all 461 00:16:21.220 --> 00:16:23.410 different directions around the Milky Way. 462 00:16:23.410 --> 00:16:25.460 In fact globular clusters were one of the 463 00:16:25.460 --> 00:16:27.550 first ways that we discovered our 464 00:16:27.550 --> 00:16:29.560 own place in the Milky Way. 465 00:16:29.560 --> 00:16:31.620 It turns out we are nowhere near the center 466 00:16:31.620 --> 00:16:33.730 of the Milky Way, we live out in the suburbs 467 00:16:33.730 --> 00:16:35.880 about three quarters of the way out into the disk 468 00:16:35.880 --> 00:16:37.940 from the center. So that's a long way from 469 00:16:37.940 --> 00:16:39.980 the middle of the galaxy. 470 00:16:39.980 --> 00:16:42.040 And all these globular clusters orbit around the center 471 00:16:42.040 --> 00:16:44.090 of mass of our galaxy. 472 00:16:44.090 --> 00:16:46.170 Astronomer along time ago realized 473 00:16:46.170 --> 00:16:48.290 that most of the globular clusters were 474 00:16:48.290 --> 00:16:50.310 in one half of the sky 475 00:16:50.310 --> 00:16:52.470 fewer on the other half of the sky and that's 476 00:16:52.470 --> 00:16:54.530 cause we were looking from a vantage point of being very 477 00:16:54.530 --> 00:16:56.560 far out from the center of the galaxy. 478 00:16:56.560 --> 00:16:58.650 When ever I see globular clusters 479 00:16:58.650 --> 00:17:00.750 I really aware of the 480 00:17:00.750 --> 00:17:02.880 place, the roll that they had in 481 00:17:02.880 --> 00:17:05.020 giving us a map as to where we are in the galaxy. 482 00:17:05.020 --> 00:17:07.070 As really good 483 00:17:07.070 --> 00:17:09.120 thing that we're not on a planet inside 484 00:17:09.120 --> 00:17:11.210 a globular cluster cause we wouldn't 485 00:17:11.210 --> 00:17:13.460 see much of the sky at all right? 486 00:17:13.460 --> 00:17:15.600 It would be like daytime all the time. 487 00:17:15.600 --> 00:17:17.660 Just look at all of those stars packed into 488 00:17:17.660 --> 00:17:19.730 that little area. 489 00:17:19.730 --> 00:17:21.820 Yes so it's very good for observing that we are 490 00:17:21.820 --> 00:17:23.940 where are. 491 00:17:23.940 --> 00:17:26.070 See you have another great image here. 492 00:17:26.070 --> 00:17:28.100 Yeah, this image is fun 493 00:17:28.100 --> 00:17:30.150 because I took it two nights ago, right? 494 00:17:30.150 --> 00:17:32.220 495 00:17:32.220 --> 00:17:34.290 I took it with a very small telescope. 496 00:17:34.290 --> 00:17:36.410 497 00:17:36.410 --> 00:17:38.530 It's in the constellation 498 00:17:38.530 --> 00:17:40.650 of Pegasus. 499 00:17:40.650 --> 00:17:42.820 The flying horse, which if you go out 500 00:17:42.820 --> 00:17:42.860 in tonight 501 00:17:42.860 --> 00:17:44.920 in tonight's sky 502 00:17:44.920 --> 00:17:47.030 it will appear as a square 503 00:17:47.030 --> 00:17:49.120 they call the square 504 00:17:49.120 --> 00:17:51.280 Pegasus, very prominent square 505 00:17:51.280 --> 00:17:53.400 in the sky and I like to 506 00:17:53.400 --> 00:17:55.440 consider it like a baseball diamond. 507 00:17:55.440 --> 00:17:57.520 Cause it's oriented that way. 508 00:17:57.520 --> 00:17:59.620 This object is located 509 00:17:59.620 --> 00:18:01.710 off first base 510 00:18:01.710 --> 00:18:03.860 and there is a 511 00:18:03.860 --> 00:18:06.040 L-shaped string of stars 512 00:18:06.040 --> 00:18:08.120 is right at the tip of the L. 513 00:18:08.120 --> 00:18:10.130 It's very easy to find. Right there. There you go. 514 00:18:10.130 --> 00:18:12.250 So we've been talking about families 515 00:18:12.250 --> 00:18:14.360 of stars, the star clusters and in fact 516 00:18:14.360 --> 00:18:16.480 the largest families of stars in the universe 517 00:18:16.480 --> 00:18:18.520 are the galaxies. 518 00:18:18.520 --> 00:18:20.590 These are families of stars that include hundreds 519 00:18:20.590 --> 00:18:22.670 of billions of stars. 520 00:18:22.670 --> 00:18:24.740 So let's talk a bit about some of the galaxies 521 00:18:24.740 --> 00:18:25.860 that we are looking at. 522 00:18:25.860 --> 00:18:27.960 While we walk over to the biggest 523 00:18:27.960 --> 00:18:30.130 screen in the room, we'll talk about the biggest objects, right? 524 00:18:30.130 --> 00:18:32.180 I just want to remind everybody 525 00:18:32.180 --> 00:18:34.350 once again we're here at Goddard. 526 00:18:34.350 --> 00:18:36.440 We're talking about Hubble's Messier objects 527 00:18:36.440 --> 00:18:38.540 and please continue to send in your questions, 528 00:18:38.540 --> 00:18:41.670 we've got a ton of good ones and I'll let you talk about galaxies. 529 00:18:41.670 --> 00:18:44.720 Sounds good, yes, right. 530 00:18:44.720 --> 00:18:46.790 We're going to end with looking at some of these beautiful 531 00:18:46.790 --> 00:18:48.870 spiral galaxies and the first one we are looking at 532 00:18:48.870 --> 00:18:50.970 is something the Whirlpool galaxy which is know 533 00:18:50.970 --> 00:18:53.030 as M51 and the 534 00:18:53.030 --> 00:18:55.150 Whirlpool galaxy is a spiral galaxy 535 00:18:55.150 --> 00:18:57.210 about half the size of our own Milky Way 536 00:18:57.210 --> 00:18:59.280 and is at a distance of about 537 00:18:59.280 --> 00:19:01.360 23 million light years away. 538 00:19:01.360 --> 00:19:03.440 You can see here in this beautiful 539 00:19:03.440 --> 00:19:05.530 Hubble image the detail on the spiral 540 00:19:05.530 --> 00:19:07.650 arms of this galaxy. 541 00:19:07.650 --> 00:19:09.780 The dark areas are actually lanes of gas 542 00:19:09.780 --> 00:19:11.820 and dust where new stars are forming 543 00:19:11.820 --> 00:19:13.920 inside that right now. In fact, 544 00:19:13.920 --> 00:19:16.000 when ever you see red areas along the spiral 545 00:19:16.000 --> 00:19:18.110 arm, that's active star formation. 546 00:19:18.110 --> 00:19:20.260 That's where young stars are still embedded 547 00:19:20.260 --> 00:19:22.260 in the dust and they are lighting up the 548 00:19:22.260 --> 00:19:24.310 dust and making glow red. 549 00:19:24.310 --> 00:19:26.340 It is an absolutely beautiful spiral. 550 00:19:26.340 --> 00:19:28.370 The thing that is amazing about 551 00:19:28.370 --> 00:19:30.490 this, is looks quite different 552 00:19:30.490 --> 00:19:32.530 through a telescope and some people might be 553 00:19:32.530 --> 00:19:34.640 disappointed but I still think it's a wonder thing to look at. 554 00:19:34.640 --> 00:19:36.800 So tell us a bit about what it's like to observe 555 00:19:36.800 --> 00:19:38.840 a beautiful galaxy like this. 556 00:19:38.840 --> 00:19:40.900 I tell you, it's fun 557 00:19:40.900 --> 00:19:42.970 to glimpse these things 558 00:19:42.970 --> 00:19:45.030 even if you're not seeing them particularly 559 00:19:45.030 --> 00:19:47.140 clearly in the night sky. 560 00:19:47.140 --> 00:19:49.270 There's a 561 00:19:49.270 --> 00:19:51.440 connection with the universe 562 00:19:51.440 --> 00:19:53.500 by looking at the light of 563 00:19:53.500 --> 00:19:55.560 these things with your own eye. 564 00:19:55.560 --> 00:19:58.660 Just like Messier would have 565 00:19:58.660 --> 00:20:01.760 seen this, it was a smudge but know you know 566 00:20:01.760 --> 00:20:04.870 what it really is and that's electrifying. 567 00:20:04.870 --> 00:20:08.070 If you're, at night, searching for these 568 00:20:08.070 --> 00:20:11.140 things with your telescope and finding 569 00:20:11.140 --> 00:20:14.220 it and realizing what you're seeing 570 00:20:14.220 --> 00:20:17.360 there is nothing really quite like it. 571 00:20:17.360 --> 00:20:20.420 Messier would not have seen the spiral arms 572 00:20:20.420 --> 00:20:23.480 because you need a large a telescope 573 00:20:23.480 --> 00:20:26.550 to do that and his telescopes where not 574 00:20:26.550 --> 00:20:28.630 very good, they weren't even made of glass. 575 00:20:28.630 --> 00:20:30.730 The ones that we use now 576 00:20:30.730 --> 00:20:32.790 with mirrors, the mirrors were made out of metal 577 00:20:32.790 --> 00:20:34.830 back then and we've 578 00:20:34.830 --> 00:20:36.860 looked at these globular clusters 579 00:20:36.860 --> 00:20:38.920 in M15 580 00:20:38.920 --> 00:20:41.000 Messier noted he didn't see one 581 00:20:41.000 --> 00:20:43.070 star in that globular cluster 582 00:20:43.070 --> 00:20:45.170 that we now know has 583 00:20:45.170 --> 00:20:47.420 millions of stars. 584 00:20:47.420 --> 00:20:50.470 So his view was very very different. 585 00:20:50.470 --> 00:20:53.510 This is an image I took, it took about 4 hours 586 00:20:53.510 --> 00:20:55.570 to layup that image. In a second 587 00:20:55.570 --> 00:20:57.650 I'll show you what one little frame looked like. 588 00:20:57.650 --> 00:20:59.740 But this object was 589 00:20:59.740 --> 00:21:01.860 not seen by Messier 590 00:21:01.860 --> 00:21:03.990 at the time, it's a neighboring galaxy. 591 00:21:03.990 --> 00:21:06.040 He only saw the very 592 00:21:06.040 --> 00:21:08.070 core of this and it looked like a little blob. 593 00:21:08.070 --> 00:21:10.130 So the thing is 594 00:21:10.130 --> 00:21:12.200 even if your telescope image 595 00:21:12.200 --> 00:21:14.310 doesn't look like this, it's still wonderful 596 00:21:14.310 --> 00:21:16.390 to think the lights your looking, even when you see a little 597 00:21:16.390 --> 00:21:18.520 smudge on the sky, in this case it's 598 00:21:18.520 --> 00:21:20.570 23 millions years old. 599 00:21:20.570 --> 00:21:22.630 23 million light years away. means the light 600 00:21:22.630 --> 00:21:24.710 took that long to get to us so when you see 601 00:21:24.710 --> 00:21:26.830 this beautiful as just a smudge 602 00:21:26.830 --> 00:21:28.950 in the sky, that light left long before 603 00:21:28.950 --> 00:21:31.100 there were humans on the earth. 604 00:21:31.100 --> 00:21:33.160 You mention you were going to show us 605 00:21:33.160 --> 00:21:35.250 so this is what you'd see through even a large telescope. 606 00:21:35.250 --> 00:21:37.340 Yeah, this was taken through a 8" diameter 607 00:21:37.340 --> 00:21:39.420 telescope and it took 608 00:21:39.420 --> 00:21:41.460 I'm trying to remember now, about 3 minutes 609 00:21:41.460 --> 00:21:43.480 or 4 minutes to layup this particular 610 00:21:43.480 --> 00:21:45.560 image and you see you get 611 00:21:45.560 --> 00:21:47.600 all the light pollution 612 00:21:47.600 --> 00:21:49.630 right? The sky glow in the back 613 00:21:49.630 --> 00:21:51.670 too. The trick 614 00:21:51.670 --> 00:21:53.760 that amateurs use 615 00:21:53.760 --> 00:21:55.840 is to stack 616 00:21:55.840 --> 00:21:57.930 all these up, line them up 617 00:21:57.930 --> 00:22:00.040 and so I took, what ever, 4 hours 618 00:22:00.040 --> 00:22:02.220 of 3 minute exposures 619 00:22:02.220 --> 00:22:04.290 and you can get software free off the web 620 00:22:04.290 --> 00:22:06.370 now to align them all and stack 621 00:22:06.370 --> 00:22:08.450 them up and you learn some about processing. 622 00:22:08.450 --> 00:22:10.550 Honestly, 623 00:22:10.550 --> 00:22:12.660 although I don't want you to think 624 00:22:12.660 --> 00:22:14.660 that your going to see these marvelous images, 625 00:22:14.660 --> 00:22:16.700 the pictures 626 00:22:16.700 --> 00:22:18.760 from Hubble or even my telescope 627 00:22:18.760 --> 00:22:20.810 by looking through the eye piece. 628 00:22:20.810 --> 00:22:22.890 It is encouraging 629 00:22:22.890 --> 00:22:25.000 or it should be encouraging you that, I've only been 630 00:22:25.000 --> 00:22:27.130 at astro-photography for maybe 4 years 631 00:22:27.130 --> 00:22:29.290 with a digital camera 632 00:22:29.290 --> 00:22:31.330 and so you can learn very quickly with a lot of 633 00:22:31.330 --> 00:22:33.390 resources on the web but 634 00:22:33.390 --> 00:22:35.490 start with the Hubble site. 635 00:22:35.490 --> 00:22:37.590 You can find out where the Messier's 636 00:22:37.590 --> 00:22:39.630 are in the sky 637 00:22:39.630 --> 00:22:41.790 and what instrument to use 638 00:22:41.790 --> 00:22:43.840 look at them and once you get more 639 00:22:43.840 --> 00:22:45.900 familiar with the sky, like I've done over many 640 00:22:45.900 --> 00:22:47.980 years then dabble in astro-photography. 641 00:22:47.980 --> 00:22:50.070 So we are going to wrap up our 642 00:22:50.070 --> 00:22:52.140 catalog of the Messier objects 643 00:22:52.140 --> 00:22:54.280 with one of the most beautiful things in the sky called 644 00:22:54.280 --> 00:22:56.380 the Andromeda galaxy, this is M31 645 00:22:56.380 --> 00:22:59.450 and I have to say Kevin this your image. 646 00:22:59.450 --> 00:23:02.530 This is absolutely spectacular. The Andromeda 647 00:23:02.530 --> 00:23:05.740 galaxy is a galaxy very much like the Milky Way 648 00:23:05.740 --> 00:23:07.790 it's a distance of a little bit more then 2 million light years away. 649 00:23:07.790 --> 00:23:09.880 The thing that is amazing about the Andromeda 650 00:23:09.880 --> 00:23:11.910 galaxy is that edge to edge this 651 00:23:11.910 --> 00:23:13.930 is as large on the sky as 652 00:23:13.930 --> 00:23:15.970 three full moons. 653 00:23:15.970 --> 00:23:18.020 Think about lining full moon up 654 00:23:18.020 --> 00:23:20.140 across that galaxy. 655 00:23:20.140 --> 00:23:22.270 At night when this thing is up, there's this 656 00:23:22.270 --> 00:23:24.320 giant galaxy actually covering a fairly large 657 00:23:24.320 --> 00:23:26.380 part of our sky but the reason we don't see 658 00:23:26.380 --> 00:23:28.440 it's very faint and in fact 659 00:23:28.440 --> 00:23:30.490 Messier could only see the very very central 660 00:23:30.490 --> 00:23:32.540 part of the galaxy but this other objects 661 00:23:32.540 --> 00:23:35.710 in here as well that Messier saw 662 00:23:35.710 --> 00:23:38.760 in this gorgeous image that you took. Tell us about that. 663 00:23:38.760 --> 00:23:41.810 Wouldn't we all had eyes to see this 664 00:23:41.810 --> 00:23:44.880 thing in the sky hanging 665 00:23:44.880 --> 00:23:47.960 there in the autumn sky as big 666 00:23:47.960 --> 00:23:51.060 as 6 full moons across, right? 667 00:23:51.060 --> 00:23:54.100 It's just an amazingly big object. 668 00:23:54.100 --> 00:23:57.250 It's faint because it's a long way away. 669 00:23:57.250 --> 00:24:00.320 So when you look at this in a telescope 670 00:24:00.320 --> 00:24:03.380 or with binoculars, in fact you can see this object 671 00:24:03.380 --> 00:24:06.480 with the naked eye from a dark place. 672 00:24:06.480 --> 00:24:09.620 You're really only seeing the very bright core 673 00:24:09.620 --> 00:24:12.750 but that is what you'll see in a scope 674 00:24:12.750 --> 00:24:15.810 or binoculars. Very fun to see. 675 00:24:15.810 --> 00:24:18.880 I remember dragging my whole family when I was maybe 15 676 00:24:18.880 --> 00:24:21.980 and it was in the winter and 677 00:24:21.980 --> 00:24:25.100 I said, now that I found you have to see it so 678 00:24:25.100 --> 00:24:28.230 it was like 20 degrees out, drag all my sisters out 679 00:24:28.230 --> 00:24:31.290 to see this thing because it's just 680 00:24:31.290 --> 00:24:34.340 it's a classic. It's very spectacular. 681 00:24:34.340 --> 00:24:37.360 This object, Messier also found probably within 682 00:24:37.360 --> 00:24:40.470 the same night that he looked at M31. 683 00:24:40.470 --> 00:24:43.520 This is called M32. 684 00:24:43.520 --> 00:24:46.660 Again, very easy to see because it's so close to N31 685 00:24:46.660 --> 00:24:49.700 and it looks like a slightly out of focus star. 686 00:24:49.700 --> 00:24:52.740 Little harder to see is this on down here 687 00:24:52.740 --> 00:24:55.770 a companion galaxy, now known as 688 00:24:55.770 --> 00:24:58.890 M110 you have to use that 689 00:24:58.890 --> 00:25:01.930 little trick I mention earlier, looking to the 690 00:25:01.930 --> 00:25:05.090 side of M110 to see it more clearly. I like to 691 00:25:05.090 --> 00:25:08.180 take people out and show them Andromeda 692 00:25:08.180 --> 00:25:11.230 through the telescope, it's very easy to see this 693 00:25:11.230 --> 00:25:14.340 little harder to see this and they have to really work to see 694 00:25:14.340 --> 00:25:17.490 M110 so it's a great learning experience. 695 00:25:17.490 --> 00:25:19.550 Going to the Hubble image of Andromeda, 696 00:25:19.550 --> 00:25:21.630 this is something that is kind of mind blowing. 697 00:25:21.630 --> 00:25:23.690 Hubble is so powerful that it can see the individual 698 00:25:23.690 --> 00:25:25.790 stars in this galaxy 699 00:25:25.790 --> 00:25:27.880 2 million light years away. 700 00:25:27.880 --> 00:25:29.950 Now this galaxy contains hundreds of 701 00:25:29.950 --> 00:25:32.100 billions of stars and when you look 702 00:25:32.100 --> 00:25:34.150 this image there is kind of graininess to the image 703 00:25:34.150 --> 00:25:36.230 and that is real. These are all individual 704 00:25:36.230 --> 00:25:38.300 stars that Hubble can pick out. 705 00:25:38.300 --> 00:25:40.410 Now the amazing thing, it Hubble over 706 00:25:40.410 --> 00:25:42.520 400 pointing's to stitch 707 00:25:42.520 --> 00:25:44.670 together this giant mosaic of Andromeda 708 00:25:44.670 --> 00:25:46.680 and in fact Hubble only had the time 709 00:25:46.680 --> 00:25:48.760 to image about 1/3 of the galaxy. 710 00:25:48.760 --> 00:25:50.840 So think about that. More then 711 00:25:50.840 --> 00:25:52.910 400 Hubble images all put together in a 712 00:25:52.910 --> 00:25:55.010 mosaic to cover just about 1/3 713 00:25:55.010 --> 00:25:57.130 of the Andromeda galaxy. 714 00:25:57.130 --> 00:25:59.200 That's amazing thing to see and an 715 00:25:59.200 --> 00:26:01.270 incredible Messier object. 716 00:26:01.270 --> 00:26:03.330 Hopefully in talking about these wonderful 717 00:26:03.330 --> 00:26:05.420 objects you can see in the sky, things like 718 00:26:05.420 --> 00:26:07.460 dead stars, stars being born, 719 00:26:07.460 --> 00:26:09.720 galaxy, star clusters. You might want to 720 00:26:09.720 --> 00:26:11.800 go out and look at them yourself and this is 721 00:26:11.800 --> 00:26:13.860 where Kevin is the expert and he's going to talk to you 722 00:26:13.860 --> 00:26:15.910 a bit about what you can do, to go out 723 00:26:15.910 --> 00:26:18.010 and make your own Messier catalog. 724 00:26:18.010 --> 00:26:20.110 So you brought some telescopes here so let's go 725 00:26:20.110 --> 00:26:22.270 over here and take a look at this. 726 00:26:22.270 --> 00:26:24.420 727 00:26:24.420 --> 00:26:26.450 So I should probably start here. 728 00:26:26.450 --> 00:26:28.510 Because 729 00:26:28.510 --> 00:26:30.570 from a dark sky 730 00:26:30.570 --> 00:26:32.660 you can see 731 00:26:32.660 --> 00:26:34.760 most of the Messier 732 00:26:34.760 --> 00:26:36.900 objects with a good pair of binoculars. 733 00:26:36.900 --> 00:26:38.940 From the Washington, DC 734 00:26:38.940 --> 00:26:40.970 area maybe a 735 00:26:40.970 --> 00:26:43.050 quarter of them but if you're out 736 00:26:43.050 --> 00:26:45.140 in a dark spot you can see 737 00:26:45.140 --> 00:26:47.250 many of these so get yourself 738 00:26:47.250 --> 00:26:49.380 a star chart like this 739 00:26:49.380 --> 00:26:51.470 and find 740 00:26:51.470 --> 00:26:53.500 them or use the star charts that 741 00:26:53.500 --> 00:26:55.580 are on the Hubble 742 00:26:55.580 --> 00:26:57.740 site and you'll 743 00:26:57.740 --> 00:26:59.850 know where to look. 744 00:26:59.850 --> 00:27:01.890 It's good to use a set of 745 00:27:01.890 --> 00:27:04.060 binoculars at night that's, 746 00:27:04.060 --> 00:27:06.130 one like this. 747 00:27:06.130 --> 00:27:08.190 This is a 10x50 748 00:27:08.190 --> 00:27:10.230 10 is the magnification 749 00:27:10.230 --> 00:27:12.330 50 is the size and milometer 750 00:27:12.330 --> 00:27:14.380 of the glass up front. 751 00:27:14.380 --> 00:27:16.550 Most of us have 7x35 at home they're 752 00:27:16.550 --> 00:27:18.580 great for terrestrial viewing, 753 00:27:18.580 --> 00:27:20.670 looking at things in the yard 754 00:27:20.670 --> 00:27:22.720 or what ever. 755 00:27:22.720 --> 00:27:24.820 But you want a little more power and you want to 756 00:27:24.820 --> 00:27:26.920 gather more light because the stars are faint. 757 00:27:26.920 --> 00:27:29.040 You want this 758 00:27:29.040 --> 00:27:29.200 lens to be as big as you can hold 759 00:27:29.200 --> 00:27:32.270 lens to be as big as you can hold steady. 760 00:27:32.270 --> 00:27:35.340 That's the other caveat, right? 761 00:27:35.340 --> 00:27:37.380 So if you get to heavy of a binocular you can't hold it steady 762 00:27:37.380 --> 00:27:39.490 and you won't get a very good view. 763 00:27:39.490 --> 00:27:41.620 So just 2 other representitives 764 00:27:41.620 --> 00:27:43.660 scopes you might 765 00:27:43.660 --> 00:27:45.710 be fascinated to know that the 766 00:27:45.710 --> 00:27:47.750 beautiful that I took 767 00:27:47.750 --> 00:27:50.830 and the one of the Pleiades was taken with 768 00:27:50.830 --> 00:27:53.890 almost exactly this size, it wasn't this particular one 769 00:27:53.890 --> 00:27:55.990 but I had it mounted on the back 770 00:27:55.990 --> 00:27:58.120 of a larger scope and more 771 00:27:58.120 --> 00:28:00.170 expensive mount that was tracking the star 772 00:28:00.170 --> 00:28:02.220 cause again I had to layup these time 773 00:28:02.220 --> 00:28:04.290 exposures. But you can enjoy 774 00:28:04.290 --> 00:28:06.450 the Pleiades and the Orion 775 00:28:06.450 --> 00:28:09.580 nebula and M31 776 00:28:09.580 --> 00:28:12.710 all as beautiful objects in a scope this size. 777 00:28:12.710 --> 00:28:15.780 Our website says 778 00:28:15.780 --> 00:28:18.860 for each individual object it's best seen or 779 00:28:18.860 --> 00:28:21.940 can be see with a large, medium, or small 780 00:28:21.940 --> 00:28:25.050 telescope. This is what we mean by small. 781 00:28:25.050 --> 00:28:28.190 Up to 3 or 4 inches. 782 00:28:28.190 --> 00:28:30.220 Medium would be more in the class of a 6 783 00:28:30.220 --> 00:28:32.280 to 10 inch diameter telescope. 784 00:28:32.280 --> 00:28:34.360 The size of the 785 00:28:34.360 --> 00:28:36.440 lens again is 786 00:28:36.440 --> 00:28:38.530 the size of the 787 00:28:38.530 --> 00:28:40.650 it's what collecting 788 00:28:40.650 --> 00:28:42.830 the light so think of it as you eyeball. 789 00:28:42.830 --> 00:28:44.920 Imagine your eyeball being 8 790 00:28:44.920 --> 00:28:46.960 inches wide, you'd collect a lot more light. 791 00:28:46.960 --> 00:28:49.000 Then larger scopes, 792 00:28:49.000 --> 00:28:51.120 we didn't have room on set to bring it in here, 793 00:28:51.120 --> 00:28:54.260 can be 10, 12, 16 794 00:28:54.260 --> 00:28:56.330 some amateurs have 20 inch telescopes, 795 00:28:56.330 --> 00:28:58.370 great big things. But the get 796 00:28:58.370 --> 00:29:00.500 obviously difficult to move around. 797 00:29:00.500 --> 00:29:02.610 So 798 00:29:02.610 --> 00:29:04.640 each has their own price range 799 00:29:04.640 --> 00:29:06.760 and pros and cons 800 00:29:06.760 --> 00:29:08.910 read up on a web site that describes 801 00:29:08.910 --> 00:29:10.970 telescopes before buying one and really I 802 00:29:10.970 --> 00:29:13.040 recommend learning your constellations, 803 00:29:13.040 --> 00:29:15.090 finding Messier objects 804 00:29:15.090 --> 00:29:17.150 with a binocular and then 805 00:29:17.150 --> 00:29:19.260 stepping up as your interest continues. 806 00:29:19.260 --> 00:29:21.400 Here's a zoom eye piece 807 00:29:21.400 --> 00:29:23.440 that I was mentioning before 808 00:29:23.440 --> 00:29:25.480 so you just twist it and it 809 00:29:25.480 --> 00:29:27.530 magnifies so you don't have to keep 810 00:29:27.530 --> 00:29:29.630 reaching for different eye pieces. 811 00:29:29.630 --> 00:29:31.720 If you do want to do that 812 00:29:31.720 --> 00:29:33.750 there are many different types 813 00:29:33.750 --> 00:29:35.910 and 814 00:29:35.910 --> 00:29:37.950 it just makes it easier, I find it easier 815 00:29:37.950 --> 00:29:40.000 to just zoom in. Interesting 816 00:29:40.000 --> 00:29:42.060 Charles Messier, he 817 00:29:42.060 --> 00:29:44.170 looked through about every telescope he could get his 818 00:29:44.170 --> 00:29:46.260 hands on and 819 00:29:46.260 --> 00:29:48.390 they were very good 820 00:29:48.390 --> 00:29:50.470 and they didn't have eye pieces 821 00:29:50.470 --> 00:29:52.550 The eye piece they had weren't 822 00:29:52.550 --> 00:29:54.580 replaceable, I should say 823 00:29:54.580 --> 00:29:56.650 they were a fixed magnification. 824 00:29:56.650 --> 00:29:58.770 Interesting different. 825 00:29:58.770 --> 00:30:00.810 Before we go on to some questions from the audience 826 00:30:00.810 --> 00:30:02.940 the question I have for you is how many Messier 827 00:30:02.940 --> 00:30:04.990 objects have you personally seen? 828 00:30:04.990 --> 00:30:07.040 Oh boy! Yeah so. 829 00:30:07.040 --> 00:30:09.120 I've seen just about all of them. 830 00:30:09.120 --> 00:30:11.180 We didn't talk about tonight but there's a 831 00:30:11.180 --> 00:30:13.290 large group of galaxies 832 00:30:13.290 --> 00:30:16.440 in the constellation Coma Berenices 833 00:30:16.440 --> 00:30:19.510 off the tail of Leo and next to Virgo 834 00:30:19.510 --> 00:30:22.570 where there are just 835 00:30:22.570 --> 00:30:24.650 literally scores of galaxies. 836 00:30:24.650 --> 00:30:26.730 Some of them are Messier objects 837 00:30:26.730 --> 00:30:28.770 many of them are not. They didn't make his list. 838 00:30:28.770 --> 00:30:30.880 So I've looked at that cluster 839 00:30:30.880 --> 00:30:33.030 and when you 840 00:30:33.030 --> 00:30:35.080 look through the field of view 841 00:30:35.080 --> 00:30:37.150 you might see 2 or 3 Messier objects 842 00:30:37.150 --> 00:30:39.240 but 2 or 3 that are almost 843 00:30:39.240 --> 00:30:41.320 as bright that he missed somehow. 844 00:30:41.320 --> 00:30:43.450 I've seen 845 00:30:43.450 --> 00:30:45.490 them all, I haven't cataloged 846 00:30:45.490 --> 00:30:47.550 all but I'm starting to do that 847 00:30:47.550 --> 00:30:49.610 now, it kind of a bucket list thing 848 00:30:49.610 --> 00:30:51.650 for me. If you write 849 00:30:51.650 --> 00:30:53.730 down the day, time, and scope 850 00:30:53.730 --> 00:30:55.820 that you used and details 851 00:30:55.820 --> 00:30:57.930 about the sky 852 00:30:57.930 --> 00:30:59.990 and send that log 853 00:30:59.990 --> 00:31:02.000 to the Astronomical League 854 00:31:02.000 --> 00:31:04.060 you can get a certificate. 855 00:31:04.060 --> 00:31:06.110 Which is really cool. Say you've seen all 856 00:31:06.110 --> 00:31:08.170 the Messier objects. So I'm now 857 00:31:08.170 --> 00:31:10.250 logging them all, I've probably seen them all. 858 00:31:10.250 --> 00:31:12.370 But I didn't log them all. 859 00:31:12.370 --> 00:31:14.430 Excellent! Before we go we have some 860 00:31:14.430 --> 00:31:15.450 time for questions. 861 00:31:15.450 --> 00:31:17.600 Yeah, we do and it seems like we have a couple 862 00:31:17.600 --> 00:31:19.640 Messier collection 863 00:31:19.640 --> 00:31:21.690 hopefuls in here. 864 00:31:21.690 --> 00:31:23.760 We have one question asking, 865 00:31:23.760 --> 00:31:25.860 what is the best kind of telescope for 866 00:31:25.860 --> 00:31:27.990 a beginner? While we are over here we might as well 867 00:31:27.990 --> 00:31:30.110 start with the telescope questions, yeah? 868 00:31:30.110 --> 00:31:32.170 The best answer I've heard to that question is 869 00:31:32.170 --> 00:31:34.250 one that you use. OK? 870 00:31:34.250 --> 00:31:36.340 So it can't be to heavy, it can't be 871 00:31:36.340 --> 00:31:38.460 too complicated, 872 00:31:38.460 --> 00:31:40.570 can't be to expensive. 873 00:31:40.570 --> 00:31:42.700 Right? If you're just a beginner. 874 00:31:42.700 --> 00:31:44.760 Because you want to get your feet wet. 875 00:31:44.760 --> 00:31:46.850 Right? 876 00:31:46.850 --> 00:31:48.920 Realize I really can find things. 877 00:31:48.920 --> 00:31:51.020 Enjoy them and then 878 00:31:51.020 --> 00:31:53.160 move up from there. 879 00:31:53.160 --> 00:31:55.190 I find ones that have this 880 00:31:55.190 --> 00:31:57.230 style of mount helpful. 881 00:31:57.230 --> 00:32:00.290 It's called a azimuth and 882 00:32:00.290 --> 00:32:03.340 elevation and so it's very intuitive to just 883 00:32:03.340 --> 00:32:05.440 swing it around and bring it up 884 00:32:05.440 --> 00:32:07.550 and look for your object in the 885 00:32:07.550 --> 00:32:09.670 one of these types of telescopes. 886 00:32:09.670 --> 00:32:11.740 I think this a good choice 887 00:32:11.740 --> 00:32:13.790 not maybe this big but 888 00:32:13.790 --> 00:32:15.870 an azimuth elevation kind of 889 00:32:15.870 --> 00:32:17.940 mount on the telescope. 890 00:32:17.940 --> 00:32:20.040 Then similar we got a different question 891 00:32:20.040 --> 00:32:22.160 from someone else asking, what are the best 892 00:32:22.160 --> 00:32:24.200 kind of binoculars for back yard astronomy? 893 00:32:24.200 --> 00:32:26.260 Yeah, well again a 894 00:32:26.260 --> 00:32:28.340 I would say shoot for something 895 00:32:28.340 --> 00:32:30.380 like a 10x50 896 00:32:30.380 --> 00:32:32.440 like these 897 00:32:32.440 --> 00:32:34.480 and not to heavy. 898 00:32:34.480 --> 00:32:36.570 If you get much heavier then this they 899 00:32:36.570 --> 00:32:38.700 sell stands you can put them on 900 00:32:38.700 --> 00:32:40.790 but you'll want something to steady them. 901 00:32:40.790 --> 00:32:42.850 I think a 10x50 is a 902 00:32:42.850 --> 00:32:44.900 pretty good size for most places. 903 00:32:44.900 --> 00:32:46.970 That's always my problem but I love using binoculars 904 00:32:46.970 --> 00:32:49.090 but it's hard to keep them steady in your hands. 905 00:32:49.090 --> 00:32:51.140 So people have techniques like resting your 906 00:32:51.140 --> 00:32:53.300 elbows on knees 907 00:32:53.300 --> 00:32:55.350 and steadying that way or actually going up against 908 00:32:55.350 --> 00:32:57.400 a wall. That's one of the harder things, learning to 909 00:32:57.400 --> 00:32:59.410 steady the image. Right. 910 00:32:59.410 --> 00:33:01.590 Speaking of images maybe we'll come out here 911 00:33:01.590 --> 00:33:02.680 so we can see some more of these 912 00:33:02.680 --> 00:33:03.780 images in the background 913 00:33:03.780 --> 00:33:04.910 while we take a few more questions. 914 00:33:04.910 --> 00:33:05.950 Watch your step. 915 00:33:05.950 --> 00:33:08.010 Kelly wants to know, what 916 00:33:08.010 --> 00:33:10.060 causes new stars to move 917 00:33:10.060 --> 00:33:12.240 away from the cloud that they were born in? 918 00:33:12.240 --> 00:33:14.370 Well there are a lot of reasons for this. 919 00:33:14.370 --> 00:33:16.500 There an intrinsic movement of the stars. 920 00:33:16.500 --> 00:33:18.560 That when stars form they pick 921 00:33:18.560 --> 00:33:20.620 up angular momentum, they begin to spin 922 00:33:20.620 --> 00:33:22.680 and the clusters of stars spin in different ways too. 923 00:33:22.680 --> 00:33:24.770 Over time this can actually spin some 924 00:33:24.770 --> 00:33:26.890 of the stars out of the cluster entirely. 925 00:33:26.890 --> 00:33:29.000 The other thing to remember is that star clusters 926 00:33:29.000 --> 00:33:31.180 never live just by themselves. 927 00:33:31.180 --> 00:33:33.250 We go around the galaxy. 928 00:33:33.250 --> 00:33:35.310 Right now we actually flying around the center 929 00:33:35.310 --> 00:33:37.400 of the Milky Way galaxy at about a 930 00:33:37.400 --> 00:33:39.420 half a million miles an hour. 931 00:33:39.420 --> 00:33:41.550 Good thing we don't actually feel that. 932 00:33:41.550 --> 00:33:43.600 As the Sun moves around the galaxy it has 933 00:33:43.600 --> 00:33:45.640 very gentle gravitation encounters 934 00:33:45.640 --> 00:33:47.700 with other stars. Over billions 935 00:33:47.700 --> 00:33:49.860 of years, over many passes around 936 00:33:49.860 --> 00:33:52.950 the galaxy, this spreads the cluster out. 937 00:33:52.950 --> 00:33:54.990 We've left probably some of our sister stars 938 00:33:54.990 --> 00:33:57.130 way on the other side of the galaxy. 939 00:33:57.130 --> 00:33:59.200 The star formed right near us but now 940 00:33:59.200 --> 00:34:01.250 it's 100 thousand light years away. 941 00:34:01.250 --> 00:34:03.300 And that's just the regular gravitational attraction 942 00:34:03.300 --> 00:34:05.380 of the different stars as we move through the galaxy. 943 00:34:05.380 --> 00:34:06.920 Great! It seems like these clusters 944 00:34:06.920 --> 00:34:08.970 kind of resonated with people. 945 00:34:08.970 --> 00:34:11.030 Someone else wanted to know, 946 00:34:11.030 --> 00:34:13.110 how far away are stars 947 00:34:13.110 --> 00:34:15.210 in a cluster? 948 00:34:15.210 --> 00:34:17.340 That's an interesting question. I don't have an exact number 949 00:34:17.340 --> 00:34:19.380 for some of the clusters that we've been showing you. 950 00:34:19.380 --> 00:34:21.480 But as Kevin mentioned, if you were in a globular 951 00:34:21.480 --> 00:34:23.530 cluster. If you were in a planet 952 00:34:23.530 --> 00:34:25.630 around a star in the heart of a globular 953 00:34:25.630 --> 00:34:27.680 cluster, the night sky would be 954 00:34:27.680 --> 00:34:29.780 brilliantly bright. So the closest 955 00:34:29.780 --> 00:34:31.900 star to us is about 4 light years away 956 00:34:31.900 --> 00:34:34.080 and in the heart of a globular cluster 957 00:34:34.080 --> 00:34:36.150 it would be a lot closer then that. 958 00:34:36.150 --> 00:34:38.230 I don't have an exact number but I do know 959 00:34:38.230 --> 00:34:40.330 the night sky would look a lot different. 960 00:34:40.330 --> 00:34:42.430 4 light years is a long way. 961 00:34:42.430 --> 00:34:44.570 Right? And so 962 00:34:44.570 --> 00:34:46.610 I've read if 963 00:34:46.610 --> 00:34:48.670 you considered the volume 964 00:34:48.670 --> 00:34:50.730 of sphere 965 00:34:50.730 --> 00:34:52.830 this 4 light years in 966 00:34:52.830 --> 00:34:54.960 radius some of these globular 967 00:34:54.960 --> 00:34:57.100 cluster there could be as many as 968 00:34:57.100 --> 00:34:59.140 10 thousand stars within that 969 00:34:59.140 --> 00:35:01.200 970 00:35:01.200 --> 00:35:03.280 that sphere and so 971 00:35:03.280 --> 00:35:05.310 imagine being on a planet around one of those 972 00:35:05.310 --> 00:35:07.420 973 00:35:07.420 --> 00:35:09.540 it would be just dazzling. 974 00:35:09.540 --> 00:35:11.700 And then another question. 975 00:35:11.700 --> 00:35:13.740 This one looks it's specifically 976 00:35:13.740 --> 00:35:15.800 for Kevin. How do you deal with light pollution? 977 00:35:15.800 --> 00:35:17.880 Yes... Well 978 00:35:17.880 --> 00:35:19.960 I cry a lot I guess is the answer. 979 00:35:19.960 --> 00:35:22.000 [Laughter] 980 00:35:22.000 --> 00:35:24.240 If you have a 981 00:35:24.240 --> 00:35:27.290 portable telescope which some of my are. 982 00:35:27.290 --> 00:35:29.350 You get to a dark spot. In that way 983 00:35:29.350 --> 00:35:31.430 you can just enjoy the night sky and 984 00:35:31.430 --> 00:35:33.540 find things easier. 985 00:35:33.540 --> 00:35:35.630 Taking pictures, see 986 00:35:35.630 --> 00:35:37.740 is one of the strategies that I have 987 00:35:37.740 --> 00:35:39.780 to fight light pollution because 988 00:35:39.780 --> 00:35:41.840 you can play tricks with a digital camera. 989 00:35:41.840 --> 00:35:43.910 Digital camera is very very 990 00:35:43.910 --> 00:35:45.950 sensitive as you've seen in these 991 00:35:45.950 --> 00:35:48.050 images and so 992 00:35:48.050 --> 00:35:50.160 you can play these tricks 993 00:35:50.160 --> 00:35:52.300 about stacking up photos 994 00:35:52.300 --> 00:35:54.340 and processing them and get these 995 00:35:54.340 --> 00:35:56.400 amazing results. I live north 996 00:35:56.400 --> 00:35:58.480 of Washington, DC where it's very 997 00:35:58.480 --> 00:36:00.590 bright and yet 998 00:36:00.590 --> 00:36:02.690 you can play these tricks 999 00:36:02.690 --> 00:36:04.810 with a digital camera. 1000 00:36:04.810 --> 00:36:06.880 Some of the same tricks Hubble 1001 00:36:06.880 --> 00:36:08.960 plays actually. 1002 00:36:08.960 --> 00:36:11.040 Taking an image 1003 00:36:11.040 --> 00:36:13.070 and then basically covering 1004 00:36:13.070 --> 00:36:15.170 the shutter 1005 00:36:15.170 --> 00:36:17.280 and putting up a black 1006 00:36:17.280 --> 00:36:19.350 cover on the telescope 1007 00:36:19.350 --> 00:36:21.390 and taking another image. You'd say 1008 00:36:21.390 --> 00:36:23.470 why would you do that? You record the 1009 00:36:23.470 --> 00:36:25.540 noise in the camera 1010 00:36:25.540 --> 00:36:27.610 and then there is software 1011 00:36:27.610 --> 00:36:29.710 that you can use to subtract off the noise 1012 00:36:29.710 --> 00:36:31.830 so this is the way to fight light 1013 00:36:31.830 --> 00:36:33.960 pollution. You subtract it off with 1014 00:36:33.960 --> 00:36:36.030 a digital camera. Can't do that with your eye. 1015 00:36:36.030 --> 00:36:38.110 But Hubble plays that same trick. 1016 00:36:38.110 --> 00:36:40.170 Not to fight light pollution so much but 1017 00:36:40.170 --> 00:36:42.290 just to get that noise that is 1018 00:36:42.290 --> 00:36:44.390 inherent in the camera because of it's 1019 00:36:44.390 --> 00:36:46.390 thermal qualities 1020 00:36:46.390 --> 00:36:48.550 and subtract that out. 1021 00:36:48.550 --> 00:36:50.590 It's amazing to me just how much we are missing with 1022 00:36:50.590 --> 00:36:52.670 light pollution. The most beautiful sky I've ever saw 1023 00:36:52.670 --> 00:36:54.750 was when I was in Chile, I was in the 1024 00:36:54.750 --> 00:36:56.850 Atacama desert where there were no lights around at all 1025 00:36:56.850 --> 00:36:59.000 and somebody pointed out that 1026 00:36:59.000 --> 00:37:01.080 the Milky Way was so bright over head 1027 00:37:01.080 --> 00:37:03.110 it was making me cry. It was so beautiful 1028 00:37:03.110 --> 00:37:05.190 I was getting tears in my eyes. I looked down 1029 00:37:05.190 --> 00:37:07.290 at the ground and someone pointed out that I was 1030 00:37:07.290 --> 00:37:09.380 casting a very dim shadow on the ground. 1031 00:37:09.380 --> 00:37:11.520 But there was no moon out that night, 1032 00:37:11.520 --> 00:37:13.680 none of the bright planets were out that night 1033 00:37:13.680 --> 00:37:15.730 I was actually a shadow being cast by the Milk Way. 1034 00:37:15.730 --> 00:37:17.780 That's how bright the Milky Way can get. 1035 00:37:17.780 --> 00:37:19.950 So get yourself 1036 00:37:19.950 --> 00:37:23.080 to a dark sky if you possible can. 1037 00:37:23.080 --> 00:37:25.150 Wow! That's crazy. So we have a question 1038 00:37:25.150 --> 00:37:27.210 about Hubble specifically. 1039 00:37:27.210 --> 00:37:29.290 How does Hubble take so many sharp 1040 00:37:29.290 --> 00:37:31.350 images when it's moving so fast? 1041 00:37:31.350 --> 00:37:33.450 Pointing. I think 1042 00:37:33.450 --> 00:37:35.550 I'll leave this to the Hubble operation manager. 1043 00:37:35.550 --> 00:37:37.690 Absolutely. That's for you Kev. Yes no. 1044 00:37:37.690 --> 00:37:39.700 You don't think about it much 1045 00:37:39.700 --> 00:37:41.760 that would be more of a problem if 1046 00:37:41.760 --> 00:37:43.810 the stars were closer but they're 1047 00:37:43.810 --> 00:37:45.870 so far away that the light 1048 00:37:45.870 --> 00:37:48.080 that's coming anywhere Earth 1049 00:37:48.080 --> 00:37:51.210 is coming in parallel beams. 1050 00:37:51.210 --> 00:37:54.300 And so, yes Hubble is moving around the Earth 1051 00:37:54.300 --> 00:37:57.390 but it's still seeing these 1052 00:37:57.390 --> 00:37:59.410 parallel beams that come from these 1053 00:37:59.410 --> 00:38:01.510 distant stars. 1054 00:38:01.510 --> 00:38:03.540 If an object was closer like 1055 00:38:03.540 --> 00:38:05.660 the moon, 1056 00:38:05.660 --> 00:38:07.720 you don't see many Hubble pictures 1057 00:38:07.720 --> 00:38:09.730 of the moon do you? See, 1058 00:38:09.730 --> 00:38:11.820 Hubble was never designed to look at the moon. 1059 00:38:11.820 --> 00:38:13.890 Now we've 1060 00:38:13.890 --> 00:38:15.930 over the years that Hubble's been operating 1061 00:38:15.930 --> 00:38:18.010 we know have modes that can but they are very 1062 00:38:18.010 --> 00:38:20.120 seldom used because you have a 1063 00:38:20.120 --> 00:38:22.160 what they have a parallax problem. 1064 00:38:22.160 --> 00:38:24.200 The moon is to close 1065 00:38:24.200 --> 00:38:26.250 and Hubble is moving to fast 1066 00:38:26.250 --> 00:38:28.320 that light beams aren't coming to you 1067 00:38:28.320 --> 00:38:30.390 in a parallel fashion. 1068 00:38:30.390 --> 00:38:32.450 And so, the secret is 1069 00:38:32.450 --> 00:38:34.570 the stars are so far way. 1070 00:38:34.570 --> 00:38:36.630 Wow that fascinating. 1071 00:38:36.630 --> 00:38:38.760 Some asked, what is the best 1072 00:38:38.760 --> 00:38:40.810 telescope for astro-photography? 1073 00:38:40.810 --> 00:38:42.850 OK.I don't know how to answer that 1074 00:38:42.850 --> 00:38:44.870 question, that's why I'm asking you. 1075 00:38:44.870 --> 00:38:46.930 [laughter] 1076 00:38:46.930 --> 00:38:48.990 There is different types of targets 1077 00:38:48.990 --> 00:38:51.070 what we've been calling 1078 00:38:51.070 --> 00:38:53.190 these ones would be classified as 1079 00:38:53.190 --> 00:38:55.290 deep space objects 1080 00:38:55.290 --> 00:38:57.350 (DOS's). There's also like the moon 1081 00:38:57.350 --> 00:38:59.400 and planets. You would 1082 00:38:59.400 --> 00:39:01.480 want a different type of telescope 1083 00:39:01.480 --> 00:39:03.540 to do lunar and 1084 00:39:03.540 --> 00:39:05.670 planetary work then you would 1085 00:39:05.670 --> 00:39:07.810 for deep sky objects. 1086 00:39:07.810 --> 00:39:09.840 And so that's part of the answer. 1087 00:39:09.840 --> 00:39:11.880 For deep sky objects I think 1088 00:39:11.880 --> 00:39:13.960 most web sites 1089 00:39:13.960 --> 00:39:16.040 I would go to and people more 1090 00:39:16.040 --> 00:39:18.150 experience then I at this would say 1091 00:39:18.150 --> 00:39:20.300 get medium size 1092 00:39:20.300 --> 00:39:22.350 refracting telescope. 1093 00:39:22.350 --> 00:39:24.400 It's the type that has the lens up front. 1094 00:39:24.400 --> 00:39:26.480 With a 1095 00:39:26.480 --> 00:39:28.540 fairly short focal length 1096 00:39:28.540 --> 00:39:30.650 and that will probably do the best 1097 00:39:30.650 --> 00:39:32.750 for you for these things. 1098 00:39:32.750 --> 00:39:34.800 Lot's of reason why 1099 00:39:34.800 --> 00:39:36.850 those kind of telescope can 1100 00:39:36.850 --> 00:39:38.910 range from the $600 that I bought 1101 00:39:38.910 --> 00:39:40.990 to $6000 so 1102 00:39:40.990 --> 00:39:43.020 you kind of go with your budget too. 1103 00:39:43.020 --> 00:39:45.110 And so much of it appears to be in the way you process the images. 1104 00:39:45.110 --> 00:39:47.160 I mean you image of Andromeda was 1105 00:39:47.160 --> 00:39:49.280 spectacular. I remember when I first saw it 1106 00:39:49.280 --> 00:39:51.460 we were rehearsing for this, I said that was something 1107 00:39:51.460 --> 00:39:53.540 that the Mt Wilson telescope would have taken 1108 00:39:53.540 --> 00:39:55.600 a 100 years ago. That would have been the best 1109 00:39:55.600 --> 00:39:57.680 astronomical image in the world but here you did this out of the 1110 00:39:57.680 --> 00:39:59.790 small scope. Yeah, there it is. 1111 00:39:59.790 --> 00:40:01.930 So that has to do a lot with what you do 1112 00:40:01.930 --> 00:40:03.980 with the imagery afterwards too. 1113 00:40:03.980 --> 00:40:06.050 So true. Yes 1114 00:40:06.050 --> 00:40:08.120 The more you stack the more signals 1115 00:40:08.120 --> 00:40:10.220 noise you get and the more you learn 1116 00:40:10.220 --> 00:40:12.310 about Photoshop and 1117 00:40:12.310 --> 00:40:14.460 these other processing techniques. 1118 00:40:14.460 --> 00:40:16.520 They just 1119 00:40:16.520 --> 00:40:18.580 the better you get at it. I really consider myself 1120 00:40:18.580 --> 00:40:20.660 a baby at it. 1121 00:40:20.660 --> 00:40:22.740 This one again was about a 4 hours exposure. 1122 00:40:22.740 --> 00:40:24.800 1123 00:40:24.800 --> 00:40:26.850 Many many times more then 1124 00:40:26.850 --> 00:40:29.000 4 hours in processing. 1125 00:40:29.000 --> 00:40:31.050 And you only have been doing this about 4 years. 1126 00:40:31.050 --> 00:40:33.130 Yep. It's because there's so many resources online. 1127 00:40:33.130 --> 00:40:35.180 We're bringing you the 1128 00:40:35.180 --> 00:40:37.220 Hubble Messier catalog 1129 00:40:37.220 --> 00:40:39.340 online with all its information 1130 00:40:39.340 --> 00:40:41.440 there's lots and lots of helpful 1131 00:40:41.440 --> 00:40:43.480 resources out there about astro-photography. 1132 00:40:43.480 --> 00:40:45.650 The Messier catalog is 1133 00:40:45.650 --> 00:40:47.720 such an inspiration to me, sort of wrapping 1134 00:40:47.720 --> 00:40:49.810 it all up again, we talk about avoiding these things that 1135 00:40:49.810 --> 00:40:51.880 aren't comets but instead 1136 00:40:51.880 --> 00:40:54.020 it turns out to be the catalog of wonders. 1137 00:40:54.020 --> 00:40:56.100 Everything from dead stars to baby stars to 1138 00:40:56.100 --> 00:40:58.140 these vast galaxies that you took a picture of 1139 00:40:58.140 --> 00:41:00.190 well in some strange way we have 1140 00:41:00.190 --> 00:41:02.260 Charles Messier even though 1141 00:41:02.260 --> 00:41:04.350 it wasn't what he was looking for. 1142 00:41:04.350 --> 00:41:06.470 Yes, he found 13 1143 00:41:06.470 --> 00:41:08.620 comets on his own. 1144 00:41:08.620 --> 00:41:10.800 Remarkable for the instruments he had and 1145 00:41:10.800 --> 00:41:11.860 operating from the center of Paris. 1146 00:41:11.860 --> 00:41:12.960 Can you imagine it? 1147 00:41:12.960 --> 00:41:16.060 In an observatory there and he 1148 00:41:16.060 --> 00:41:19.160 co-discovered 7 others with 1149 00:41:19.160 --> 00:41:22.300 his friends. So the man found 20 1150 00:41:22.300 --> 00:41:25.360 comets in his lifetime. 1151 00:41:25.360 --> 00:41:27.420 Very remarkable for the instruments he had 1152 00:41:27.420 --> 00:41:29.510 and the place he was doing it from. 1153 00:41:29.510 --> 00:41:31.600 Try to discover one from the center of Paris right now. 1154 00:41:31.600 --> 00:41:33.730 Pretty hard to do. OK. 1155 00:41:33.730 --> 00:41:35.880 Are you ready for another question? Sure! 1156 00:41:35.880 --> 00:41:37.930 Alahondra wants to know what are your favorite 1157 00:41:37.930 --> 00:41:39.950 locations for stargazing? I guess I can ask both 1158 00:41:39.950 --> 00:41:42.030 of you that question. 1159 00:41:42.030 --> 00:41:44.110 Well I just mention the Atacama Desert but that's kind 1160 00:41:44.110 --> 00:41:46.220 hard to get to. So it is 1161 00:41:46.220 --> 00:41:48.360 amazing to me how much you actually 1162 00:41:48.360 --> 00:41:50.420 can see from a relatively dark back yard. 1163 00:41:50.420 --> 00:41:52.480 If you can get yourself to a nice clear 1164 00:41:52.480 --> 00:41:54.540 horizon. I've seen comets 1165 00:41:54.540 --> 00:41:56.620 through small binoculars. 1166 00:41:56.620 --> 00:41:58.710 I've seen small telescopes where you can see the rings 1167 00:41:58.710 --> 00:42:00.830 of Saturn. Saturn in particular 1168 00:42:00.830 --> 00:42:02.990 is an object a lot closer to us 1169 00:42:02.990 --> 00:42:05.050 then the Messier objects are but 1170 00:42:05.050 --> 00:42:07.110 this is one of the things where if you're a little disappointed 1171 00:42:07.110 --> 00:42:09.210 by the Andromeda galaxy just being a smudge. 1172 00:42:09.210 --> 00:42:11.300 When you see Saturn and it's rings 1173 00:42:11.300 --> 00:42:13.420 right there in front of you and the moons of Saturn 1174 00:42:13.420 --> 00:42:15.570 as well, that's something that just floored 1175 00:42:15.570 --> 00:42:17.630 me the first time I saw it. It looked like somebody 1176 00:42:17.630 --> 00:42:19.700 had taken a picture of Saturn from a textbook and 1177 00:42:19.700 --> 00:42:21.760 just kind of pasted on the end of the telescope. 1178 00:42:21.760 --> 00:42:23.890 So some of these objects are very easy to 1179 00:42:23.890 --> 00:42:25.950 see, they are very bright 1180 00:42:25.950 --> 00:42:28.090 don't need a dark sky to see them. 1181 00:42:28.090 --> 00:42:30.130 Yeah that's right. 1182 00:42:30.130 --> 00:42:32.190 The moon and planets 1183 00:42:32.190 --> 00:42:34.220 in even a very modest size scope 1184 00:42:34.220 --> 00:42:36.330 can be a 1185 00:42:36.330 --> 00:42:39.360 unforgettable 1186 00:42:39.360 --> 00:42:41.490 experience. 1187 00:42:41.490 --> 00:42:43.660 As you mentioned, seeing the rings of Saturn 1188 00:42:43.660 --> 00:42:45.710 I've been at so many 1189 00:42:45.710 --> 00:42:47.760 star parties, we call them, we have telescopes 1190 00:42:47.760 --> 00:42:49.850 out and have fun with 1191 00:42:49.850 --> 00:42:51.940 the heavens. 1192 00:42:51.940 --> 00:42:54.060 It's so fun to see people 1193 00:42:54.060 --> 00:42:56.230 see the moon or the planets 1194 00:42:56.230 --> 00:42:58.360 Saturn or Jupiter with it's 1195 00:42:58.360 --> 00:43:01.380 moons and bands for the first time. 1196 00:43:01.380 --> 00:43:03.380 They never forget it. I never forget it. 1197 00:43:03.380 --> 00:43:05.490 That's what got me into astronomy 1198 00:43:05.490 --> 00:43:07.600 many, many years ago 1199 00:43:07.600 --> 00:43:09.740 seeing Saturn 1200 00:43:09.740 --> 00:43:11.800 there is connection with the universe 1201 00:43:11.800 --> 00:43:13.870 that you feel and it's really 1202 00:43:13.870 --> 00:43:15.940 unforgettable. Where would I go 1203 00:43:15.940 --> 00:43:18.040 around here? I have a brother-in-law 1204 00:43:18.040 --> 00:43:20.150 that lives down in Virginia in the mountains 1205 00:43:20.150 --> 00:43:22.290 and so that's a good spot to go 1206 00:43:22.290 --> 00:43:24.330 and the eastern shore is pretty 1207 00:43:24.330 --> 00:43:26.370 good dark spot with nice horizons. 1208 00:43:26.370 --> 00:43:28.420 So you can see things 1209 00:43:28.420 --> 00:43:30.510 from horizon to horizon 1210 00:43:30.510 --> 00:43:32.560 but if I were going to pay money and go some 1211 00:43:32.560 --> 00:43:34.660 place it would probably Chile or someplace like that 1212 00:43:34.660 --> 00:43:36.840 or Hawaii 1213 00:43:36.840 --> 00:43:39.910 to have, be on top of a mountain 1214 00:43:39.910 --> 00:43:42.950 where all the other great telescopes are 1215 00:43:42.950 --> 00:43:44.020 and observe from there. 1216 00:43:44.020 --> 00:43:45.200 One thing I have to say is take advantage of 1217 00:43:45.200 --> 00:43:47.320 your local amateur astronomy societies. 1218 00:43:47.320 --> 00:43:49.380 Because pretty much where ever you are in the US 1219 00:43:49.380 --> 00:43:51.430 there is local club where if don't know what 1220 00:43:51.430 --> 00:43:52.480 sort of telescope you'd like 1221 00:43:52.480 --> 00:43:53.570 or you don't know how to use a telescope 1222 00:43:53.570 --> 00:43:55.600 if you don't where the nearest dark sky 1223 00:43:55.600 --> 00:43:57.710 areas are around you. Your local astronomy 1224 00:43:57.710 --> 00:43:59.840 club will know these things. And they are an 1225 00:43:59.840 --> 00:44:02.010 incredible resource. As a professional 1226 00:44:02.010 --> 00:44:04.070 astronomer I would go to these large 1227 00:44:04.070 --> 00:44:06.140 observatories and people would type coordinates 1228 00:44:06.140 --> 00:44:08.230 in the computers and I would make my observations 1229 00:44:08.230 --> 00:44:10.350 I often feel that the amateur astronomy 1230 00:44:10.350 --> 00:44:12.650 community are the real astronomers. 1231 00:44:12.650 --> 00:44:13.710 They're the people who really know the sky 1232 00:44:13.710 --> 00:44:14.750 like the back of their hand. 1233 00:44:14.750 --> 00:44:15.800 Right. 1234 00:44:15.800 --> 00:44:17.900 Amateur astronomy 1235 00:44:17.900 --> 00:44:19.990 groups will also 1236 00:44:19.990 --> 00:44:22.100 love to show you telescopes 1237 00:44:22.100 --> 00:44:24.250 and so you can try 1238 00:44:24.250 --> 00:44:26.320 before you buy. If you 1239 00:44:26.320 --> 00:44:28.370 go to a club and that's 1240 00:44:28.370 --> 00:44:29.410 also helpful. 1241 00:44:29.410 --> 00:44:30.510 Great! 1242 00:44:30.510 --> 00:44:31.640 It's kind of like asking someone about 1243 00:44:31.640 --> 00:44:32.760 their job, 1244 00:44:32.760 --> 00:44:33.920 asking someone about their telescope 1245 00:44:33.920 --> 00:44:34.970 they can talk for days. 1246 00:44:34.970 --> 00:44:37.010 So unfortunately we only have time for 1247 00:44:37.010 --> 00:44:39.110 one more question. 1248 00:44:39.110 --> 00:44:41.200 We're going to keep answering some of your questions on 1249 00:44:41.200 --> 00:44:43.370 Facebook as they are coming in later on but 1250 00:44:43.370 --> 00:44:45.540 unfortunately we only have so much camera time so. 1251 00:44:45.540 --> 00:44:47.600 One more question. 1252 00:44:47.600 --> 00:44:49.670 What is your favorite object you've view 1253 00:44:49.670 --> 00:44:51.740 through a telescope? 1254 00:44:51.740 --> 00:44:53.860 Awe, it's like choosing between your children. 1255 00:44:53.860 --> 00:44:55.910 Oh wow. OK so I guess. 1256 00:44:55.910 --> 00:44:57.960 We just mentioned Saturn 1257 00:44:57.960 --> 00:45:00.100 so I think that actually is my favorite. 1258 00:45:00.100 --> 00:45:02.180 In the southern sky 1259 00:45:02.180 --> 00:45:04.280 there is something called the Carina nebula 1260 00:45:04.280 --> 00:45:06.400 and the Carina nebula is an area where 1261 00:45:06.400 --> 00:45:08.520 can see star birth and star death 1262 00:45:08.520 --> 00:45:10.660 all happening at once. There are young 1263 00:45:10.660 --> 00:45:12.720 clusters of stars, then there's a star called 1264 00:45:12.720 --> 00:45:14.790 Eta Carinae which is very close 1265 00:45:14.790 --> 00:45:16.840 we think to blowing itself up in a supernova 1266 00:45:16.840 --> 00:45:18.950 explosion. This part of the sky 1267 00:45:18.950 --> 00:45:21.090 has these vast bands of 1268 00:45:21.090 --> 00:45:23.270 dark dust and bright gas 1269 00:45:23.270 --> 00:45:24.310 and I have to say 1270 00:45:24.310 --> 00:45:25.360 those are some of the things that I've 1271 00:45:25.360 --> 00:45:26.420 seen with my own eyes 1272 00:45:26.420 --> 00:45:27.540 when I was living in the southern hemisphere 1273 00:45:27.540 --> 00:45:29.790 that just blew me away. 1274 00:45:29.790 --> 00:45:30.930 I mean this is probably the closest thing 1275 00:45:30.930 --> 00:45:31.990 I've seen with my 1276 00:45:31.990 --> 00:45:33.100 naked eyes looking through a telescope 1277 00:45:33.100 --> 00:45:35.180 that looked like a Hubble image. 1278 00:45:35.180 --> 00:45:37.270 Eda Carinae would have to be one of my favorites. 1279 00:45:37.270 --> 00:45:39.300 Yeah and for me 1280 00:45:39.300 --> 00:45:41.410 It is like deciding between 1281 00:45:41.410 --> 00:45:43.560 your children I guess. 1282 00:45:43.560 --> 00:45:45.590 I really love to look 1283 00:45:45.590 --> 00:45:47.630 visually at M11 1284 00:45:47.630 --> 00:45:49.690 that Wild Duck cluster. 1285 00:45:49.690 --> 00:45:51.780 Because when you first look at it in the scope 1286 00:45:51.780 --> 00:45:53.880 you can 1287 00:45:53.880 --> 00:45:55.930 imagine how Messier 1288 00:45:55.930 --> 00:45:58.090 didn't see any stars in, they're very 1289 00:45:58.090 --> 00:46:00.130 very close and yet you 1290 00:46:00.130 --> 00:46:02.180 zoom in and 1291 00:46:02.180 --> 00:46:04.260 it's almost like the 1292 00:46:04.260 --> 00:46:06.460 fly through that we saw. 1293 00:46:06.460 --> 00:46:09.580 It turns into something else. 1294 00:46:09.580 --> 00:46:12.630 And it's in the heart of the Milky Way where 1295 00:46:12.630 --> 00:46:14.710 it's surrounded by hundreds and hundreds stars 1296 00:46:14.710 --> 00:46:16.790 to begin with and so it's just 1297 00:46:16.790 --> 00:46:18.900 it's 1298 00:46:18.900 --> 00:46:20.990 I don't know how to describe it. 1299 00:46:20.990 --> 00:46:23.140 It's just beautiful. I could look at it 1300 00:46:23.140 --> 00:46:24.310 a long time. 1301 00:46:24.310 --> 00:46:25.370 If we don't know how to 1302 00:46:25.370 --> 00:46:26.450 describe it, you need to try it yourself. 1303 00:46:26.450 --> 00:46:27.550 That's right. 1304 00:46:27.550 --> 00:46:28.630 So get out there and 1305 00:46:28.630 --> 00:46:30.760 find the Messier catalog yourself 1306 00:46:30.760 --> 00:46:32.900 and enjoy the absolutely 1307 00:46:32.900 --> 00:46:34.990 beautiful that the Hubble Space Telescope 1308 00:46:34.990 --> 00:46:35.590 has made of these objects. 1309 00:46:35.590 --> 00:46:36.760 Absolutely, like they said 1310 00:46:36.760 --> 00:46:38.810 if you want more we've got 1311 00:46:38.810 --> 00:46:40.860 the catalog up on our web site at 1312 00:46:40.860 --> 00:46:41.920 nasa.gov/hubble and if you want 1313 00:46:41.920 --> 00:46:43.000 to know anything about Hubble 1314 00:46:43.000 --> 00:46:44.010 at anytime you can follow 1315 00:46:44.010 --> 00:46:45.160 us on twitter 1316 00:46:45.160 --> 00:46:46.310 @nasahubble 1317 00:46:46.310 --> 00:46:48.460 Thank you both so so much for being 1318 00:46:48.460 --> 00:46:50.540 here and thank you all for tuning into us 1319 00:46:50.540 --> 00:46:52.610 and we'll see you next time. 1320 00:46:52.610 --> 00:46:54.650 Bye 1321 00:46:54.650 --> 00:46:56.710 1322 00:46:56.710 --> 00:46:56.947