WEBVTT 00:00:00.090 --> 00:00:02.490 The following content is provided under a Creative 00:00:02.490 --> 00:00:04.059 Commons license. 00:00:04.059 --> 00:00:06.330 Your support will help MIT mighty OpenCourseWare 00:00:06.330 --> 00:00:10.690 continue to offer high-quality educational resources for free. 00:00:10.690 --> 00:00:13.320 To make a donation or view additional materials 00:00:13.320 --> 00:00:17.290 from hundreds of MIT courses, visit MIT OpenCourseWare 00:00:17.290 --> 00:00:20.611 at ocw.mit.edu. 00:00:20.611 --> 00:00:22.680 PROFESSOR: In a previous demonstration 00:00:22.680 --> 00:00:26.580 on two-beam interference, we saw that the fringe pattern 00:00:26.580 --> 00:00:29.250 was a series of vertical lines. 00:00:29.250 --> 00:00:33.990 The reason was that the two beams were plane waves. 00:00:33.990 --> 00:00:37.800 And the lines were due to the interference of two plane waves 00:00:37.800 --> 00:00:41.370 with a slight angle between them. 00:00:41.370 --> 00:00:43.130 In this demonstration, we're going 00:00:43.130 --> 00:00:46.230 to show that you can get all kinds of shapes in the fringe 00:00:46.230 --> 00:00:50.070 pattern by simply placing a lens in the setup. 00:00:50.070 --> 00:00:52.680 And here is the setup. 00:00:52.680 --> 00:00:55.650 As you may recall, here's the laser. 00:00:55.650 --> 00:00:59.340 Here's the beam from the laser being reflected by this mirror. 00:00:59.340 --> 00:01:03.060 And, here, we're going to add a lens. 00:01:03.060 --> 00:01:06.480 The light coming out of the lens and reflected by this mirror 00:01:06.480 --> 00:01:09.030 here will have some curvature now. 00:01:09.030 --> 00:01:13.740 And when it enters the Michelson interferometer here, 00:01:13.740 --> 00:01:18.120 the beam going to this arm being the longer arm-- 00:01:18.120 --> 00:01:19.900 slightly longer arm-- 00:01:19.900 --> 00:01:22.400 will have slightly different curvature 00:01:22.400 --> 00:01:25.410 when it interferes with the beam coming from this arm, 00:01:25.410 --> 00:01:29.400 because the path length here is shorter than this one. 00:01:29.400 --> 00:01:34.790 The two beams will interfere and pass along this direction. 00:01:34.790 --> 00:01:38.010 Then they will get reflected at this mirror through the lens 00:01:38.010 --> 00:01:40.600 and then onto the screen. 00:01:40.600 --> 00:01:45.150 So, now, if we take a close-up at the fringe pattern, 00:01:45.150 --> 00:01:49.800 we will see that we have circular fringes. 00:01:49.800 --> 00:01:53.760 And what's interesting about the circular fringes 00:01:53.760 --> 00:01:57.750 is that the spacing between the fringes 00:01:57.750 --> 00:02:01.710 can be changed by disturbing the setup. 00:02:01.710 --> 00:02:09.630 For example, if I change the length of this arm here, 00:02:09.630 --> 00:02:13.800 I can change the spacing between the fringes, 00:02:13.800 --> 00:02:15.810 because I'm getting closer. 00:02:15.810 --> 00:02:21.480 I'm closer to the same curvature as in the other arm. 00:02:21.480 --> 00:02:24.900 If I go further, again, we can see 00:02:24.900 --> 00:02:27.450 that I can increase the number of fringes, 00:02:27.450 --> 00:02:30.420 showing that, again, the curvature has 00:02:30.420 --> 00:02:34.800 changed relative to this fixed arm over here. 00:02:34.800 --> 00:02:39.150 Now, I'm going to show the effect of misalignment 00:02:39.150 --> 00:02:42.870 on the circular fringes. 00:02:42.870 --> 00:02:46.520 If I adjust this mirror to here, and then 00:02:46.520 --> 00:02:49.470 let's again look at the fringes, and then you 00:02:49.470 --> 00:02:53.670 can see that by misaligning this mirror, 00:02:53.670 --> 00:03:00.720 I can get arcs instead of the bullseye. 00:03:00.720 --> 00:03:03.750 And, in fact, if I look closely at the arcs, 00:03:03.750 --> 00:03:08.464 I can tell which way the beams are misaligned. 00:03:15.250 --> 00:03:16.570 All right. 00:03:16.570 --> 00:03:24.460 Now, what I'll try and do is to try and make the field go 00:03:24.460 --> 00:03:31.090 all dark or all bright by making the two 00:03:31.090 --> 00:03:35.937 paths as identical as possible. 00:03:35.937 --> 00:03:37.770 Now, you can see, I only have about a couple 00:03:37.770 --> 00:03:41.010 of fringes in the interference pattern. 00:03:41.010 --> 00:03:44.870 They're slightly misaligned. 00:03:44.870 --> 00:03:49.470 So I have them a little better centered. 00:03:49.470 --> 00:03:54.660 So let me close in one path, and then 00:03:54.660 --> 00:03:58.740 see if I can get complete darkness 00:03:58.740 --> 00:04:01.910 or complete brightness. 00:04:01.910 --> 00:04:06.540 Let me adjust the alignment as I move in. 00:04:12.620 --> 00:04:19.720 Here, you can see I'm getting close to equal path. 00:04:19.720 --> 00:04:21.980 And then a little bit more. 00:04:26.960 --> 00:04:27.475 Not quite. 00:04:38.560 --> 00:04:41.720 That's almost-- we're almost there. 00:04:41.720 --> 00:04:43.450 You can see, if I press on the table, 00:04:43.450 --> 00:04:47.870 you can see the screen going bright and dark. 00:04:47.870 --> 00:04:51.850 I think I have a little bit to go. 00:04:51.850 --> 00:05:02.890 And maybe we can get complete extinction. 00:05:02.890 --> 00:05:03.390 Let's see. 00:05:03.390 --> 00:05:15.851 This is pretty close to a complete extinction. 00:05:18.940 --> 00:05:22.050 So in this brief demonstration then, 00:05:22.050 --> 00:05:27.480 we've shown that you can get circular fringes, bullseye, 00:05:27.480 --> 00:05:30.480 arcs, and what have you, by simply 00:05:30.480 --> 00:05:34.170 making the input beam to the interferometer 00:05:34.170 --> 00:05:36.060 have some curvature. 00:05:36.060 --> 00:05:40.830 And by adjusting the path length difference between the two 00:05:40.830 --> 00:05:45.010 arms, you can get a variety of fringe systems.