1 00:00:02,490 --> 00:00:04,830 The following content is provided under a Creative 2 00:00:04,830 --> 00:00:06,250 Commons license. 3 00:00:06,250 --> 00:00:08,460 Your support will help MIT OpenCourseWare 4 00:00:08,460 --> 00:00:12,550 continue to offer high quality educational resources for free. 5 00:00:12,550 --> 00:00:15,090 To make a donation or to view additional materials 6 00:00:15,090 --> 00:00:19,020 from hundreds of MIT courses, visit MIT OpenCourseWare 7 00:00:19,020 --> 00:00:20,280 at ocw.mit.edu. 8 00:00:24,010 --> 00:00:27,400 PROFESSOR: Today we are going to continue discussion about two 9 00:00:27,400 --> 00:00:29,420 very important issues. 10 00:00:29,420 --> 00:00:31,780 The first one is the understanding 11 00:00:31,780 --> 00:00:34,700 of so-called quarter wave plate. 12 00:00:34,700 --> 00:00:38,170 That may not mean anything to you in the beginning, 13 00:00:38,170 --> 00:00:40,590 but I hope after this lecture, you 14 00:00:40,590 --> 00:00:43,810 will know what does that mean and why that is actually 15 00:00:43,810 --> 00:00:46,010 interesting. 16 00:00:46,010 --> 00:00:49,630 The second thing is that-- 17 00:00:49,630 --> 00:00:52,600 the second topic we want to talk about in the lecture today 18 00:00:52,600 --> 00:00:56,620 is, OK, we have been talking about electromagnetic waves 19 00:00:56,620 --> 00:01:01,130 for a long time already, since the last few lectures. 20 00:01:01,130 --> 00:01:04,250 But we have never touched the topic, 21 00:01:04,250 --> 00:01:09,180 how do we actually create electromagnetic wave, right? 22 00:01:09,180 --> 00:01:12,530 And we are going to answer that in the lecture today. 23 00:01:12,530 --> 00:01:15,560 So that's my plan about these two topics. 24 00:01:15,560 --> 00:01:18,940 OK, so before we start, it's a reminder 25 00:01:18,940 --> 00:01:21,370 about why we have learned last time. 26 00:01:21,370 --> 00:01:24,790 So we have learned several situations 27 00:01:24,790 --> 00:01:27,280 related to polarization. 28 00:01:27,280 --> 00:01:30,520 So we have learned linearly polarized wave. 29 00:01:30,520 --> 00:01:32,080 What is linearly polarized wave? 30 00:01:32,080 --> 00:01:37,060 If you plot the wave amplitude as a function of time 31 00:01:37,060 --> 00:01:40,750 as a function of space, it's going up and down, up and down, 32 00:01:40,750 --> 00:01:43,150 up and down. 33 00:01:43,150 --> 00:01:45,580 And the direction of the field doesn't 34 00:01:45,580 --> 00:01:47,410 change as a function of time. 35 00:01:47,410 --> 00:01:51,640 So that is actually called linearly polarized light. 36 00:01:51,640 --> 00:01:56,110 And we also learned circularly polarized light, right? 37 00:01:56,110 --> 00:02:00,500 When you have two components, one is in the x direction, 38 00:02:00,500 --> 00:02:03,520 the other one is in the y direction, if the two 39 00:02:03,520 --> 00:02:08,560 components are out of phase, say, they differ 40 00:02:08,560 --> 00:02:17,290 by 90 degrees, for example, and they the same amplitude, 41 00:02:17,290 --> 00:02:20,770 then the superposition of these two waves 42 00:02:20,770 --> 00:02:23,500 will be a circularly polarized wave. 43 00:02:23,500 --> 00:02:27,530 So basically, the wave propagation looks like this. 44 00:02:27,530 --> 00:02:31,390 So basically, the pointy angle of the electric field 45 00:02:31,390 --> 00:02:34,060 is rotating as a function over time 46 00:02:34,060 --> 00:02:37,060 as a function of the distance it travels. 47 00:02:37,060 --> 00:02:40,300 And the other case, which is also interesting, 48 00:02:40,300 --> 00:02:42,205 is that when you have-- 49 00:02:42,205 --> 00:02:45,760 OK, for example, different phase difference. 50 00:02:45,760 --> 00:02:49,912 Like delta phi different from 90 degree, or say 51 00:02:49,912 --> 00:02:52,370 you have different amplitude, although the phase difference 52 00:02:52,370 --> 00:02:55,220 is 90 degree but you have different amplitude 53 00:02:55,220 --> 00:02:58,210 in the x and the y direction. 54 00:02:58,210 --> 00:03:04,540 If that's the case, then you have a situation which not only 55 00:03:04,540 --> 00:03:06,820 the direction is changing, but also the amplitude 56 00:03:06,820 --> 00:03:09,220 is changing as a function of time. 57 00:03:09,220 --> 00:03:12,520 And that we call it elliptically polarized. 58 00:03:12,520 --> 00:03:16,120 So that's actually the three situations we learned. 59 00:03:16,120 --> 00:03:22,460 And also we learned about how to make polarized light 60 00:03:22,460 --> 00:03:23,630 during the class. 61 00:03:23,630 --> 00:03:27,540 So usually, the light source we are talking about, 62 00:03:27,540 --> 00:03:31,750 or even present in this room, like the light 63 00:03:31,750 --> 00:03:34,880 from the light bulb, et cetera, those 64 00:03:34,880 --> 00:03:36,410 are unpolarized light, right? 65 00:03:36,410 --> 00:03:42,790 So that means you have a lot of electromagnetic wave emitted 66 00:03:42,790 --> 00:03:47,740 from the light with different initial time, emission time. 67 00:03:47,740 --> 00:03:51,940 And those are in slightly different angular frequency, 68 00:03:51,940 --> 00:03:55,200 slightly different pointing direction. 69 00:03:55,200 --> 00:03:58,780 So you can have all kinds of different emissions. 70 00:03:58,780 --> 00:04:01,660 And the sum of all those emissions 71 00:04:01,660 --> 00:04:04,830 is unpolarized light, which is actually 72 00:04:04,830 --> 00:04:08,180 the light source I have here. 73 00:04:08,180 --> 00:04:11,440 And you can use so-called polarizer. 74 00:04:11,440 --> 00:04:18,910 So the polarizer can actually kill one of the direction, 75 00:04:18,910 --> 00:04:23,500 and only keep all the projection to the easy axis. 76 00:04:23,500 --> 00:04:25,630 And in this presentation, the easy axis 77 00:04:25,630 --> 00:04:27,320 is in the x direction. 78 00:04:27,320 --> 00:04:30,750 And you can see that if you start with unpolarized light, 79 00:04:30,750 --> 00:04:34,870 and basically, you have that pass through a polarizer, 80 00:04:34,870 --> 00:04:37,180 then the resulting electric field 81 00:04:37,180 --> 00:04:41,340 will be pointing toward the so-called easy axis. 82 00:04:41,340 --> 00:04:43,990 So the easier axis to pass, right? 83 00:04:43,990 --> 00:04:48,730 So therefore, all the electric field perpendicular 84 00:04:48,730 --> 00:04:52,360 to the easy axis is illuminated. 85 00:04:52,360 --> 00:04:55,360 And what is left over is the electric field, 86 00:04:55,360 --> 00:05:00,520 which is actually parallel to the easy axis. 87 00:05:00,520 --> 00:05:06,200 And of course, you can rotate this polarizer 88 00:05:06,200 --> 00:05:09,070 and you would see that, OK, if you 89 00:05:09,070 --> 00:05:13,800 have a linearly polarized wave passing through polarizer, 90 00:05:13,800 --> 00:05:15,940 because easy axis is actually now 91 00:05:15,940 --> 00:05:19,630 in line with the polarization, what is going to happen 92 00:05:19,630 --> 00:05:24,940 is, as I said, still only the component which is actually 93 00:05:24,940 --> 00:05:27,730 parallel to the easy axis will passed through. 94 00:05:27,730 --> 00:05:30,165 And the resulting electric field will still 95 00:05:30,165 --> 00:05:33,520 be pointing to the direction of the easy axis. 96 00:05:33,520 --> 00:05:36,920 So that's actually what we have learned last time. 97 00:05:36,920 --> 00:05:40,370 OK, so that means we know how to generate 98 00:05:40,370 --> 00:05:42,490 linearly polarized wave, right? 99 00:05:42,490 --> 00:05:45,070 Because you just need a polarizer 100 00:05:45,070 --> 00:05:47,200 and put it in front of your light source, 101 00:05:47,200 --> 00:05:50,230 then you produce a linearly polarized save. 102 00:05:50,230 --> 00:05:54,400 But we didn't talk about how to produce a circularly 103 00:05:54,400 --> 00:05:56,200 polarized wave, right? 104 00:05:56,200 --> 00:05:58,150 OK, so that is actually the topic which 105 00:05:58,150 --> 00:06:01,510 I would like to talk about. 106 00:06:01,510 --> 00:06:05,700 So let's take a look at the diagram here. 107 00:06:05,700 --> 00:06:12,560 So assuming that I have a single layer of sheet, 108 00:06:12,560 --> 00:06:14,750 which I call wave plate. 109 00:06:14,750 --> 00:06:18,420 This is actually the zoom in and zoom in of that sheet. 110 00:06:18,420 --> 00:06:24,410 And the interesting property of this wave plate sheet 111 00:06:24,410 --> 00:06:31,280 is that the refraction index in the x direction 112 00:06:31,280 --> 00:06:35,930 and the refraction index for the linearly 113 00:06:35,930 --> 00:06:40,390 polarized wave in the y direction, they are different. 114 00:06:40,390 --> 00:06:41,360 That can happen, right? 115 00:06:41,360 --> 00:06:44,450 Because when we were discussing two-dimensional and 116 00:06:44,450 --> 00:06:49,490 three-dimensional waves, the dispersion relation 117 00:06:49,490 --> 00:06:53,930 can be dependent on the k vector, right? 118 00:06:53,930 --> 00:06:56,660 So that should not surprise you by now. 119 00:06:56,660 --> 00:07:02,390 And it depends on the structure of the material you 120 00:07:02,390 --> 00:07:04,940 use to make this wave plate. 121 00:07:04,940 --> 00:07:09,830 So therefore, you can have different velocity 122 00:07:09,830 --> 00:07:13,400 when you have an incident where pointing in the x direction, 123 00:07:13,400 --> 00:07:15,530 and compared to an incident where 124 00:07:15,530 --> 00:07:17,840 pointing in the y direction. 125 00:07:17,840 --> 00:07:21,390 So in short, we can actually summarize 126 00:07:21,390 --> 00:07:24,760 this kind of information, the dispersion relation, 127 00:07:24,760 --> 00:07:25,840 into two components. 128 00:07:25,840 --> 00:07:29,460 One is the velocity, the phase velocity in the x direction, 129 00:07:29,460 --> 00:07:32,270 which is denoted as nx. 130 00:07:32,270 --> 00:07:35,810 Just a reminder, the speed of the light 131 00:07:35,810 --> 00:07:39,260 will be equal to c divided by nx, right? 132 00:07:39,260 --> 00:07:45,230 So larger n means smaller speed of light in material. 133 00:07:45,230 --> 00:07:50,060 And if that happens, if nx is different from ny, what 134 00:07:50,060 --> 00:07:56,570 is going to happen is that if you have an incident wave, when 135 00:07:56,570 --> 00:08:00,440 it passes through this wave plate, what is going to happen 136 00:08:00,440 --> 00:08:04,070 is that the x component, the delay in phase 137 00:08:04,070 --> 00:08:07,910 in the x component, would be different from the delay 138 00:08:07,910 --> 00:08:11,480 in phase in the y component. 139 00:08:11,480 --> 00:08:14,210 And that is, essentially, how we can actually 140 00:08:14,210 --> 00:08:16,990 make use of that to create elliptically 141 00:08:16,990 --> 00:08:21,410 polarized wave or circularly polarized wave, OK? 142 00:08:21,410 --> 00:08:23,970 So let's take a look at this example together. 143 00:08:23,970 --> 00:08:29,840 So suppose I have incident light with angular frequency omega, 144 00:08:29,840 --> 00:08:30,830 OK? 145 00:08:30,830 --> 00:08:34,880 Since I give you already the omega, what I really need 146 00:08:34,880 --> 00:08:38,030 is the speed of light, then I can calculate the resulting 147 00:08:38,030 --> 00:08:40,250 wave number and wave lengths. 148 00:08:40,250 --> 00:08:44,570 So this is actually the incident wave angular frequency. 149 00:08:44,570 --> 00:08:49,970 And the lens of the-- or say the thickness of the wave plate 150 00:08:49,970 --> 00:08:52,070 is called little l. 151 00:08:52,070 --> 00:08:54,860 And we can actually check immediately 152 00:08:54,860 --> 00:08:57,380 what would be the corresponding wave 153 00:08:57,380 --> 00:09:04,580 number in the median for the linearly polarized wave 154 00:09:04,580 --> 00:09:07,640 in the x direction and linearly polarized wave in the y 155 00:09:07,640 --> 00:09:08,460 direction. 156 00:09:08,460 --> 00:09:10,770 So we can actually calculate Kx will 157 00:09:10,770 --> 00:09:15,965 be equal to nx over c omega, because this is actually 158 00:09:15,965 --> 00:09:18,800 just omega divided by v, which is 159 00:09:18,800 --> 00:09:24,950 the phase velocity in the median for waves in the x direction. 160 00:09:24,950 --> 00:09:29,080 And that would be equal to 2 pi over lambda x. 161 00:09:29,080 --> 00:09:32,180 Similarly, you can also conclude that Ky 162 00:09:32,180 --> 00:09:37,260 can be written as ny divided by c times omega, 163 00:09:37,260 --> 00:09:39,783 which is 2 pi over lambda u. 164 00:09:39,783 --> 00:09:45,050 Kx and Ky are the wave numbers inside 165 00:09:45,050 --> 00:09:50,510 for the progressing harmonic waves inside the median, OK? 166 00:09:50,510 --> 00:09:51,700 One is in the x direction. 167 00:09:51,700 --> 00:09:54,290 The other one's in the y direction. 168 00:09:54,290 --> 00:09:58,140 So if we keep those in mind, you will see that, 169 00:09:58,140 --> 00:10:04,820 huh, if I have different nx and ny, when the same frequency 170 00:10:04,820 --> 00:10:10,010 light goes through this median, its x component 171 00:10:10,010 --> 00:10:13,650 will travel through different amount of period, 172 00:10:13,650 --> 00:10:17,150 where is a different amount of phase difference. 173 00:10:17,150 --> 00:10:20,180 Compared to the light polarized-- 174 00:10:20,180 --> 00:10:24,000 compared to the component in the y direction, 175 00:10:24,000 --> 00:10:26,210 as you can see from this demonstration. 176 00:10:26,210 --> 00:10:29,240 Therefore, we can actually conclude 177 00:10:29,240 --> 00:10:31,730 that there must be a phase difference 178 00:10:31,730 --> 00:10:33,860 between the x component and y component. 179 00:10:33,860 --> 00:10:35,570 And we can calculate that-- 180 00:10:35,570 --> 00:10:38,390 this is actually delta phi, the phase difference 181 00:10:38,390 --> 00:10:42,740 between the x direction and y direction will be equal to 2 pi 182 00:10:42,740 --> 00:10:46,070 times l divided by lambda x. 183 00:10:46,070 --> 00:10:50,680 So basically, it's the number of waves times 2 pi. 184 00:10:50,680 --> 00:10:54,770 l over lambda x is number of periods past. 185 00:10:54,770 --> 00:11:00,110 And the times 2 pi translates that to phase. 186 00:11:00,110 --> 00:11:02,840 And we are taking the difference between the x 187 00:11:02,840 --> 00:11:05,090 and the y direction. 188 00:11:05,090 --> 00:11:09,480 And we can conclude that based on what we have written here. 189 00:11:09,480 --> 00:11:12,920 As you see that this is just nx minus ny 190 00:11:12,920 --> 00:11:19,380 divided by c times omega times l, OK? 191 00:11:19,380 --> 00:11:23,790 So this is actually how the wave plate works. 192 00:11:23,790 --> 00:11:29,320 Suppose I have a linearly polarizer 193 00:11:29,320 --> 00:11:32,580 wave coming into this plate. 194 00:11:32,580 --> 00:11:37,080 And the direction of the polarization 195 00:11:37,080 --> 00:11:39,050 is not in the x direction or y direction. 196 00:11:39,050 --> 00:11:41,140 So they are positioned-- 197 00:11:41,140 --> 00:11:44,820 they are components in the x direction and y direction. 198 00:11:44,820 --> 00:11:50,100 For example, I can have an incoming polarizer like this. 199 00:11:50,100 --> 00:11:52,400 And this is actually the x direction. 200 00:11:52,400 --> 00:11:54,290 This is actually the y direction. 201 00:11:54,290 --> 00:11:59,580 And I can now decompose this kind of linearly polarized wave 202 00:11:59,580 --> 00:12:00,900 into two components. 203 00:12:00,900 --> 00:12:07,160 And after this wave passes through the wave plate, 204 00:12:07,160 --> 00:12:10,200 x component will be-- 205 00:12:10,200 --> 00:12:13,210 the phase difference between x and y 206 00:12:13,210 --> 00:12:16,320 will be increased by delta phi. 207 00:12:16,320 --> 00:12:19,320 So if originally there were no phase difference 208 00:12:19,320 --> 00:12:22,410 because this is actually a linearly polarized wave, 209 00:12:22,410 --> 00:12:24,990 and after it passes through the wave plate, 210 00:12:24,990 --> 00:12:26,220 it will be increased. 211 00:12:26,220 --> 00:12:28,500 And then the phase difference between x and y 212 00:12:28,500 --> 00:12:31,560 will be delta phi. 213 00:12:31,560 --> 00:12:35,420 All right, so that's really nice tour. 214 00:12:35,420 --> 00:12:39,120 And the so-called quarter wave plate 215 00:12:39,120 --> 00:12:45,450 is a device which we intentionally set the delta phi 216 00:12:45,450 --> 00:12:48,090 to be pi over 2. 217 00:12:48,090 --> 00:12:49,580 Why is that interesting? 218 00:12:49,580 --> 00:12:52,140 That is because initially you have 219 00:12:52,140 --> 00:13:05,420 Ex equal to E0 cosine omega t minus Kz, 220 00:13:05,420 --> 00:13:10,230 and this is actually the y component. 221 00:13:10,230 --> 00:13:14,720 If initially you have this kind of incident wave, 222 00:13:14,720 --> 00:13:19,170 now it corresponds to a polarization 223 00:13:19,170 --> 00:13:25,189 which is actually 45 degree with respect to the x-axis. 224 00:13:25,189 --> 00:13:26,480 So this is actually the x-axis. 225 00:13:29,190 --> 00:13:31,000 And this is actually the y-axis. 226 00:13:33,540 --> 00:13:39,030 When I have this kind of linearly polarized wave pass 227 00:13:39,030 --> 00:13:43,680 through the quarter wave plate, what is going to happen? 228 00:13:43,680 --> 00:13:46,440 What is going to happen is that one of the components 229 00:13:46,440 --> 00:13:50,100 will be delayed by delta phi or pi over 2. 230 00:13:50,100 --> 00:13:54,360 That will make you a circularly polarized wave. 231 00:13:54,360 --> 00:13:58,030 Because that will become sine and cosine. 232 00:13:58,030 --> 00:14:02,510 Therefore, if you plot the locus of the electric field 233 00:14:02,510 --> 00:14:07,410 in two-dimensional xy plane, you will see a circle. 234 00:14:07,410 --> 00:14:10,740 So that is actually why we want are 235 00:14:10,740 --> 00:14:14,130 interested in a special setup which delta phi is 236 00:14:14,130 --> 00:14:17,460 equal to pi over 2, OK? 237 00:14:17,460 --> 00:14:20,550 So let me go through a few examples 238 00:14:20,550 --> 00:14:24,990 so that actually you get some feelings about what is actually 239 00:14:24,990 --> 00:14:27,780 a quarter wave plate. 240 00:14:27,780 --> 00:14:32,910 Usually, instead of drawing this complicated diagram, 241 00:14:32,910 --> 00:14:35,670 we actually simplify the presentation 242 00:14:35,670 --> 00:14:38,280 into a diagram like this. 243 00:14:38,280 --> 00:14:42,160 So basically, you have a fast axis, 244 00:14:42,160 --> 00:14:47,160 which is the axis with smaller phase shift. 245 00:14:47,160 --> 00:14:53,490 And you have slow axis, which is actually the axis with larger 246 00:14:53,490 --> 00:14:54,990 phase shift. 247 00:14:54,990 --> 00:14:58,670 So basically, we just reduce the whole complicated setup 248 00:14:58,670 --> 00:15:02,520 into a simple diagram like that. 249 00:15:02,520 --> 00:15:10,060 So suppose I have an incident wave which is actually linearly 250 00:15:10,060 --> 00:15:14,140 polarized in this direction. 251 00:15:14,140 --> 00:15:17,570 In this direction, which I can call it x direction. 252 00:15:17,570 --> 00:15:21,000 And this is actually y direction. 253 00:15:21,000 --> 00:15:26,190 And I have that pass through a quarter wave plate, 254 00:15:26,190 --> 00:15:30,350 where the fast axis is in the x direction, 255 00:15:30,350 --> 00:15:33,465 and there's a slow axis in the y direction. 256 00:15:36,080 --> 00:15:41,660 Can somebody tell me, what would be the resulting polarization 257 00:15:41,660 --> 00:15:45,620 after this electromagnetic wave passes through this quarter 258 00:15:45,620 --> 00:15:47,240 wave plate? 259 00:15:47,240 --> 00:15:49,550 Somebody want to try it? 260 00:15:49,550 --> 00:15:50,417 Yes. 261 00:15:50,417 --> 00:15:53,550 STUDENT: It would be polarized in the y direction. 262 00:15:53,550 --> 00:15:55,178 PROFESSOR: Polarized in what? 263 00:15:55,178 --> 00:15:58,507 STUDENT: In the y direction. 264 00:15:58,507 --> 00:15:59,090 PROFESSOR: No. 265 00:15:59,090 --> 00:16:04,390 Basically-- OK, maybe I didn't explain that clearly. 266 00:16:04,390 --> 00:16:10,810 So initially, in this example, all the electric field 267 00:16:10,810 --> 00:16:13,320 is in the x direction. 268 00:16:13,320 --> 00:16:17,140 Therefore, in the y direction, there's nothing there. 269 00:16:17,140 --> 00:16:20,252 So that's actually a linearly polarized wave. 270 00:16:20,252 --> 00:16:22,480 The direction in actually in the x direction. 271 00:16:22,480 --> 00:16:25,030 And this quarter wave plate is going 272 00:16:25,030 --> 00:16:31,900 to slow down the y component by a phase of pi over 2. 273 00:16:31,900 --> 00:16:34,831 So what would be the resulting polarization? 274 00:16:34,831 --> 00:16:35,330 Yes. 275 00:16:35,330 --> 00:16:39,160 STUDENT: Very similar to [INAUDIBLE].. 276 00:16:39,160 --> 00:16:40,450 PROFESSOR: Yes, that's right. 277 00:16:40,450 --> 00:16:44,780 So because we are dividing something which is zero. 278 00:16:44,780 --> 00:16:46,660 But zero is zero. 279 00:16:46,660 --> 00:16:49,730 So zero is zero is zero, right? 280 00:16:49,730 --> 00:16:54,060 So therefore, what you are going to get is this. 281 00:16:54,060 --> 00:16:57,100 It's still a linearly polarized wave, right? 282 00:16:57,100 --> 00:17:01,420 OK, doesn't surprise you after I explain to you more clearly. 283 00:17:01,420 --> 00:17:05,609 And then you can see that if you have this-- 284 00:17:05,609 --> 00:17:08,750 OK, now I change the situation. 285 00:17:08,750 --> 00:17:10,500 So this is the x direction. 286 00:17:10,500 --> 00:17:12,099 This is the y direction. 287 00:17:12,099 --> 00:17:14,230 And I have something which is 45 degrees. 288 00:17:17,450 --> 00:17:21,870 And I have that pass through the same setup. 289 00:17:21,870 --> 00:17:25,840 Slow axis is in the y direction and the fast axis 290 00:17:25,840 --> 00:17:27,980 is in the x direction. 291 00:17:27,980 --> 00:17:29,300 What will we get? 292 00:17:29,300 --> 00:17:32,000 What kind of polarized light will we 293 00:17:32,000 --> 00:17:38,240 get after it passed through this quarter wave plate? 294 00:17:38,240 --> 00:17:39,676 Somebody can help me? 295 00:17:39,676 --> 00:17:40,509 STUDENT: Circular. 296 00:17:40,509 --> 00:17:41,550 PROFESSOR: Circular, yes. 297 00:17:41,550 --> 00:17:42,660 Thank you very much. 298 00:17:42,660 --> 00:17:44,610 So that's actually exactly what I was 299 00:17:44,610 --> 00:17:46,470 talking about in the beginning. 300 00:17:46,470 --> 00:17:50,610 The y component will be delayed by pi over 2. 301 00:17:50,610 --> 00:17:55,230 Therefore, it would become a circularly polarized wave. 302 00:17:55,230 --> 00:17:59,520 How about I change this to 30 degrees? 303 00:17:59,520 --> 00:18:00,950 What is going to happen? 304 00:18:00,950 --> 00:18:02,024 STUDENT: [INAUDIBLE]. 305 00:18:02,024 --> 00:18:04,440 PROFESSOR: Yeah, it will be elliptically polarized, right? 306 00:18:04,440 --> 00:18:08,190 Because now the projection to a different component 307 00:18:08,190 --> 00:18:09,050 is different. 308 00:18:09,050 --> 00:18:12,870 So therefore, it would be elliptically polarized wave. 309 00:18:12,870 --> 00:18:13,680 Very good. 310 00:18:13,680 --> 00:18:15,900 It seems to me that most of you actually 311 00:18:15,900 --> 00:18:17,880 understand what we are doing. 312 00:18:17,880 --> 00:18:23,641 And now it's time to do some experiment to actually show you 313 00:18:23,641 --> 00:18:24,390 what we have done. 314 00:18:24,390 --> 00:18:25,147 Yes. 315 00:18:25,147 --> 00:18:26,772 STUDENT: It's a little more complicated 316 00:18:26,772 --> 00:18:29,123 than that because the slope the refraction 317 00:18:29,123 --> 00:18:42,050 is [INAUDIBLE] be much, much slower than the fast axis. 318 00:18:42,050 --> 00:18:43,925 PROFESSOR: Yeah. 319 00:18:43,925 --> 00:18:47,050 Yeah, that's right. 320 00:18:47,050 --> 00:18:48,570 You are absolutely right. 321 00:18:48,570 --> 00:18:51,150 So it depends on the delta phi, right? 322 00:18:51,150 --> 00:18:54,740 So if delta phi is not pi over 2, 323 00:18:54,740 --> 00:18:58,430 then it can be elliptically polarized. 324 00:18:58,430 --> 00:19:01,610 And in this setup, I say that this is actually a quarter wave 325 00:19:01,610 --> 00:19:03,800 plate, therefore, the delay is always 326 00:19:03,800 --> 00:19:05,570 delta phi equal to pi over 2. 327 00:19:05,570 --> 00:19:07,120 Yeah. 328 00:19:07,120 --> 00:19:09,410 So then-- thank you for that. 329 00:19:09,410 --> 00:19:11,480 This is what we have been discussing 330 00:19:11,480 --> 00:19:13,610 is always quarter wave plate. 331 00:19:13,610 --> 00:19:17,120 Therefore, the delta phi between the slow and fast axis 332 00:19:17,120 --> 00:19:18,800 is always pi over 2, OK? 333 00:19:18,800 --> 00:19:21,900 So that everybody is on the same page. 334 00:19:21,900 --> 00:19:22,568 Yes. 335 00:19:22,568 --> 00:19:24,480 STUDENT: How can you have a material 336 00:19:24,480 --> 00:19:28,310 that has a different refraction index for different directions? 337 00:19:28,310 --> 00:19:33,170 PROFESSOR: For example, we were talking about materials-- 338 00:19:33,170 --> 00:19:36,950 or say the two-dimensional discrete case, right? 339 00:19:36,950 --> 00:19:41,690 So we can have little mass arranged 340 00:19:41,690 --> 00:19:43,370 in the x and y direction. 341 00:19:43,370 --> 00:19:50,450 But the space between mass in the x direction and y direction 342 00:19:50,450 --> 00:19:53,690 are different, then you have a dispersion relation 343 00:19:53,690 --> 00:19:56,840 which is actually different for the harmonic 344 00:19:56,840 --> 00:19:59,780 wave in the x direction compared to y direction. 345 00:19:59,780 --> 00:20:01,440 And that's just some random example. 346 00:20:01,440 --> 00:20:04,700 And that can be achieved by engineering 347 00:20:04,700 --> 00:20:09,150 the material we will use for the wave plate, OK? 348 00:20:09,150 --> 00:20:10,580 Good question. 349 00:20:10,580 --> 00:20:12,460 All right, so we will go ahead and I'll 350 00:20:12,460 --> 00:20:15,440 show you some demonstration. 351 00:20:15,440 --> 00:20:17,360 We prepare. 352 00:20:17,360 --> 00:20:22,840 The first thing I have to do is to turn off the light 353 00:20:22,840 --> 00:20:24,630 to have some more excitement. 354 00:20:27,810 --> 00:20:31,050 I cannot even see where is my experiment now. 355 00:20:31,050 --> 00:20:33,060 Oh, right here, yeah. 356 00:20:33,060 --> 00:20:34,910 OK, woo. 357 00:20:34,910 --> 00:20:38,190 OK, so look at what we have here. 358 00:20:38,190 --> 00:20:41,820 This is a projector. 359 00:20:41,820 --> 00:20:44,095 So what is the polarization of that light? 360 00:20:44,095 --> 00:20:44,970 STUDENT: Unpolarized. 361 00:20:44,970 --> 00:20:46,190 PROFESSOR: Unpolarized. 362 00:20:46,190 --> 00:20:47,480 Yeah, very good. 363 00:20:47,480 --> 00:20:50,900 OK, I'm very happy to hear that. 364 00:20:50,900 --> 00:20:55,520 All right, so now I have the polarizer and I put it on it. 365 00:20:55,520 --> 00:20:58,184 What is the polarization of this light? 366 00:20:58,184 --> 00:21:01,490 STUDENT: [INAUDIBLE]. 367 00:21:01,490 --> 00:21:03,003 PROFESSOR: I couldn't hear you. 368 00:21:03,003 --> 00:21:04,160 STUDENT: It's linear. 369 00:21:04,160 --> 00:21:04,670 PROFESSOR: Linear, yeah. 370 00:21:04,670 --> 00:21:06,410 Linearly of-- don't be afraid. 371 00:21:06,410 --> 00:21:07,400 OK, you can say that. 372 00:21:07,400 --> 00:21:08,570 No, this is not linear. 373 00:21:08,570 --> 00:21:10,310 The edge is not linear, right? 374 00:21:10,310 --> 00:21:11,430 But it's OK. 375 00:21:11,430 --> 00:21:15,830 I'm talking about everything inside of this material. 376 00:21:15,830 --> 00:21:17,000 Very good. 377 00:21:17,000 --> 00:21:22,070 So now what I'm going to do is to put two polarizers 378 00:21:22,070 --> 00:21:24,380 on top of each other. 379 00:21:24,380 --> 00:21:29,960 And of course, I can rotate such that the polarizer, the easy 380 00:21:29,960 --> 00:21:33,170 axis is perpendicular to each other, OK? 381 00:21:33,170 --> 00:21:37,700 So you see that ha, I almost black most of that light. 382 00:21:37,700 --> 00:21:41,120 So the first thing which I have been doing 383 00:21:41,120 --> 00:21:46,820 is that I first turn this unpolarized light polarized. 384 00:21:46,820 --> 00:21:49,760 And it's actually oscillating in one direction. 385 00:21:49,760 --> 00:21:53,340 And I block it again with the second one. 386 00:21:53,340 --> 00:21:55,220 And then you see that it's black. 387 00:21:55,220 --> 00:21:57,900 It's consistent with what we expect. 388 00:21:57,900 --> 00:22:00,032 So we are happy. 389 00:22:00,032 --> 00:22:00,740 We are not happy? 390 00:22:00,740 --> 00:22:01,400 No? 391 00:22:01,400 --> 00:22:03,530 Yes, we are happy. 392 00:22:03,530 --> 00:22:08,100 All right, so remember the discussion we had before. 393 00:22:08,100 --> 00:22:15,440 So what I could do is to add a third one, a third polarizer. 394 00:22:15,440 --> 00:22:18,430 So I can have the first polarizer 395 00:22:18,430 --> 00:22:21,920 which actually makes the direction of the oscillation 396 00:22:21,920 --> 00:22:24,330 in this direction. 397 00:22:24,330 --> 00:22:28,760 Then I put a second polarizer, where the easy axis 398 00:22:28,760 --> 00:22:30,380 is in this direction. 399 00:22:30,380 --> 00:22:35,840 Then I actually-- I'm going to extract all the components 400 00:22:35,840 --> 00:22:37,950 which projected to this axis. 401 00:22:37,950 --> 00:22:44,270 Therefore, after passing the second polarizer, 402 00:22:44,270 --> 00:22:48,860 the oscillation of the wave will be in this direction. 403 00:22:48,860 --> 00:22:55,130 Therefore, aha, now I put the third polarizer on, 404 00:22:55,130 --> 00:23:00,050 you can see that in the middle, because it changed 405 00:23:00,050 --> 00:23:03,110 the direction of the polarization by 45 degrees 406 00:23:03,110 --> 00:23:06,610 already by this polarizer, therefore 407 00:23:06,610 --> 00:23:11,372 you can see that there's some residual light survived. 408 00:23:11,372 --> 00:23:12,830 And then you can actually calculate 409 00:23:12,830 --> 00:23:20,100 what will be the intensity of the light surviving these three 410 00:23:20,100 --> 00:23:21,020 polarizers. 411 00:23:21,020 --> 00:23:22,610 And you can see that the ones which 412 00:23:22,610 --> 00:23:29,450 didn't pass the second polarizer is actually completely blocked 413 00:23:29,450 --> 00:23:33,410 by the two polarizers, which their easy axes are 414 00:23:33,410 --> 00:23:35,880 perpendicular to each other. 415 00:23:35,880 --> 00:23:38,420 So now, the interesting thing is that now I 416 00:23:38,420 --> 00:23:41,360 have a quarter wave plate here. 417 00:23:41,360 --> 00:23:42,270 OK, it's here. 418 00:23:42,270 --> 00:23:44,010 Hope you can see it. 419 00:23:44,010 --> 00:23:48,220 And I'm going to insert this into this experiment 420 00:23:48,220 --> 00:23:50,830 and see what is going to happen. 421 00:23:50,830 --> 00:23:53,660 Look at what we have here. 422 00:23:53,660 --> 00:23:57,920 Oh, this is actually much brighter, right? 423 00:23:57,920 --> 00:24:01,860 So basically, this water-- 424 00:24:01,860 --> 00:24:04,690 this quarter wave plate-- sorry, it's not water-- 425 00:24:04,690 --> 00:24:07,320 quarter wave plate, OK? 426 00:24:07,320 --> 00:24:10,390 Quarter wave plate actually turned the polarized light 427 00:24:10,390 --> 00:24:14,170 into a circularly polarized light. 428 00:24:14,170 --> 00:24:20,100 And after this circularly polarized light 429 00:24:20,100 --> 00:24:25,180 continued and passed through the third polarizer, 430 00:24:25,180 --> 00:24:27,760 you can see that, huh, the light passed 431 00:24:27,760 --> 00:24:31,510 through this kind of combination is 432 00:24:31,510 --> 00:24:39,310 a lot more than this experiment which was three polarizers. 433 00:24:39,310 --> 00:24:41,320 And we can also calculate what would 434 00:24:41,320 --> 00:24:43,330 be the expected intensity. 435 00:24:43,330 --> 00:24:46,360 And the good news is that we are not going to calculate that 436 00:24:46,360 --> 00:24:48,820 now, but in your P set. 437 00:24:48,820 --> 00:24:52,840 So you will be able to show that, indeed, the intensity you 438 00:24:52,840 --> 00:24:57,690 expect with quarter wave plate will be higher than why you 439 00:24:57,690 --> 00:25:01,630 expect with three polarizers. 440 00:25:01,630 --> 00:25:03,650 So that's actually the first experiment 441 00:25:03,650 --> 00:25:04,700 I would like to show you. 442 00:25:07,460 --> 00:25:11,270 The second experiment is also very interesting. 443 00:25:11,270 --> 00:25:13,810 So I have here-- 444 00:25:13,810 --> 00:25:20,370 OK, first I need to see if I can turn on the light. 445 00:25:20,370 --> 00:25:22,890 I have to turn on this light. 446 00:25:22,890 --> 00:25:25,130 Very good. 447 00:25:25,130 --> 00:25:27,060 So look at this tube. 448 00:25:27,060 --> 00:25:33,140 This tube is made of water and sugar. 449 00:25:33,140 --> 00:25:35,440 So we all love sugar. 450 00:25:35,440 --> 00:25:39,980 And I love it too much, so I add too much into this tube. 451 00:25:39,980 --> 00:25:45,070 So it's actually oversaturated sugar water. 452 00:25:45,070 --> 00:25:50,270 And so there is sugar inside and there are some animal 453 00:25:50,270 --> 00:25:52,610 or whatever living inside. 454 00:25:52,610 --> 00:25:54,540 But we don't care. 455 00:25:54,540 --> 00:25:57,500 We are not studying biology. 456 00:25:57,500 --> 00:26:02,510 But what is actually interesting is that, OK, now I 457 00:26:02,510 --> 00:26:06,350 have a light source from the lamp inside emitting 458 00:26:06,350 --> 00:26:09,040 what kind of polarized light? 459 00:26:09,040 --> 00:26:10,310 Unpolarized light, right? 460 00:26:10,310 --> 00:26:15,590 And I have that pass through a polarizer, which is here. 461 00:26:15,590 --> 00:26:17,120 There's a polarizer here. 462 00:26:17,120 --> 00:26:19,400 And therefore, what I want to say 463 00:26:19,400 --> 00:26:26,720 is that the incident light into this tube is polarized. 464 00:26:26,720 --> 00:26:28,790 That's the first thing I want to say. 465 00:26:28,790 --> 00:26:32,090 The second thing I want to say is that, OK, 466 00:26:32,090 --> 00:26:36,880 a linearly polarized light, due to superposition principle, 467 00:26:36,880 --> 00:26:41,300 actually you can decompose that into two 468 00:26:41,300 --> 00:26:44,630 circularly polarized light. 469 00:26:44,630 --> 00:26:46,970 Both of them are actually rotating 470 00:26:46,970 --> 00:26:49,100 in different directions. 471 00:26:49,100 --> 00:26:50,540 You can actually work on the mass 472 00:26:50,540 --> 00:26:53,060 and you will see that, ha, indeed, it works. 473 00:26:53,060 --> 00:26:57,220 So our linearly polarized light you can always rewrite it 474 00:26:57,220 --> 00:27:00,010 as a superposition of two circularly 475 00:27:00,010 --> 00:27:04,810 polarized light, but rotating in different directions. 476 00:27:04,810 --> 00:27:07,400 The interesting thing is the material 477 00:27:07,400 --> 00:27:12,830 which we use in this demonstration is oversaturated 478 00:27:12,830 --> 00:27:13,910 sugar. 479 00:27:13,910 --> 00:27:19,610 And we know that the molecule for the sugar and those kind 480 00:27:19,610 --> 00:27:26,630 of material is asymmetric under mirror transformation. 481 00:27:26,630 --> 00:27:27,860 It's asymmetric. 482 00:27:27,860 --> 00:27:30,050 It's a chiral material. 483 00:27:30,050 --> 00:27:31,850 OK, chiral is actually just some name, 484 00:27:31,850 --> 00:27:33,470 but it doesn't mean anything to you. 485 00:27:33,470 --> 00:27:37,640 But what is actually interesting is that this material 486 00:27:37,640 --> 00:27:39,470 is asymmetric. 487 00:27:39,470 --> 00:27:41,750 If you have a mirror and this material 488 00:27:41,750 --> 00:27:45,390 is looking at the mirror, in the other side of the mirror, 489 00:27:45,390 --> 00:27:47,480 it looks different. 490 00:27:47,480 --> 00:27:52,150 It's like your hand, right? 491 00:27:52,150 --> 00:27:56,300 So in a mirror, it's asymmetric. 492 00:27:56,300 --> 00:27:59,960 So what is interesting is that due to this kind of structure 493 00:27:59,960 --> 00:28:04,860 in the material that the light passed through, 494 00:28:04,860 --> 00:28:09,530 the circularly polarized light, counterclockwise polarized 495 00:28:09,530 --> 00:28:13,070 light, will have different refractive index 496 00:28:13,070 --> 00:28:15,680 compared to clockwise. 497 00:28:15,680 --> 00:28:18,800 Clockwise and counterclockwise light 498 00:28:18,800 --> 00:28:21,860 will have different refractive index. 499 00:28:21,860 --> 00:28:29,420 Therefore, you see that now you can see some kind of rotation 500 00:28:29,420 --> 00:28:32,840 or some kind of change in the polarization 501 00:28:32,840 --> 00:28:36,830 as a function of distance the light travels through. 502 00:28:36,830 --> 00:28:39,320 So basically, this material would 503 00:28:39,320 --> 00:28:42,530 rotate the linearly polarized light, 504 00:28:42,530 --> 00:28:46,280 because the refractive index for the clockwise and 505 00:28:46,280 --> 00:28:49,920 counterclockwise are different. 506 00:28:49,920 --> 00:28:51,830 So if you accept that, I would like 507 00:28:51,830 --> 00:28:54,200 to add another complication. 508 00:28:54,200 --> 00:28:58,520 In addition to that, the refractive index 509 00:28:58,520 --> 00:29:04,250 also depends on the frequency of the incident light. 510 00:29:04,250 --> 00:29:09,020 Therefore, you will have different amount of rotation 511 00:29:09,020 --> 00:29:11,330 for different color. 512 00:29:11,330 --> 00:29:13,760 So therefore, you can see that once I 513 00:29:13,760 --> 00:29:16,670 have incident light which is linearly polarized, 514 00:29:16,670 --> 00:29:19,370 all the colors are lined up. 515 00:29:19,370 --> 00:29:21,410 You can see that here. 516 00:29:21,410 --> 00:29:24,160 What is the color here? 517 00:29:24,160 --> 00:29:27,760 It's kind of bluish or white, essentially, right? 518 00:29:27,760 --> 00:29:32,030 But if you move slightly more, then it becomes pretty blue. 519 00:29:32,030 --> 00:29:35,800 And then if you move more, because of the dependence 520 00:29:35,800 --> 00:29:40,360 of the refractive index as a function of wavelength, 521 00:29:40,360 --> 00:29:42,790 therefore, you can see that this whole thing is actually 522 00:29:42,790 --> 00:29:44,260 changing color. 523 00:29:44,260 --> 00:29:48,700 And in the end, I have another polarizer which 524 00:29:48,700 --> 00:29:51,980 filter one of the directions. 525 00:29:51,980 --> 00:29:54,010 And I can change the direction, and you 526 00:29:54,010 --> 00:29:59,320 will see that I can filter out different colors. 527 00:29:59,320 --> 00:30:02,130 Which color do you like? 528 00:30:02,130 --> 00:30:02,990 Now it's red. 529 00:30:05,900 --> 00:30:09,770 And of course, I can rotate this polarizer, 530 00:30:09,770 --> 00:30:12,080 and I am sampling different color. 531 00:30:12,080 --> 00:30:16,070 Because at the time different color of light 532 00:30:16,070 --> 00:30:18,170 passes through this material, they 533 00:30:18,170 --> 00:30:21,650 are rotated by different amount of degree. 534 00:30:21,650 --> 00:30:25,370 Therefore, I can filter out and create all kinds 535 00:30:25,370 --> 00:30:27,820 of different color on the wall. 536 00:30:27,820 --> 00:30:31,120 The other thing which is interesting which I can do 537 00:30:31,120 --> 00:30:36,200 is that I can now change that direction of the incident 538 00:30:36,200 --> 00:30:39,950 light, or the direction of the polarization of the incident 539 00:30:39,950 --> 00:30:41,960 light, by rotating this one. 540 00:30:44,720 --> 00:30:51,350 You can see that the whole tube is changing color, like why you 541 00:30:51,350 --> 00:30:54,190 see in the barber shop, right? 542 00:30:57,400 --> 00:31:02,700 OK, so maybe this is a fancy way to make that kind of tube. 543 00:31:02,700 --> 00:31:03,200 No? 544 00:31:03,200 --> 00:31:06,330 A physics barber shop. 545 00:31:06,330 --> 00:31:07,910 Maybe we should do that. 546 00:31:07,910 --> 00:31:10,335 OK, so I hope you enjoyed this demonstration. 547 00:31:10,335 --> 00:31:13,420 And we will take a five minute break to take questions. 548 00:31:13,420 --> 00:31:15,430 And the next topic we are going to talk about 549 00:31:15,430 --> 00:31:21,620 is how do we actually create electromagnetic wave at all. 550 00:31:21,620 --> 00:31:24,670 So let's come back in 15. 551 00:31:31,070 --> 00:31:35,030 OK, so I hope you can hear me. 552 00:31:35,030 --> 00:31:39,140 All right, so welcome back from the break. 553 00:31:39,140 --> 00:31:42,440 So we are going to talk about the second topic we would like 554 00:31:42,440 --> 00:31:45,150 to cover in the lecture today. 555 00:31:45,150 --> 00:31:48,640 The question we are asking is, how do we actually 556 00:31:48,640 --> 00:31:54,680 create electromagnetic waves and so-called radiation? 557 00:31:54,680 --> 00:31:59,300 So this is actually a picture from Hubble telescope. 558 00:31:59,300 --> 00:32:02,540 And you can see that light can travel 559 00:32:02,540 --> 00:32:07,280 through billions, or tens of billions, of light years 560 00:32:07,280 --> 00:32:09,260 and arrive at Earth. 561 00:32:09,260 --> 00:32:11,790 And you can actually measure them 562 00:32:11,790 --> 00:32:16,770 and see you what is actually going on in the past. 563 00:32:16,770 --> 00:32:20,300 And that means if you have a source 564 00:32:20,300 --> 00:32:22,890 and you have some kind of radiation, 565 00:32:22,890 --> 00:32:29,360 and this source is going to emit energy towards somewhere, which 566 00:32:29,360 --> 00:32:32,960 is actually really, really far away toward the edge 567 00:32:32,960 --> 00:32:34,730 of the universe. 568 00:32:34,730 --> 00:32:39,980 So that is actually what we call electromagnetic wave 569 00:32:39,980 --> 00:32:44,090 and radiation. 570 00:32:44,090 --> 00:32:47,290 But the what is actually requirement for that to happen? 571 00:32:47,290 --> 00:32:49,730 What is the requirement for us to be 572 00:32:49,730 --> 00:32:53,390 able to see the stars which are so far away? 573 00:32:53,390 --> 00:32:55,460 That's the question. 574 00:32:55,460 --> 00:33:00,670 So let me actually make a simple argument here. 575 00:33:00,670 --> 00:33:03,410 Suppose I have some kind of a light source. 576 00:33:03,410 --> 00:33:06,180 It's a source in the center. 577 00:33:06,180 --> 00:33:09,420 And we have learned about pointing vector, right? 578 00:33:09,420 --> 00:33:11,610 So what this actually pointing vector? 579 00:33:11,610 --> 00:33:13,800 It's not really the pointing vector, right? 580 00:33:13,800 --> 00:33:20,730 So it's rate of energy transfer per unit area. 581 00:33:20,730 --> 00:33:22,530 So it's kind of pointing, but it's 582 00:33:22,530 --> 00:33:27,660 pointing to the direction of the energy transfer. 583 00:33:27,660 --> 00:33:29,420 So this is a vector. 584 00:33:29,420 --> 00:33:32,280 And it's actually highly related to the direction 585 00:33:32,280 --> 00:33:36,220 of the electric field and the magnetic field. 586 00:33:36,220 --> 00:33:38,540 And now, if I-- 587 00:33:38,540 --> 00:33:42,690 since this is essentially the energy transfer per area, 588 00:33:42,690 --> 00:33:50,820 I can now capture the average pointing vector times area. 589 00:33:50,820 --> 00:33:55,820 And what is going to happen is that if I do this calculation 590 00:33:55,820 --> 00:33:56,760 at this surface-- 591 00:33:56,760 --> 00:34:02,740 this is actually a sphere which is covering this source. 592 00:34:02,740 --> 00:34:05,990 I can do this at sphere number 1. 593 00:34:05,990 --> 00:34:10,739 And I can actually also do that in the sphere number 2. 594 00:34:10,739 --> 00:34:13,949 Since there are absolutely no other source-- 595 00:34:13,949 --> 00:34:16,530 I'm assuming that there's only one source here. 596 00:34:16,530 --> 00:34:19,889 There's only one light source in the universe, 597 00:34:19,889 --> 00:34:21,870 which is kind of lonely. 598 00:34:21,870 --> 00:34:26,370 Apparently it's not my universe, but somebody else's problem. 599 00:34:26,370 --> 00:34:31,770 And then I will conclude that since there's nothing outside, 600 00:34:31,770 --> 00:34:36,880 I will conclude that S times A, if I evaluate that 601 00:34:36,880 --> 00:34:40,199 in the first surface, will be equal to S 602 00:34:40,199 --> 00:34:42,199 times A in the second surface. 603 00:34:42,199 --> 00:34:44,639 That's equal to power, OK? 604 00:34:44,639 --> 00:34:48,260 So that should not surprise anybody. 605 00:34:48,260 --> 00:34:51,440 So that means the pointing vector 606 00:34:51,440 --> 00:34:57,620 will be proportional to 1/A, which is the surface area. 607 00:34:57,620 --> 00:35:01,250 And that means, based on simple mathematics, that 608 00:35:01,250 --> 00:35:03,810 would be proportional to 1 over r 609 00:35:03,810 --> 00:35:10,760 squared for this constant power transfer to happen. 610 00:35:10,760 --> 00:35:13,640 So this means that there's a source. 611 00:35:13,640 --> 00:35:18,050 And if I integrate all the energy transfer 612 00:35:18,050 --> 00:35:20,270 from some kind of surface, it's going 613 00:35:20,270 --> 00:35:26,000 to be a constant, no matter what surface you are choosing. 614 00:35:26,000 --> 00:35:29,630 So that means if I look at the structure of the S 615 00:35:29,630 --> 00:35:32,300 vector, the pointing vector, we can 616 00:35:32,300 --> 00:35:36,010 conclude that at least the electric field 617 00:35:36,010 --> 00:35:41,610 and magnetic field has to be proportional to 1/r, 618 00:35:41,610 --> 00:35:44,600 which is the distance with respect to the source. 619 00:35:44,600 --> 00:35:49,790 Otherwise, it's going to be decaying faster, or reducing 620 00:35:49,790 --> 00:35:56,720 faster than 1/r, then the total power will approach zero 621 00:35:56,720 --> 00:35:58,760 when you increase r enough. 622 00:35:58,760 --> 00:36:01,910 Then that means if you have that happen, 623 00:36:01,910 --> 00:36:06,710 you will not see anything if you are far enough. 624 00:36:06,710 --> 00:36:10,390 So if that's actually the case, we 625 00:36:10,390 --> 00:36:16,670 can now come back and discuss two situations which 626 00:36:16,670 --> 00:36:18,980 we are very familiar with. 627 00:36:18,980 --> 00:36:22,070 For example, you can say, how about I 628 00:36:22,070 --> 00:36:23,420 have a stationary charge? 629 00:36:27,220 --> 00:36:28,710 So I can have a stationary charge 630 00:36:28,710 --> 00:36:30,330 and see what will happen. 631 00:36:30,330 --> 00:36:33,390 And apparently, if I have a charge here 632 00:36:33,390 --> 00:36:37,250 without actually moving it, it's going to emit-- 633 00:36:37,250 --> 00:36:42,750 basically, it is going to have an electric field around this. 634 00:36:42,750 --> 00:36:46,980 But electric field, based on what we learned from 8.02, 635 00:36:46,980 --> 00:36:54,690 is going to be 2 divided by 4 pi epsilon zero r squared r hat. 636 00:36:54,690 --> 00:36:59,090 It's going to be proportional to 1 over r squared. 637 00:36:59,090 --> 00:37:02,130 It's already not very good news, because it's proportional to 1 638 00:37:02,130 --> 00:37:03,330 over r squared. 639 00:37:03,330 --> 00:37:05,530 And it's hitted by this. 640 00:37:05,530 --> 00:37:07,365 The magnetic field is zero. 641 00:37:10,551 --> 00:37:14,360 If I have something times zero it's zero. 642 00:37:14,360 --> 00:37:16,650 Then there will be no energy transfer 643 00:37:16,650 --> 00:37:20,970 if you have a stationary charge just sitting there. 644 00:37:20,970 --> 00:37:22,830 So apparently, this is not a good way 645 00:37:22,830 --> 00:37:27,320 to create electromagnetic wave, based on our argument. 646 00:37:27,320 --> 00:37:32,050 The pointing vector is actually equal to zero. 647 00:37:32,050 --> 00:37:34,940 So now you can say, OK, this is actually too boring, 648 00:37:34,940 --> 00:37:36,760 so let's introduce some excitement. 649 00:37:36,760 --> 00:37:42,780 How about we make this charge moving at a constant speed? 650 00:37:42,780 --> 00:37:44,380 What we can do is like this. 651 00:37:44,380 --> 00:37:47,950 Basically, if you have a positively charged particle, 652 00:37:47,950 --> 00:37:51,780 you can actually make it move at a constant speed, 653 00:37:51,780 --> 00:37:56,060 velocity equal to v. And what you are going to see is that, 654 00:37:56,060 --> 00:37:59,560 oh, indeed, there will be some changes in the electric field 655 00:37:59,560 --> 00:38:00,940 and the magnetic field. 656 00:38:00,940 --> 00:38:03,880 And I'm not going to go through the calculation 657 00:38:03,880 --> 00:38:05,590 of this kind of situation. 658 00:38:05,590 --> 00:38:07,390 And I will leave that as an exercise. 659 00:38:07,390 --> 00:38:11,230 But I would like to tell you what would be the conclusion. 660 00:38:11,230 --> 00:38:15,190 So if you have a single charge, which is essentially 661 00:38:15,190 --> 00:38:19,900 moving at a constant speed, and what is going to happen 662 00:38:19,900 --> 00:38:26,860 is that the electric field density, or the field line 663 00:38:26,860 --> 00:38:28,720 density will change. 664 00:38:28,720 --> 00:38:32,180 And you will be more concentrated in the direction, 665 00:38:32,180 --> 00:38:34,890 which is essentially perpendicular to the direction 666 00:38:34,890 --> 00:38:40,450 of the motion of this charge. 667 00:38:40,450 --> 00:38:42,830 And we can actually calculate what 668 00:38:42,830 --> 00:38:44,980 would be the electric field. 669 00:38:44,980 --> 00:38:52,360 The electric field will be equal to q divided by 4 pi epsilon0 r 670 00:38:52,360 --> 00:38:55,540 squared, 1 minus beta squared. 671 00:38:55,540 --> 00:38:57,580 I will define bet in a moment. 672 00:38:57,580 --> 00:39:00,870 1 minus beta squared sine squared 673 00:39:00,870 --> 00:39:07,270 theta 3/2 in the r direction. 674 00:39:07,270 --> 00:39:15,030 And where the beta is actually defined as u/c, which is u 675 00:39:15,030 --> 00:39:22,070 is actually the velocity of this little charge. 676 00:39:22,070 --> 00:39:24,740 And of course, you can also calculate 677 00:39:24,740 --> 00:39:27,710 what would be the corresponding B, right? 678 00:39:27,710 --> 00:39:33,445 The magnetic field will be actually equal to u plus E 679 00:39:33,445 --> 00:39:36,430 divided by c squared. 680 00:39:36,430 --> 00:39:39,080 And that is actually proportional to 1 681 00:39:39,080 --> 00:39:42,830 over r squared. 682 00:39:42,830 --> 00:39:46,100 As you can see from here, the bad news 683 00:39:46,100 --> 00:39:50,420 is that, OK, you indeed now have both electric field 684 00:39:50,420 --> 00:39:51,540 and the magnetic field. 685 00:39:51,540 --> 00:39:52,940 There is some improvement. 686 00:39:52,940 --> 00:39:57,497 But the problem is that the reduction 687 00:39:57,497 --> 00:39:59,330 of the electric field and the magnetic field 688 00:39:59,330 --> 00:40:00,970 is a function of distance. 689 00:40:00,970 --> 00:40:02,450 It's too large. 690 00:40:02,450 --> 00:40:06,920 Both of them are proportional to 1 over r squared, 691 00:40:06,920 --> 00:40:09,020 proportional to 1 over r squared. 692 00:40:09,020 --> 00:40:13,150 Therefore, the magnitude of S will be proportional 1 693 00:40:13,150 --> 00:40:16,510 over r to the fourth. 694 00:40:16,510 --> 00:40:20,140 So if you are far enough, you can 695 00:40:20,140 --> 00:40:26,200 conclude that the total power will approach zero, 696 00:40:26,200 --> 00:40:30,780 even if you integrate over the whole surface 697 00:40:30,780 --> 00:40:34,570 surrounding this moving charge. 698 00:40:34,570 --> 00:40:38,380 So apparently, that's actually not the solution 699 00:40:38,380 --> 00:40:42,600 we are seeking. 700 00:40:42,600 --> 00:40:45,060 Therefore, we have to do something 701 00:40:45,060 --> 00:40:50,230 more aggressive to accelerate the charge. 702 00:40:50,230 --> 00:40:53,810 So you can now have a charge moving at a constant speed. 703 00:40:53,810 --> 00:40:55,520 We see that it didn't do anything. 704 00:40:55,520 --> 00:40:59,890 Therefore, we have to make the velocity increase 705 00:40:59,890 --> 00:41:02,080 and see what'll happen. 706 00:41:02,080 --> 00:41:06,870 So what I am going to do now requires concentration. 707 00:41:06,870 --> 00:41:09,890 So I will hope that you don't take notes. 708 00:41:09,890 --> 00:41:14,920 Just follow me so that you get what I am trying to argue. 709 00:41:14,920 --> 00:41:18,190 And of course, if you are really good in mathematics, 710 00:41:18,190 --> 00:41:23,470 you can actually also go through page 356 to 360 711 00:41:23,470 --> 00:41:24,730 in George's book. 712 00:41:24,730 --> 00:41:27,180 There are some really mathematical deviations 713 00:41:27,180 --> 00:41:30,460 of the radiation from an accelerated charge. 714 00:41:33,100 --> 00:41:40,160 So let's try to see how can we actually understand 715 00:41:40,160 --> 00:41:42,560 an accelerated charge and what is actually 716 00:41:42,560 --> 00:41:47,150 the associated electromagnetic field. 717 00:41:47,150 --> 00:41:52,590 So my goal is to have some kind of acceleration. 718 00:41:52,590 --> 00:41:54,830 So I would like to set up the stage. 719 00:41:54,830 --> 00:41:58,210 So let's take a look at the slide here. 720 00:41:58,210 --> 00:42:01,970 At t equal to zero, time equal to zero, 721 00:42:01,970 --> 00:42:05,510 before I introduce any excitement, 722 00:42:05,510 --> 00:42:11,270 I have a charged particle initially at rest. 723 00:42:11,270 --> 00:42:13,890 And it's sitting there. 724 00:42:13,890 --> 00:42:17,360 What I'm going to do is that at some point, at t equal to zero, 725 00:42:17,360 --> 00:42:24,170 I try to accelerate this charge until t equal to delta t. 726 00:42:24,170 --> 00:42:30,770 The original position of that charged particle is at a. 727 00:42:30,770 --> 00:42:38,490 And I try to accelerate this charge by acceleration a. 728 00:42:38,490 --> 00:42:42,440 And that only happened in a very small amount of time, 729 00:42:42,440 --> 00:42:44,720 which is delta t. 730 00:42:44,720 --> 00:42:46,810 So what is going to happen is that this charge 731 00:42:46,810 --> 00:42:48,680 will get accelerated. 732 00:42:48,680 --> 00:42:52,640 And you can see that the velocity of the charge-- 733 00:42:52,640 --> 00:42:55,450 you can see velocity as a function of time here-- 734 00:42:55,450 --> 00:42:59,590 is increasing linearly in this period, and reaching 735 00:42:59,590 --> 00:43:04,030 maxima, which is a delta t. 736 00:43:04,030 --> 00:43:08,350 So after that, I stop the acceleration. 737 00:43:08,350 --> 00:43:11,210 So originally, the charge is at rest. 738 00:43:11,210 --> 00:43:14,170 Then I accelerate it for some period of time. 739 00:43:14,170 --> 00:43:19,690 And I stop the acceleration at A prime, or t equal to delta t. 740 00:43:19,690 --> 00:43:23,840 And what is going to happen afterwards to the charge? 741 00:43:23,840 --> 00:43:25,210 Everybody is following? 742 00:43:25,210 --> 00:43:28,420 You will be moving at constant velocity. 743 00:43:28,420 --> 00:43:30,030 Very good. 744 00:43:30,030 --> 00:43:32,090 So that's actually what you see here. 745 00:43:32,090 --> 00:43:36,860 And the wave can actually-- this information can propagate 746 00:43:36,860 --> 00:43:38,290 as a function of time. 747 00:43:38,290 --> 00:43:40,600 So that's actually the whole setup, 748 00:43:40,600 --> 00:43:43,840 which I would like to discuss. 749 00:43:43,840 --> 00:43:46,930 Before that, I would like to bring your attention 750 00:43:46,930 --> 00:43:50,790 to the graph I was trying to draw here. 751 00:43:50,790 --> 00:43:52,290 So you can see that originally there 752 00:43:52,290 --> 00:43:57,560 is a line which is pointing up, like 45 degree with respect 753 00:43:57,560 --> 00:44:00,040 to this charge. 754 00:44:00,040 --> 00:44:04,360 So that's one of the field lines I was drawing here. 755 00:44:04,360 --> 00:44:08,380 That's actually the electric field line. 756 00:44:08,380 --> 00:44:12,970 And as you can see that as I manipulate this charged 757 00:44:12,970 --> 00:44:16,180 particle, this is a sphere-- 758 00:44:16,180 --> 00:44:18,300 or a circle I should-- 759 00:44:18,300 --> 00:44:23,500 on this slide, which is actually telling you 760 00:44:23,500 --> 00:44:28,930 where this information already propagated in the space. 761 00:44:28,930 --> 00:44:32,740 So for example, if I am sitting here 762 00:44:32,740 --> 00:44:35,122 in the position of my little mouse here. 763 00:44:35,122 --> 00:44:35,830 Can you see that? 764 00:44:35,830 --> 00:44:37,990 No, you cannot see it. 765 00:44:37,990 --> 00:44:46,060 If I'm sitting in the upper right corner of the slide, 766 00:44:46,060 --> 00:44:48,340 and I try to-- 767 00:44:48,340 --> 00:44:54,030 then the experiment starts and I move the charge, 768 00:44:54,030 --> 00:45:00,240 the observer at the upper right corner would not feel anything. 769 00:45:00,240 --> 00:45:05,070 Because it takes time for the field, or for the changes, 770 00:45:05,070 --> 00:45:11,430 or for the information to be sent from the position A 771 00:45:11,430 --> 00:45:17,580 to the observer, which are far away from the charged particle. 772 00:45:17,580 --> 00:45:21,060 And the surface which-- 773 00:45:21,060 --> 00:45:26,520 the surface is actually where the information has propagated. 774 00:45:26,520 --> 00:45:32,100 So this information that my charge is accelerated, 775 00:45:32,100 --> 00:45:34,740 this information has already propagated 776 00:45:34,740 --> 00:45:40,950 to a sphere, which is actually far away by c times delta t 777 00:45:40,950 --> 00:45:46,550 away from the center, which is the location 778 00:45:46,550 --> 00:45:47,820 of the charged particle. 779 00:45:47,820 --> 00:45:50,640 And you can see that as time goes on, 780 00:45:50,640 --> 00:45:56,290 this black circle is actually becoming larger and larger, 781 00:45:56,290 --> 00:45:58,070 which contains the information that, 782 00:45:58,070 --> 00:46:01,520 OK, I accelerated the charge. 783 00:46:01,520 --> 00:46:04,620 This is actually where you can see that out of this circle 784 00:46:04,620 --> 00:46:08,340 is as if the charge is stationary. 785 00:46:08,340 --> 00:46:11,380 So you can see the field line is still linear. 786 00:46:11,380 --> 00:46:16,280 And passing through this line, or say, this surface, 787 00:46:16,280 --> 00:46:18,640 the information is already propagated. 788 00:46:18,640 --> 00:46:22,840 If you standing inside this line, like for example, 789 00:46:22,840 --> 00:46:26,380 next to the question mark, if you are there, 790 00:46:26,380 --> 00:46:30,700 you feel, aha, now I observe the acceleration 791 00:46:30,700 --> 00:46:33,610 to the charged particle. 792 00:46:33,610 --> 00:46:39,940 Finally, if I go toward the charged particle even more, 793 00:46:39,940 --> 00:46:44,560 and I will see, aha, if I am now inside the green circle, 794 00:46:44,560 --> 00:46:46,660 I know that this charged particle already 795 00:46:46,660 --> 00:46:48,430 stopped the acceleration. 796 00:46:48,430 --> 00:46:50,920 It's now moving at constant speed. 797 00:46:50,920 --> 00:46:54,760 So that's the meaning of these two little circles. 798 00:46:54,760 --> 00:47:00,570 And now I am looking at the situation at time 799 00:47:00,570 --> 00:47:07,920 equal to t where the charge is at position B. 800 00:47:07,920 --> 00:47:12,550 And I should see something really interesting. 801 00:47:12,550 --> 00:47:17,400 As I mentioned before, if you have a constantly propagating 802 00:47:17,400 --> 00:47:24,830 charge, the field line is actually still 803 00:47:24,830 --> 00:47:29,500 a straight line, actually, right there in the equation. 804 00:47:29,500 --> 00:47:31,510 If you have a stationary charge, it's 805 00:47:31,510 --> 00:47:34,780 also a linear straight line. 806 00:47:34,780 --> 00:47:38,080 And you can see that you have two straight lines, 807 00:47:38,080 --> 00:47:44,850 but in between, there's a kink which connects these two lines. 808 00:47:44,850 --> 00:47:49,680 So between these two lines, basically this 809 00:47:49,680 --> 00:47:51,360 is actually what we have here. 810 00:47:51,360 --> 00:47:54,200 So we have the original particle. 811 00:47:54,200 --> 00:47:58,370 And this is actually where the particle have the field 812 00:47:58,370 --> 00:48:01,220 line as a moving charge. 813 00:48:01,220 --> 00:48:04,890 And there's another surface, which 814 00:48:04,890 --> 00:48:07,250 actually out of the surface, it's 815 00:48:07,250 --> 00:48:11,930 like there is no acceleration at all. 816 00:48:11,930 --> 00:48:15,320 The charge is still stationary at A. 817 00:48:15,320 --> 00:48:20,840 You can see that these two field lines are linear, 818 00:48:20,840 --> 00:48:25,020 and also essentially in the radial direction. 819 00:48:25,020 --> 00:48:28,220 But the excitement is that since the field line has 820 00:48:28,220 --> 00:48:34,760 to be continuous, the excitement is that I have successfully 821 00:48:34,760 --> 00:48:39,210 created a kink, which is actually propagating 822 00:48:39,210 --> 00:48:42,210 in the radial direction. 823 00:48:42,210 --> 00:48:48,390 And this kink is going to be our electromagnetic wave because it 824 00:48:48,390 --> 00:48:53,760 has a component which is perpendicular to the direction 825 00:48:53,760 --> 00:48:54,600 of propagation. 826 00:48:54,600 --> 00:48:56,670 Just a reminder, what is actually 827 00:48:56,670 --> 00:48:59,010 an electromagnetic field looks like, it 828 00:48:59,010 --> 00:49:01,350 looks like this, right? 829 00:49:01,350 --> 00:49:03,120 So basically, you have the electric field 830 00:49:03,120 --> 00:49:07,920 oscillating up and down in one of the directions, 831 00:49:07,920 --> 00:49:09,690 the polarization-- 832 00:49:09,690 --> 00:49:12,780 linearly polarized electromagnetic wave. 833 00:49:12,780 --> 00:49:15,000 And the whole wave is actually propagating 834 00:49:15,000 --> 00:49:17,010 toward the right-hand side of the board. 835 00:49:17,010 --> 00:49:20,490 And the electric field is in the perpendicular direction 836 00:49:20,490 --> 00:49:22,120 of the direction of propagation. 837 00:49:22,120 --> 00:49:26,550 And this kink is actually what we are looking for, OK? 838 00:49:26,550 --> 00:49:32,600 And that really becomes the electromagnetic wave 839 00:49:32,600 --> 00:49:37,130 right there from the point source. 840 00:49:37,130 --> 00:49:40,080 Any questions so far? 841 00:49:40,080 --> 00:49:42,090 Everybody's following? 842 00:49:42,090 --> 00:49:45,060 OK, so now, that's good. 843 00:49:45,060 --> 00:49:49,260 We have managed to create this situation. 844 00:49:49,260 --> 00:49:51,660 And I would like to be more concrete 845 00:49:51,660 --> 00:49:53,740 about several settings. 846 00:49:53,740 --> 00:49:57,630 The first one is actually we have a constant acceleration a, 847 00:49:57,630 --> 00:50:01,140 and this delta t is really small. 848 00:50:01,140 --> 00:50:05,000 Very small delta t, very small acceleration. 849 00:50:05,000 --> 00:50:11,700 Therefore, I would assume that u defined as delta t, 850 00:50:11,700 --> 00:50:15,450 the resulting velocity is much, much smaller 851 00:50:15,450 --> 00:50:17,700 than the speed of light. 852 00:50:17,700 --> 00:50:23,100 So that's actually the setup which I would like to use. 853 00:50:23,100 --> 00:50:26,280 Then the question now is, how do we actually 854 00:50:26,280 --> 00:50:29,490 evaluate what will be the magnitude 855 00:50:29,490 --> 00:50:33,750 of this so-called kink electric field? 856 00:50:33,750 --> 00:50:38,640 So for this, it's actually also pretty easy. 857 00:50:38,640 --> 00:50:43,770 So now I would like to copy the geometry which I have there. 858 00:50:43,770 --> 00:50:50,040 I am trying to draw a copy of that to my board here. 859 00:50:50,040 --> 00:50:55,140 So basically, originally the charge is stationary at A. 860 00:50:55,140 --> 00:51:02,580 And it's emitting an electric field, which is actually only 861 00:51:02,580 --> 00:51:05,520 in the radial direction. 862 00:51:05,520 --> 00:51:09,930 And it got accelerated by a really small time. 863 00:51:09,930 --> 00:51:12,720 I'm exaggerating in that figure, OK? 864 00:51:12,720 --> 00:51:18,210 So it got accelerated a really small amount of time. 865 00:51:18,210 --> 00:51:21,960 And after that, it reached a prime, 866 00:51:21,960 --> 00:51:25,580 which is the exaggerated version is actually probably there. 867 00:51:25,580 --> 00:51:31,110 And A and A prime is, in fact, very, very close to each other, 868 00:51:31,110 --> 00:51:35,040 because this is actually just a very, very small delta t. 869 00:51:35,040 --> 00:51:38,190 I can have delta t goes to zero. 870 00:51:38,190 --> 00:51:42,510 Then A and A prime would be very, very similar. 871 00:51:42,510 --> 00:51:49,130 And now I let the time go on, and now this 872 00:51:49,130 --> 00:51:55,650 charged particle is now at point B. It's moved to point B. 873 00:51:55,650 --> 00:51:59,670 And I can connect B to A and A prime. 874 00:51:59,670 --> 00:52:01,860 And I can actually conclude that, OK, 875 00:52:01,860 --> 00:52:06,160 since the resulting velocity of the charged particle 876 00:52:06,160 --> 00:52:11,100 up to a prime is actually equal to u, defined as a times delta 877 00:52:11,100 --> 00:52:17,490 t, and we are now at time equal to t. 878 00:52:17,490 --> 00:52:20,160 Therefore, the distance these charged 879 00:52:20,160 --> 00:52:24,090 particles pass through, or travel through, 880 00:52:24,090 --> 00:52:27,740 is actually u times t. 881 00:52:27,740 --> 00:52:29,100 Doesn't surprise you, right? 882 00:52:29,100 --> 00:52:30,550 So that's velocity times t. 883 00:52:33,630 --> 00:52:39,020 And also, we can actually calculate this lens. 884 00:52:39,020 --> 00:52:40,390 This lens is actually-- 885 00:52:40,390 --> 00:52:43,500 I call it this point D here, which 886 00:52:43,500 --> 00:52:46,570 is the intersection between the second surface 887 00:52:46,570 --> 00:52:49,350 and the original field line. 888 00:52:49,350 --> 00:52:54,430 And I call this one E, which is the intersection of the field 889 00:52:54,430 --> 00:53:00,310 line from the moving charge and the second surface. 890 00:53:00,310 --> 00:53:04,300 And finally, I also have the intersection, 891 00:53:04,300 --> 00:53:06,910 which I call it F, which is actually 892 00:53:06,910 --> 00:53:10,330 where the field line and the surface actually join, 893 00:53:10,330 --> 00:53:13,270 which is actually the information about the charge 894 00:53:13,270 --> 00:53:18,910 has moved is actually the surface, which 895 00:53:18,910 --> 00:53:22,900 within that surface, people know the charge is actually 896 00:53:22,900 --> 00:53:24,320 already moved. 897 00:53:24,320 --> 00:53:29,070 So once I have all these, I can now evaluate what will be at D 898 00:53:29,070 --> 00:53:33,970 and F. D and F are actually pretty straightforward as well, 899 00:53:33,970 --> 00:53:38,460 because all those surfaces are traveling at the speed of what? 900 00:53:38,460 --> 00:53:40,190 Light, right. 901 00:53:40,190 --> 00:53:44,230 So what is actually the delta t between these two surfaces? 902 00:53:44,230 --> 00:53:46,630 It's delta t, right? 903 00:53:46,630 --> 00:53:51,550 Because I actually stopped the acceleration at delta t, 904 00:53:51,550 --> 00:53:55,840 therefore, the distance between D point and F 905 00:53:55,840 --> 00:53:57,812 is actually just c times delta t. 906 00:54:01,260 --> 00:54:04,500 And of course, now I have this. 907 00:54:04,500 --> 00:54:11,160 I can connect E and D. And roughly, because a and a prime 908 00:54:11,160 --> 00:54:14,700 are very, very close to each other, 909 00:54:14,700 --> 00:54:22,290 and also t is very large, therefore the BE, this line, 910 00:54:22,290 --> 00:54:27,480 is roughly parallel to these AF line. 911 00:54:27,480 --> 00:54:32,760 So these two lines are actually roughly parallel to each other. 912 00:54:32,760 --> 00:54:35,370 Therefore, I can now evaluate what 913 00:54:35,370 --> 00:54:39,510 will be this line, D and E-- 914 00:54:39,510 --> 00:54:43,800 what would be the size of the distance between D and E. 915 00:54:43,800 --> 00:54:45,190 And that can be evaluated. 916 00:54:45,190 --> 00:54:49,920 And it's actually just u perpendicular times t-- 917 00:54:49,920 --> 00:54:55,410 perpendicular to the direction of the field. 918 00:54:55,410 --> 00:54:58,560 And I can copy that here. 919 00:54:58,560 --> 00:55:06,880 The distance between D and E is just u perpendicular times t. 920 00:55:06,880 --> 00:55:10,780 And of course, I can approximate that is actually just a line. 921 00:55:10,780 --> 00:55:13,930 And I have a theta angle which is actually DEF. 922 00:55:17,840 --> 00:55:23,960 So now I can actually try to use this information, 923 00:55:23,960 --> 00:55:28,010 this geometrical argument information, 924 00:55:28,010 --> 00:55:33,620 to figure out what will be the electric field, this kink. 925 00:55:33,620 --> 00:55:41,430 So now I can have the electric field, the same triangle here, 926 00:55:41,430 --> 00:55:43,850 this is angle theta. 927 00:55:43,850 --> 00:55:52,790 And this is the electric field parallel to the AF line. 928 00:55:52,790 --> 00:55:56,970 And I can have also E perp, which 929 00:55:56,970 --> 00:56:01,340 is actually the perpendicular to AF, this line. 930 00:56:01,340 --> 00:56:05,480 And the kink, E kink, is actually 931 00:56:05,480 --> 00:56:10,010 what we would like to figure out as well. 932 00:56:10,010 --> 00:56:14,210 And basically, this E kink is what we want to figure out. 933 00:56:14,210 --> 00:56:18,480 And the E has the following two components. 934 00:56:18,480 --> 00:56:20,060 One is the E parallel. 935 00:56:20,060 --> 00:56:22,070 The other one is the E perp, which 936 00:56:22,070 --> 00:56:25,940 is the perpendicular and the parallel components to the AF 937 00:56:25,940 --> 00:56:28,010 line. 938 00:56:28,010 --> 00:56:31,640 And we can already make use of the similarity of these two 939 00:56:31,640 --> 00:56:32,990 triangles, right? 940 00:56:32,990 --> 00:56:36,920 Basically, this field line is actually pure geometrical, 941 00:56:36,920 --> 00:56:38,870 therefore, I know what is actually 942 00:56:38,870 --> 00:56:41,600 theta from this geometrical argument. 943 00:56:41,600 --> 00:56:46,880 So what is actually theta, basically, you 944 00:56:46,880 --> 00:56:50,470 can get that from the information of c delta t. 945 00:56:50,470 --> 00:56:54,140 And then u perp times t. 946 00:56:54,140 --> 00:56:56,730 So therefore, I can conclude that the magnitude 947 00:56:56,730 --> 00:57:01,810 of E perp divided by magnitude of E parallel 948 00:57:01,810 --> 00:57:11,610 will be equal to u perp t divided by c delta t. 949 00:57:11,610 --> 00:57:15,110 And this E kink is like this. 950 00:57:15,110 --> 00:57:18,290 It actually has a direction. 951 00:57:18,290 --> 00:57:21,710 However, you can see that, wait a second, 952 00:57:21,710 --> 00:57:23,390 you have this ratio, right? 953 00:57:23,390 --> 00:57:28,430 But the E kink is actually pointing to this direction. 954 00:57:28,430 --> 00:57:33,980 And this ut is pointing up to upward direction. 955 00:57:33,980 --> 00:57:37,820 Therefore, if you take this ratio, 956 00:57:37,820 --> 00:57:41,360 the E kink will be pointing to the upper left direction. 957 00:57:41,360 --> 00:57:44,350 Therefore, you really need a minus sign here, right? 958 00:57:44,350 --> 00:57:49,370 Therefore, the E perp would be pointing downward. 959 00:57:49,370 --> 00:57:53,640 Therefore, that's actually how you get this minus sign there. 960 00:57:53,640 --> 00:57:56,210 From this pure geometrical argument, 961 00:57:56,210 --> 00:57:57,780 you can actually conclude what would 962 00:57:57,780 --> 00:58:01,980 be the ratio between E perp and the E parallel, which 963 00:58:01,980 --> 00:58:03,770 is actually equal to that. 964 00:58:03,770 --> 00:58:06,190 And I can write it down explicitly. 965 00:58:06,190 --> 00:58:11,276 Basically, that's going to be equal to a delta t times 966 00:58:11,276 --> 00:58:14,760 t divided by c delta t. 967 00:58:14,760 --> 00:58:21,350 Remember, u is equal to a times delta t. 968 00:58:21,350 --> 00:58:24,350 Therefore, I can now cancel delta t. 969 00:58:24,350 --> 00:58:29,145 Then basically, what I get is minus a perp t divided by c. 970 00:58:32,380 --> 00:58:34,730 And now this is actually equal to minus 971 00:58:34,730 --> 00:58:39,050 a perp r divided by c squared, where 972 00:58:39,050 --> 00:58:42,980 r is actually just c times t. 973 00:58:42,980 --> 00:58:46,640 r is actually the distance between the position 974 00:58:46,640 --> 00:58:56,220 you are evaluating this field and the origin, which is A, OK? 975 00:58:56,220 --> 00:58:58,770 So you can now conclude that-- based 976 00:58:58,770 --> 00:59:01,080 on this geometrical argument, you 977 00:59:01,080 --> 00:59:04,050 can conclude that E perp is highly related 978 00:59:04,050 --> 00:59:06,630 to the E parallel. 979 00:59:06,630 --> 00:59:11,400 The E perp is equal to minus a perp r divided 980 00:59:11,400 --> 00:59:16,462 by c squared E parallel. 981 00:59:16,462 --> 00:59:18,458 Any questions so far? 982 00:59:21,951 --> 00:59:22,949 Yes. 983 00:59:22,949 --> 00:59:24,960 STUDENT: How'd you get r real quick? 984 00:59:24,960 --> 00:59:27,710 PROFESSOR: R is actually-- yeah, so r is actually 985 00:59:27,710 --> 00:59:29,610 just c times t. 986 00:59:29,610 --> 00:59:36,028 So it's the whole distance is the r. 987 00:59:36,028 --> 00:59:37,020 Cool. 988 00:59:37,020 --> 00:59:41,590 All right, so you can see that right now all of those things 989 00:59:41,590 --> 00:59:44,620 are purely geometrical, right? 990 00:59:44,620 --> 00:59:46,200 So this is really no magic. 991 00:59:46,200 --> 00:59:48,790 And no even integration. 992 00:59:48,790 --> 00:59:52,720 So now we are going to do some integration. 993 00:59:52,720 --> 00:59:55,320 So now we are almost there. 994 00:59:55,320 --> 00:59:58,320 I would like to figure out what would be the E kink. 995 00:59:58,320 --> 01:00:02,760 And I am especially interested in E perp, 996 01:00:02,760 --> 01:00:05,070 because E perp is the direction which 997 01:00:05,070 --> 01:00:08,130 is actually perpendicular to the direction of propagation. 998 01:00:08,130 --> 01:00:09,210 It's really cool. 999 01:00:09,210 --> 01:00:11,820 So that's actually related to the magnitude 1000 01:00:11,820 --> 01:00:14,490 of the electromagnetic field radiating. 1001 01:00:14,490 --> 01:00:16,920 So I would like to know E perp, but I 1002 01:00:16,920 --> 01:00:19,470 don't know what is E parallel. 1003 01:00:19,470 --> 01:00:25,650 So what we could do is to use Gauss' law in this example. 1004 01:00:25,650 --> 01:00:28,770 So now what I could do is that I can 1005 01:00:28,770 --> 01:00:35,140 draw a pillbox, which is actually 1006 01:00:35,140 --> 01:00:38,350 through the surface number 1. 1007 01:00:38,350 --> 01:00:40,780 This is actually surface number 1. 1008 01:00:40,780 --> 01:00:45,060 What I could do is I can draw a pillbox which is actually 1009 01:00:45,060 --> 01:00:48,930 passing through the surface number 1. 1010 01:00:48,930 --> 01:00:53,320 Out of surface number 1, we know the physics very well, 1011 01:00:53,320 --> 01:00:55,860 which is actually the electric field 1012 01:00:55,860 --> 01:00:59,310 of a single stationary charge. 1013 01:00:59,310 --> 01:01:02,470 So therefore, I know what is actually the electric field 1014 01:01:02,470 --> 01:01:02,970 outside. 1015 01:01:08,550 --> 01:01:12,010 Which is actually pointing outward 1016 01:01:12,010 --> 01:01:14,640 in the radial direction. 1017 01:01:14,640 --> 01:01:18,870 And the E parallel is actually what we are stuck with. 1018 01:01:18,870 --> 01:01:20,445 So we don't know what is actually 1019 01:01:20,445 --> 01:01:23,060 the magnitude of E parallel. 1020 01:01:23,060 --> 01:01:26,950 That's the electric field inside the surface number 1. 1021 01:01:29,590 --> 01:01:32,250 Makes sense? 1022 01:01:32,250 --> 01:01:36,660 So now we also have the component 1023 01:01:36,660 --> 01:01:41,130 which is actually perpendicular to the direction 1024 01:01:41,130 --> 01:01:42,330 of propagation. 1025 01:01:42,330 --> 01:01:46,140 So this is actually the contribution of the E perp 1026 01:01:46,140 --> 01:01:50,910 and the contribution of E perp, which they go from the side 1027 01:01:50,910 --> 01:01:52,200 to the site. 1028 01:01:52,200 --> 01:01:58,110 Go in from the side, go out from the side of this pillbox. 1029 01:01:58,110 --> 01:02:00,720 So I can now immediately conclude 1030 01:02:00,720 --> 01:02:07,650 that the total contribution of this surface integral 1031 01:02:07,650 --> 01:02:10,750 will be equal to 0, because of Gauss' law. 1032 01:02:10,750 --> 01:02:15,060 There's no charge in my pillbox. 1033 01:02:15,060 --> 01:02:18,180 Therefore, all those things should cancel. 1034 01:02:18,180 --> 01:02:23,720 Apparently, these will cancel, because side 1035 01:02:23,720 --> 01:02:29,050 in, side out, the same magnitude, which is E perp. 1036 01:02:29,050 --> 01:02:31,740 Therefore, that cancel is trivial. 1037 01:02:31,740 --> 01:02:34,650 And the interesting thing is that we can also 1038 01:02:34,650 --> 01:02:41,610 figure out that e parallel will have to be equal to E out. 1039 01:02:45,060 --> 01:02:51,180 So that the sum of all the integral will be equal to 0, 1040 01:02:51,180 --> 01:02:52,970 because of Gauss' law. 1041 01:02:52,970 --> 01:02:55,650 That's actually a very big amount of information, 1042 01:02:55,650 --> 01:03:01,560 because I know how to write down E out. 1043 01:03:01,560 --> 01:03:06,210 So E parallel will be equal to E out. 1044 01:03:06,210 --> 01:03:10,510 We learned from 8.02 this is actually just q divided 1045 01:03:10,510 --> 01:03:14,605 by 4 pi epsilon0 r squared. 1046 01:03:17,550 --> 01:03:19,110 Does that surprise you? 1047 01:03:19,110 --> 01:03:22,920 Should not, right, because out of the surface, 1048 01:03:22,920 --> 01:03:25,200 people think nothing actually really 1049 01:03:25,200 --> 01:03:27,930 happened to the charged particle. 1050 01:03:27,930 --> 01:03:31,500 So it's actually still stationary sitting there. 1051 01:03:31,500 --> 01:03:34,590 So therefore, I have the information of E parallel, 1052 01:03:34,590 --> 01:03:39,660 therefore, I can now conclude what would be the E perp. 1053 01:03:39,660 --> 01:03:47,700 Now, E perp will be equal to minus q a perp divided by 4 pi 1054 01:03:47,700 --> 01:03:52,710 epsilon0 c squared r, because this is actually 1055 01:03:52,710 --> 01:03:55,980 just a perp minus a perp r divided 1056 01:03:55,980 --> 01:04:00,010 by c squared times E parallel. 1057 01:04:00,010 --> 01:04:02,740 Look at what we have achieved. 1058 01:04:02,740 --> 01:04:04,430 Look at this. 1059 01:04:04,430 --> 01:04:08,060 This is actually proportional to what? 1060 01:04:08,060 --> 01:04:10,230 1/r, right? 1061 01:04:10,230 --> 01:04:19,020 So that means the decaying speed of this E perp 1062 01:04:19,020 --> 01:04:23,970 is really slow compared to the electric field 1063 01:04:23,970 --> 01:04:25,890 from a stationary charge. 1064 01:04:25,890 --> 01:04:27,930 So that's actually very encouraging. 1065 01:04:27,930 --> 01:04:31,050 And of course, you can also write down 1066 01:04:31,050 --> 01:04:36,210 what will be the resulting magnetic field. 1067 01:04:36,210 --> 01:04:39,930 And it's going to be also proportional to 1/r. 1068 01:04:39,930 --> 01:04:41,970 So what we can actually conclude is 1069 01:04:41,970 --> 01:04:50,510 that the E rad is a function of direction of the-- 1070 01:04:50,510 --> 01:04:54,450 evaluating this E radiated electric field is 1071 01:04:54,450 --> 01:04:56,370 a function of t. 1072 01:04:56,370 --> 01:04:58,830 And we can actually-- based on this exercise, 1073 01:04:58,830 --> 01:05:02,640 this will be minus q. 1074 01:05:02,640 --> 01:05:05,390 a is a vector, but now I only take 1075 01:05:05,390 --> 01:05:08,300 the perpendicular direction. 1076 01:05:08,300 --> 01:05:11,350 And this thing is actually evaluated 1077 01:05:11,350 --> 01:05:22,570 at t minus r over c divided by 4 pi epsilon0 c squared r. 1078 01:05:22,570 --> 01:05:24,190 Let's take a look at this formula 1079 01:05:24,190 --> 01:05:27,880 closely together, since we have spent a lot of time 1080 01:05:27,880 --> 01:05:29,500 trying to get this result. 1081 01:05:29,500 --> 01:05:31,370 So look at this structure. 1082 01:05:31,370 --> 01:05:35,230 So basically, the radiated energy 1083 01:05:35,230 --> 01:05:40,000 has a minus sign in front of q and a perp, 1084 01:05:40,000 --> 01:05:43,960 because the E kink is actually pointing 1085 01:05:43,960 --> 01:05:45,580 in the opposite direction compared 1086 01:05:45,580 --> 01:05:49,390 to the directional acceleration, as you can see from here. 1087 01:05:49,390 --> 01:05:54,280 The E kink and the E perpendicular 1088 01:05:54,280 --> 01:06:03,640 is pointing to the opposite direction of the acceleration. 1089 01:06:03,640 --> 01:06:07,450 Therefore, we have this minus sign there. 1090 01:06:07,450 --> 01:06:11,680 And only the perpendicular direction motion, acceleration, 1091 01:06:11,680 --> 01:06:14,020 works. 1092 01:06:14,020 --> 01:06:18,670 And there's this little component here, t minus r/c. 1093 01:06:18,670 --> 01:06:20,510 This is actually-- now multiplying 1094 01:06:20,510 --> 01:06:26,690 this factor is evaluated at the t equal to t minus r/c. 1095 01:06:26,690 --> 01:06:28,900 It's evaluated at that time. 1096 01:06:28,900 --> 01:06:34,160 So this is actually evaluated at retarded time. 1097 01:06:34,160 --> 01:06:39,050 So that means I am really slow. 1098 01:06:39,050 --> 01:06:41,150 I need to wait for the information 1099 01:06:41,150 --> 01:06:46,910 to arrive my detector so that I know there are acceleration 1100 01:06:46,910 --> 01:06:49,780 happening. 1101 01:06:49,780 --> 01:06:53,750 Finally, I can now also conclude what 1102 01:06:53,750 --> 01:06:56,060 will be the magnetic field. 1103 01:06:56,060 --> 01:06:59,270 The magnetic field rad, as I mentioned, 1104 01:06:59,270 --> 01:07:01,660 would be proportional to 1/r. 1105 01:07:01,660 --> 01:07:06,610 And of course, I also give you the explicit formula 1106 01:07:06,610 --> 01:07:10,330 in the lecture notes. 1107 01:07:10,330 --> 01:07:14,980 And now we can actually conclude that s will be proportional 1108 01:07:14,980 --> 01:07:17,350 to 1 over r squared. 1109 01:07:17,350 --> 01:07:20,800 So that means I can now send energy 1110 01:07:20,800 --> 01:07:25,600 to the edge of the universe, because of all this hard work 1111 01:07:25,600 --> 01:07:28,000 we have been doing here. 1112 01:07:28,000 --> 01:07:31,520 Any questions? 1113 01:07:31,520 --> 01:07:34,760 All right, before the end of the lecture 1114 01:07:34,760 --> 01:07:38,550 today, I'm going to show you an experiment here. 1115 01:07:38,550 --> 01:07:41,840 So here I have an antenna, which you 1116 01:07:41,840 --> 01:07:46,250 can have electron going back and forth, 1117 01:07:46,250 --> 01:07:52,730 oscillating harmonically really, really fast like this. 1118 01:07:52,730 --> 01:07:55,910 Therefore, there will be acceleration, because 1119 01:07:55,910 --> 01:07:57,950 of this harmonic oscillation. 1120 01:07:57,950 --> 01:07:59,952 And I'm going to turn off the light. 1121 01:08:06,900 --> 01:08:10,620 Also probably hide the image. 1122 01:08:10,620 --> 01:08:14,180 OK, this is good. 1123 01:08:14,180 --> 01:08:21,500 But I have to be able to see the button. 1124 01:08:21,500 --> 01:08:22,450 Can I see it? 1125 01:08:22,450 --> 01:08:24,390 No. 1126 01:08:24,390 --> 01:08:26,206 Oh, I'm in trouble. 1127 01:08:26,206 --> 01:08:28,290 Ah, here. 1128 01:08:28,290 --> 01:08:31,200 OK, here I have a receiver. 1129 01:08:31,200 --> 01:08:35,100 It's also a metal rod. 1130 01:08:35,100 --> 01:08:38,700 And I have a light bulb in between, 1131 01:08:38,700 --> 01:08:43,830 which is actually trying to receive the information from-- 1132 01:08:43,830 --> 01:08:47,340 or say that it receives the electromagnetic wave emitted 1133 01:08:47,340 --> 01:08:49,290 from that source. 1134 01:08:49,290 --> 01:08:51,930 Which you have electrons going back and forth 1135 01:08:51,930 --> 01:08:53,399 in that direction. 1136 01:08:53,399 --> 01:08:57,810 So now, first, I am trying to align 1137 01:08:57,810 --> 01:09:01,649 my setup in this direction so that it's really-- 1138 01:09:01,649 --> 01:09:04,972 what would be the polarization of an electromagnetic wave? 1139 01:09:04,972 --> 01:09:08,689 The polarization is going to be in a horizontal direction. 1140 01:09:08,689 --> 01:09:10,220 Yes, very good. 1141 01:09:10,220 --> 01:09:14,670 Therefore, if I have this set up like this, 1142 01:09:14,670 --> 01:09:17,120 it's actually perpendicular to the direction 1143 01:09:17,120 --> 01:09:21,220 of the polarization, therefore, I see nothing here, 1144 01:09:21,220 --> 01:09:24,350 It is also possible that the light bulb is actually broken, 1145 01:09:24,350 --> 01:09:25,970 but let's see. 1146 01:09:25,970 --> 01:09:30,250 So now what I'm going to do is to change the direction. 1147 01:09:30,250 --> 01:09:31,279 You see that? 1148 01:09:31,279 --> 01:09:35,180 I am moving also closer really carefully. 1149 01:09:35,180 --> 01:09:37,160 Now you can see what happened. 1150 01:09:37,160 --> 01:09:43,470 You can see that now I receive the signal from this machine. 1151 01:09:43,470 --> 01:09:47,630 The emitted light is actually polarized 1152 01:09:47,630 --> 01:09:49,430 in the horizontal direction. 1153 01:09:49,430 --> 01:09:52,470 And now I have also the electron going back and forth, 1154 01:09:52,470 --> 01:09:56,330 and that actually can light up the light bulb. 1155 01:09:56,330 --> 01:09:58,926 Now, if I change the direction, you 1156 01:09:58,926 --> 01:10:01,060 can see that this is actually gone. 1157 01:10:04,850 --> 01:10:06,460 And I can do this again. 1158 01:10:06,460 --> 01:10:09,410 And I can go farther away from the source. 1159 01:10:09,410 --> 01:10:13,450 You can see that now the light is actually disappearing. 1160 01:10:13,450 --> 01:10:14,320 Why? 1161 01:10:14,320 --> 01:10:18,030 That is because you get the 1/r term. 1162 01:10:18,030 --> 01:10:20,310 Therefore, it's actually disappearing. 1163 01:10:20,310 --> 01:10:24,030 And if I move closer to the source, it's reappearing. 1164 01:10:24,030 --> 01:10:29,550 So now I need an assistant to hold this thing for me. 1165 01:10:29,550 --> 01:10:30,600 Who can volunteer? 1166 01:10:30,600 --> 01:10:33,270 And I would like to rotate that. 1167 01:10:33,270 --> 01:10:35,880 I can actually also rotate my setup. 1168 01:10:35,880 --> 01:10:36,660 Can you help? 1169 01:10:36,660 --> 01:10:37,550 Yes. 1170 01:10:37,550 --> 01:10:39,710 OK, be careful. 1171 01:10:39,710 --> 01:10:42,160 And I hope you can survive this. 1172 01:10:44,710 --> 01:10:47,230 So now what am I going to do-- 1173 01:10:47,230 --> 01:10:48,870 OK, so stay there. 1174 01:10:48,870 --> 01:10:53,040 And what I'm going to do is I can rotate the whole setup, 1175 01:10:53,040 --> 01:10:56,270 the same concept. 1176 01:10:56,270 --> 01:10:59,690 If I rotate the setup, I have to be careful so that I am not 1177 01:10:59,690 --> 01:11:01,670 touching this more. 1178 01:11:01,670 --> 01:11:03,690 I want to survive. 1179 01:11:03,690 --> 01:11:05,740 And you can see now what is actually 1180 01:11:05,740 --> 01:11:07,000 the direction of the emission. 1181 01:11:07,000 --> 01:11:09,590 It's actually in this direction, right? 1182 01:11:09,590 --> 01:11:13,410 The direction of the polarization 1183 01:11:13,410 --> 01:11:15,860 is in the back and forth direction. 1184 01:11:15,860 --> 01:11:19,500 And you see that that the light bulb is actually turned off. 1185 01:11:19,500 --> 01:11:23,060 And now I can turn it back on. 1186 01:11:23,060 --> 01:11:24,900 And you see that it's still there. 1187 01:11:24,900 --> 01:11:26,180 OK, thank you very much. 1188 01:11:26,180 --> 01:11:27,050 You survived. 1189 01:11:27,050 --> 01:11:29,030 Not everybody actually survives this. 1190 01:11:29,030 --> 01:11:31,070 [LAUGHTER] 1191 01:11:31,070 --> 01:11:35,780 So you can see it now I can move really close to this thing. 1192 01:11:35,780 --> 01:11:37,920 And what is going to happen? 1193 01:11:37,920 --> 01:11:40,490 The amount of energy will be too high, 1194 01:11:40,490 --> 01:11:44,620 and probably this light bulb will explode or broken. 1195 01:11:44,620 --> 01:11:46,126 Do you want to see that? 1196 01:11:46,126 --> 01:11:47,100 STUDENT: [INAUDIBLE]. 1197 01:11:47,100 --> 01:11:49,540 PROFESSOR: Oh, my god. 1198 01:11:49,540 --> 01:11:50,830 Let's see. 1199 01:11:50,830 --> 01:11:52,288 Ooh, [INAUDIBLE]. 1200 01:11:52,288 --> 01:11:54,760 [LAUGHTER] 1201 01:11:54,760 --> 01:11:56,390 OK, very good. 1202 01:11:56,390 --> 01:11:59,210 So now this experiment is dead. 1203 01:11:59,210 --> 01:12:02,610 And then we can-- it's a very good time 1204 01:12:02,610 --> 01:12:04,660 to close the lecture today. 1205 01:12:04,660 --> 01:12:07,530 And thank you very much for attending the lecture today. 1206 01:12:07,530 --> 01:12:14,130 And I hope now you understand how we actually create light. 1207 01:12:14,130 --> 01:12:19,860 And enjoy the homework, because you 1208 01:12:19,860 --> 01:12:27,270 will be able to figure out why the quarter wave plate 1209 01:12:27,270 --> 01:12:31,500 combination will give you a higher light intensity. 1210 01:12:31,500 --> 01:12:32,940 OK, so if you have any questions, 1211 01:12:32,940 --> 01:12:35,460 I will be here and just standing up here. 1212 01:12:42,732 --> 01:12:44,940 OK, hello everybody. 1213 01:12:44,940 --> 01:12:50,760 Today I'm going to show you a demonstration, which actually 1214 01:12:50,760 --> 01:12:56,370 demonstrates the effect of polarizer and quarter wave 1215 01:12:56,370 --> 01:12:58,470 plate. 1216 01:12:58,470 --> 01:12:59,850 Here is the setup. 1217 01:12:59,850 --> 01:13:07,180 I have a projector here, which emits our polarizer light. 1218 01:13:07,180 --> 01:13:13,810 And if I put a sheet of polarizer on top of it 1219 01:13:13,810 --> 01:13:21,750 with easy axis in the vertical direction, 1220 01:13:21,750 --> 01:13:23,630 like what my finger-- 1221 01:13:23,630 --> 01:13:27,900 in the direction oscillation along the direction 1222 01:13:27,900 --> 01:13:29,600 of my finger, then basically, you 1223 01:13:29,600 --> 01:13:34,710 will see that the intensity of the light is reduced. 1224 01:13:34,710 --> 01:13:39,830 Because for the unpolarized light, 1225 01:13:39,830 --> 01:13:41,340 light component which is actually 1226 01:13:41,340 --> 01:13:46,170 oscillating along the easy axis can pass through the polarizer, 1227 01:13:46,170 --> 01:13:48,600 but the component which is actually 1228 01:13:48,600 --> 01:13:54,250 oscillating perpendicular to the easy axis, like this, 1229 01:13:54,250 --> 01:13:56,190 is not going to pass the polarizer. 1230 01:13:56,190 --> 01:14:00,340 Therefore, a large fraction of unpolarized light 1231 01:14:00,340 --> 01:14:04,230 is actually filtered out, and you will see a reduction 1232 01:14:04,230 --> 01:14:08,440 in the intensity on the screen. 1233 01:14:08,440 --> 01:14:12,990 So what I'm going to do now is to place another polarizer 1234 01:14:12,990 --> 01:14:16,290 on top of the first one. 1235 01:14:16,290 --> 01:14:18,150 So now we have two sheets. 1236 01:14:18,150 --> 01:14:25,290 And you can see that after adding the second sheet, 1237 01:14:25,290 --> 01:14:28,550 you see some change in the intensity. 1238 01:14:28,550 --> 01:14:32,630 But if I rotate this sheet so that now 1239 01:14:32,630 --> 01:14:36,960 the easy axis of the first and the second sheet 1240 01:14:36,960 --> 01:14:40,770 are perpendicular to each other, you can see on the screen 1241 01:14:40,770 --> 01:14:47,520 that all the light which are emitted from the projector 1242 01:14:47,520 --> 01:14:50,660 is actually filtered out. 1243 01:14:50,660 --> 01:14:51,480 Why is that? 1244 01:14:51,480 --> 01:14:56,870 That is because now the first sheet actually filters out 1245 01:14:56,870 --> 01:15:02,310 all that light which is actually oscillating in the direction 1246 01:15:02,310 --> 01:15:05,100 perpendicular to the easy axis. 1247 01:15:05,100 --> 01:15:10,830 If I actually introduce another filter which has easy axis 1248 01:15:10,830 --> 01:15:16,920 now perpendicular to the one from the first sheet, 1249 01:15:16,920 --> 01:15:20,250 then I'm going to filter out both directions. 1250 01:15:20,250 --> 01:15:23,786 Therefore, all the light are filtered out 1251 01:15:23,786 --> 01:15:28,686 due to this putting perpendicular setup. 1252 01:15:28,686 --> 01:15:33,420 Now, if I introduce a third sheet, 1253 01:15:33,420 --> 01:15:36,990 insert that between the two existing sheets, 1254 01:15:36,990 --> 01:15:39,180 but now I am trying to actually insert 1255 01:15:39,180 --> 01:15:44,760 that such that the direction of the easy axis 1256 01:15:44,760 --> 01:15:47,440 is actually 45 degrees with respect 1257 01:15:47,440 --> 01:15:52,230 to the easy axis of the first sheet. 1258 01:15:52,230 --> 01:15:57,180 According to our calculation in class, also in your homework, 1259 01:15:57,180 --> 01:16:02,260 you should see some light which will pass through this setup. 1260 01:16:02,260 --> 01:16:05,130 And let's take a look at the experimental result. 1261 01:16:05,130 --> 01:16:11,070 You can see that, indeed, after you insert a third sheet, 1262 01:16:11,070 --> 01:16:14,970 you see that now the easy axis is actually 1263 01:16:14,970 --> 01:16:18,300 45 degrees with respect to the first sheet. 1264 01:16:18,300 --> 01:16:25,410 And you do see the intensity of the light becomes larger, 1265 01:16:25,410 --> 01:16:29,340 or you see a brighter light output passing 1266 01:16:29,340 --> 01:16:33,250 through these three polarizers. 1267 01:16:33,250 --> 01:16:39,450 And if I rotate it so that actually 1268 01:16:39,450 --> 01:16:43,380 the easy axis of the second sheet is actually changing, 1269 01:16:43,380 --> 01:16:45,700 you can see that it reached maxima 1270 01:16:45,700 --> 01:16:48,360 at roughly 45 degrees, which is actually 1271 01:16:48,360 --> 01:16:54,150 consistent with what we predicted from your homework. 1272 01:16:54,150 --> 01:16:57,510 And then the other thing which you predicted from the homework 1273 01:16:57,510 --> 01:17:03,230 is that if we insert a quarter wave plate between these two 1274 01:17:03,230 --> 01:17:08,250 sheets, you are going to see a brighter light passing 1275 01:17:08,250 --> 01:17:10,440 through this setup. 1276 01:17:10,440 --> 01:17:12,170 So let's actually take a look at what 1277 01:17:12,170 --> 01:17:15,330 will happen by inserting the quarter wave 1278 01:17:15,330 --> 01:17:18,900 plate between these two sheets. 1279 01:17:18,900 --> 01:17:22,230 And this is actually the result. You 1280 01:17:22,230 --> 01:17:29,610 can see that, indeed, the intensity is higher 1281 01:17:29,610 --> 01:17:35,030 compared to the three polarizer experiment. 1282 01:17:35,030 --> 01:17:40,410 And also, the intensity actually reached maxima 1283 01:17:40,410 --> 01:17:45,030 when the fast axis of the polarizer 1284 01:17:45,030 --> 01:17:49,200 is 45 degrees with respect to the easy axis, 1285 01:17:49,200 --> 01:17:51,850 as we predicted from your homework. 1286 01:17:51,850 --> 01:17:55,720 And we can actually put both experimental results side 1287 01:17:55,720 --> 01:17:56,910 by side. 1288 01:17:56,910 --> 01:17:59,430 Indeed, the results from the-- 1289 01:17:59,430 --> 01:18:02,170 so now I am inserting the polarizer also 1290 01:18:02,170 --> 01:18:04,300 between the two sheets. 1291 01:18:04,300 --> 01:18:08,620 And you can see that, indeed, the light passing 1292 01:18:08,620 --> 01:18:12,160 through three polarizers, the intensity 1293 01:18:12,160 --> 01:18:16,980 is actually lower than two polarizers and the one quarter 1294 01:18:16,980 --> 01:18:18,109 wave plate setup. 1295 01:18:25,100 --> 01:18:27,030 Hello, everybody. 1296 01:18:27,030 --> 01:18:29,520 So today, we are going to show you a demonstration 1297 01:18:29,520 --> 01:18:32,250 of dipole radiation. 1298 01:18:32,250 --> 01:18:33,550 Here is the setup. 1299 01:18:33,550 --> 01:18:38,480 So we have a radiator here with two antenna. 1300 01:18:38,480 --> 01:18:41,720 And when I turn it down, there will be current 1301 01:18:41,720 --> 01:18:46,940 going back and forth through these two antenna. 1302 01:18:46,940 --> 01:18:49,070 And therefore, this setup is going 1303 01:18:49,070 --> 01:18:55,610 to emit polarized electromagnetic wave. 1304 01:18:55,610 --> 01:19:00,530 And we are able to detect those electromagnetic waves 1305 01:19:00,530 --> 01:19:08,600 by using a detector here, which consists of two antenna and one 1306 01:19:08,600 --> 01:19:09,590 light bulb here. 1307 01:19:09,590 --> 01:19:18,180 When there are current on this antenna, 1308 01:19:18,180 --> 01:19:21,230 you will see the light emitting from the light bulb. 1309 01:19:21,230 --> 01:19:24,020 And the intensity of the light bulb 1310 01:19:24,020 --> 01:19:26,510 actually can help us to understand 1311 01:19:26,510 --> 01:19:32,510 the structure of the radiation from the dipole radiator. 1312 01:19:32,510 --> 01:19:39,260 So what I am going to do now is to turn this setup on. 1313 01:19:39,260 --> 01:19:43,640 You can see now, the setup is on and the light is on. 1314 01:19:43,640 --> 01:19:49,170 And there will be current going back and forth 1315 01:19:49,170 --> 01:19:52,340 through these two antenna. 1316 01:19:52,340 --> 01:19:57,170 So since the oscillation of the charge will 1317 01:19:57,170 --> 01:19:59,540 generate electromagnetic wave-- 1318 01:19:59,540 --> 01:20:01,670 since the direction of oscillation 1319 01:20:01,670 --> 01:20:06,140 is in the horizontal direction, therefore, the electric field 1320 01:20:06,140 --> 01:20:08,300 of the electromagnetic wave is going 1321 01:20:08,300 --> 01:20:11,550 to be in the horizontal direction. 1322 01:20:11,550 --> 01:20:15,890 So this can be actually verified by using the detector here. 1323 01:20:15,890 --> 01:20:19,610 When my detector-- the direction of the antenna 1324 01:20:19,610 --> 01:20:24,250 is actually perpendicular to the direction of the oscillation, 1325 01:20:24,250 --> 01:20:27,140 you basically don't see any light emitting 1326 01:20:27,140 --> 01:20:29,060 from the light bulb. 1327 01:20:29,060 --> 01:20:32,290 Now I'm going to rotate my detector. 1328 01:20:32,290 --> 01:20:40,070 You can see that as we actually rotate so that the antenna is 1329 01:20:40,070 --> 01:20:43,700 parallel to the direction of the oscillation, 1330 01:20:43,700 --> 01:20:45,260 then you will see that, huh, we will 1331 01:20:45,260 --> 01:20:50,270 see a large intensity of light emitted from the light bulb. 1332 01:20:50,270 --> 01:20:53,680 But on the other hand, if we actually rotate such 1333 01:20:53,680 --> 01:20:57,260 that the direction of the antenna 1334 01:20:57,260 --> 01:21:00,440 is perpendicular to the direction of oscillation 1335 01:21:00,440 --> 01:21:03,020 of the charges, then you will not 1336 01:21:03,020 --> 01:21:07,460 see any light emitted from the light bulb. 1337 01:21:07,460 --> 01:21:10,640 This can also be demonstrated from on the other side 1338 01:21:10,640 --> 01:21:12,150 of the experiment. 1339 01:21:12,150 --> 01:21:15,640 So now, instead of standing in front of the setup, 1340 01:21:15,640 --> 01:21:22,660 I'm going to go to the side of this dipole radiator. 1341 01:21:22,660 --> 01:21:28,040 So here is actually roughly 90 degrees with respect 1342 01:21:28,040 --> 01:21:30,010 to where I was standing. 1343 01:21:30,010 --> 01:21:32,180 And you can see that no matter which angle-- 1344 01:21:35,375 --> 01:21:42,575 no matter which angle of my detector is in, basically, 1345 01:21:42,575 --> 01:21:48,810 you will never see light emitted from the light bulb. 1346 01:21:48,810 --> 01:21:53,230 That is because the direction of the oscillation 1347 01:21:53,230 --> 01:21:54,910 is in this direction. 1348 01:21:54,910 --> 01:21:58,390 And according to our formula, our prediction 1349 01:21:58,390 --> 01:22:04,420 is that there will be no electromagnetic wave traveling 1350 01:22:04,420 --> 01:22:06,870 in this direction. 1351 01:22:06,870 --> 01:22:10,630 And therefore, no matter which angle you are actually 1352 01:22:10,630 --> 01:22:14,380 trying to detect the emitted light, 1353 01:22:14,380 --> 01:22:18,970 the light bulb will never light up. 1354 01:22:18,970 --> 01:22:22,690 So that's essentially consistent with our declaration. 1355 01:22:22,690 --> 01:22:26,800 The second thing which I would like to actually show you 1356 01:22:26,800 --> 01:22:31,720 is that we can also detect the nodal point 1357 01:22:31,720 --> 01:22:36,470 of the emitted electromagnetic wave 1358 01:22:36,470 --> 01:22:43,910 by moving this detector around in the classroom. 1359 01:22:43,910 --> 01:22:51,640 For example, if now I move farther away from the dipole, 1360 01:22:51,640 --> 01:22:56,530 now I am here and you can see that the intensity goes 1361 01:22:56,530 --> 01:23:00,600 to zero at this point, because we are actually 1362 01:23:00,600 --> 01:23:06,980 in one of the nodes of the electromagnetic radiation. 1363 01:23:06,980 --> 01:23:11,080 And if I now move further away from the setup, 1364 01:23:11,080 --> 01:23:17,090 you can see now the light is actually emitting again. 1365 01:23:17,090 --> 01:23:20,210 And also, the intensity increases. 1366 01:23:20,210 --> 01:23:26,935 And again, if I move farther and farther away from the setup, 1367 01:23:26,935 --> 01:23:30,580 you can see that the light becomes dimmer and dimmer, 1368 01:23:30,580 --> 01:23:32,370 and disappears again. 1369 01:23:32,370 --> 01:23:35,840 Here is actually another node in the classroom. 1370 01:23:35,840 --> 01:23:41,390 And also, you can see that as a function of distance, 1371 01:23:41,390 --> 01:23:46,000 the maxima intensity emitted by the light bulb 1372 01:23:46,000 --> 01:23:50,200 is also decreasing because of the larger and larger distance 1373 01:23:50,200 --> 01:23:53,770 with respect to the source. 1374 01:23:53,770 --> 01:23:57,760 So this demonstration actually shows 1375 01:23:57,760 --> 01:24:01,750 that we can understand the dipole radiation. 1376 01:24:01,750 --> 01:24:03,700 And the other experimental results 1377 01:24:03,700 --> 01:24:05,870 are consistent with the calculation 1378 01:24:05,870 --> 01:24:08,390 we have done in class.