1 00:00:00,060 --> 00:00:01,780 The following content is provided 2 00:00:01,780 --> 00:00:04,010 under a Creative Commons license. 3 00:00:04,010 --> 00:00:06,870 Your support will help MIT OpenCourseWare continue 4 00:00:06,870 --> 00:00:10,730 to offer high quality educational resources for free. 5 00:00:10,730 --> 00:00:13,340 To make a donation or view additional materials 6 00:00:13,340 --> 00:00:17,217 from hundreds of MIT courses, visit MIT OpenCourseWare 7 00:00:17,217 --> 00:00:17,842 at ocw.mit.edu. 8 00:00:22,120 --> 00:00:23,545 PROFESSOR: OK, let's start. 9 00:00:26,360 --> 00:00:32,360 So, we've moved onto the two-dimensional xy model. 10 00:00:36,910 --> 00:00:43,070 This is a system where, let's say 11 00:00:43,070 --> 00:00:49,410 on each side of a square lattice you put a unit vector that 12 00:00:49,410 --> 00:00:53,030 has two components and hence, can 13 00:00:53,030 --> 00:00:56,605 be described by an angle theta. 14 00:00:56,605 --> 00:01:01,130 So basically, at each side, you have an angle theta 15 00:01:01,130 --> 00:01:02,950 for that side. 16 00:01:02,950 --> 00:01:09,450 And there is a tendency for a neighboring spins to be aligned 17 00:01:09,450 --> 00:01:13,020 and the partition function can be 18 00:01:13,020 --> 00:01:18,670 written as a sum over all configurations, which 19 00:01:18,670 --> 00:01:22,780 is equivalent to integrating over all of these angles. 20 00:01:25,700 --> 00:01:32,490 And the weight that wants to make the two neighboring 21 00:01:32,490 --> 00:01:36,590 spins to be parallel to each other. 22 00:01:36,590 --> 00:01:39,900 So we have a sum over nearest neighbors. 23 00:01:39,900 --> 00:01:43,410 And the dot product of the two spins amounts 24 00:01:43,410 --> 00:01:47,890 to looking at the cosine of theta i minus theta j. 25 00:01:47,890 --> 00:01:51,390 And so, we have this factor over here. 26 00:01:55,460 --> 00:02:05,850 Now, if we go to the limit where k is large, 27 00:02:05,850 --> 00:02:10,210 then the cosine will tend to keep the angles close 28 00:02:10,210 --> 00:02:12,180 to each other. 29 00:02:12,180 --> 00:02:20,080 And we are tempted to expand this around the configurations 30 00:02:20,080 --> 00:02:22,680 where everybody's parallel. 31 00:02:22,680 --> 00:02:28,620 Let's call that nk by the factor of 2. 32 00:02:28,620 --> 00:02:33,530 And then, expanding with the cosine to the next order, 33 00:02:33,530 --> 00:02:40,550 you may want to replace this-- let's call this k0-- 34 00:02:40,550 --> 00:02:44,870 and have a factor of k, which is proportional 35 00:02:44,870 --> 00:02:48,890 to k0 after some lattice spacing. 36 00:02:48,890 --> 00:02:54,990 And integral of gradient of theta squared. 37 00:02:54,990 --> 00:03:01,150 So basically, the difference between the angles 38 00:03:01,150 --> 00:03:04,160 in the continuum version, I want to replace 39 00:03:04,160 --> 00:03:11,000 with the term that tries to make the gradient to be fixed. 40 00:03:11,000 --> 00:03:12,910 OK. 41 00:03:12,910 --> 00:03:18,940 Now the reason I put these quotes around the gradient 42 00:03:18,940 --> 00:03:22,440 is something that we noticed last time, which 43 00:03:22,440 --> 00:03:27,650 is that in principal, theta is defined up 44 00:03:27,650 --> 00:03:30,330 to a multiple of 2 pi. 45 00:03:30,330 --> 00:03:36,290 So that if I were to take a circuit along the lattice 46 00:03:36,290 --> 00:03:39,650 that comes back to itself. 47 00:03:39,650 --> 00:03:49,900 And all along, this circuit integrate this gradient 48 00:03:49,900 --> 00:03:55,260 of theta, so basically, gradient of theta would be a vector. 49 00:03:55,260 --> 00:03:59,330 I integrated along a circuit. 50 00:03:59,330 --> 00:04:03,370 And by the time I have come back and close the circuit to where 51 00:04:03,370 --> 00:04:08,450 I started, the answer may not come back to 0. 52 00:04:08,450 --> 00:04:16,985 It may be any integer multiple of 2 pi. 53 00:04:16,985 --> 00:04:17,485 All right. 54 00:04:22,480 --> 00:04:25,690 So how do we account for this? 55 00:04:25,690 --> 00:04:29,060 The way we account for this is that we 56 00:04:29,060 --> 00:04:38,280 note that this gradient of data I can decompose into two parts. 57 00:04:38,280 --> 00:04:41,240 One, where I just write it as a gradient 58 00:04:41,240 --> 00:04:44,440 of some regular function. 59 00:04:44,440 --> 00:04:46,950 And the characteristic of gradient 60 00:04:46,950 --> 00:04:51,340 is that once you go over a closed loop and you integrate, 61 00:04:51,340 --> 00:04:53,850 you essentially are evaluating this field 62 00:04:53,850 --> 00:04:57,420 phi at the beginning and the end. 63 00:04:57,420 --> 00:05:01,100 And for any regular single valued phi, 64 00:05:01,100 --> 00:05:04,800 this would come back to zero. 65 00:05:04,800 --> 00:05:09,360 And to take care of this fact the result 66 00:05:09,360 --> 00:05:11,770 does not have to come to zero if I integrate 67 00:05:11,770 --> 00:05:19,900 this gradient of theta, I introduce another field, u, 68 00:05:19,900 --> 00:05:26,190 that takes care of these topological defects. 69 00:05:34,390 --> 00:05:36,820 OK? 70 00:05:36,820 --> 00:05:43,370 So that, really, I have to include both configurations 71 00:05:43,370 --> 00:05:48,900 in order to correctly capture the original model that 72 00:05:48,900 --> 00:05:51,380 had these angles. 73 00:05:51,380 --> 00:05:54,890 OK, so what can this u be? 74 00:05:54,890 --> 00:06:02,100 We already looked at what u is for the case of one 75 00:06:02,100 --> 00:06:03,390 topological defect. 76 00:06:13,950 --> 00:06:17,560 And the idea here was that maybe I 77 00:06:17,560 --> 00:06:23,530 had a configuration where around a particular center, 78 00:06:23,530 --> 00:06:29,230 let's say all of the spins were flowing out, 79 00:06:29,230 --> 00:06:32,900 or some other such configuration such 80 00:06:32,900 --> 00:06:41,500 that when I go over a large distance r from this center, 81 00:06:41,500 --> 00:06:51,940 and integrate this field u, just like I did over there, 82 00:06:51,940 --> 00:06:55,620 the answer is going to be, let's say, 2 pi n. 83 00:06:55,620 --> 00:06:58,940 So there's this u. 84 00:06:58,940 --> 00:07:03,960 And I integrated along this circle. 85 00:07:03,960 --> 00:07:08,500 And the answer is going to be 2 pi n. 86 00:07:08,500 --> 00:07:15,460 Well, clearly, the magnitude of u times 87 00:07:15,460 --> 00:07:21,060 2 pi r, which is the radius of the circle 88 00:07:21,060 --> 00:07:25,960 is going to be 2 pi times some integer-- could 89 00:07:25,960 --> 00:07:29,890 be plus, minus 1, plus minus 2. 90 00:07:29,890 --> 00:07:34,010 And so, the magnitude of u is n over r. 91 00:07:43,390 --> 00:07:51,446 The direction of u is orthogonal to the direction of r. 92 00:07:51,446 --> 00:07:53,230 And how can I show that? 93 00:07:53,230 --> 00:07:55,850 Well, one way I can show that is I 94 00:07:55,850 --> 00:08:05,170 can say that it is z hat crossed with r hat, 95 00:08:05,170 --> 00:08:12,490 there z hat is the vector that comes out of the plane. 96 00:08:12,490 --> 00:08:16,260 And r hat is the unit vector in this direction. 97 00:08:16,260 --> 00:08:19,360 u is clearly orthogonal to r. 98 00:08:19,360 --> 00:08:24,530 The direction of the gradient of this angle is orthogonal to r. 99 00:08:24,530 --> 00:08:29,290 It is in the plane so it's orthogonal to this. 100 00:08:29,290 --> 00:08:36,730 And this I can also write as z hat 3 101 00:08:36,730 --> 00:08:43,830 crossed with the gradient of log of r, with some cut-off. 102 00:08:43,830 --> 00:08:47,800 Because the gradient of log of r will give me, 103 00:08:47,800 --> 00:08:51,410 essentially, 1 over R in the direction of r hat. 104 00:08:51,410 --> 00:08:53,540 And this is like the potential that I 105 00:08:53,540 --> 00:08:57,450 would have for a charge in two dimensions, 106 00:08:57,450 --> 00:09:01,640 except that I have rotated it by somewhat. 107 00:09:01,640 --> 00:09:12,070 And this I can also write as minus the curl of z hat 108 00:09:12,070 --> 00:09:16,655 log r over a with a factor of n. 109 00:09:20,120 --> 00:09:24,880 And essentially, what you can see 110 00:09:24,880 --> 00:09:30,610 is that the gradient of data for a field that 111 00:09:30,610 --> 00:09:33,860 has this topological defect has a part 112 00:09:33,860 --> 00:09:39,240 can be written as a potential gradient of some y, 113 00:09:39,240 --> 00:09:43,010 and a part that can be written as curl to keep track 114 00:09:43,010 --> 00:09:45,310 of these vortices, if you like. 115 00:09:45,310 --> 00:09:48,140 If you were to think of this gradient of data 116 00:09:48,140 --> 00:09:50,755 like the flow field that you would have in two dimensions. 117 00:09:50,755 --> 00:09:52,510 It has a potential part. 118 00:09:52,510 --> 00:09:58,480 And it has a part that is due to curvatures and vortices, which 119 00:09:58,480 --> 00:10:01,870 is what we have over here. 120 00:10:01,870 --> 00:10:03,950 OK. 121 00:10:03,950 --> 00:10:08,480 So this is, however, only for one topological defect. 122 00:10:08,480 --> 00:10:11,935 What happens if I have many such defects? 123 00:10:17,390 --> 00:10:22,940 What I can do is, rather than having just one of them, 124 00:10:22,940 --> 00:10:27,690 I could have another topological defect here, another one here, 125 00:10:27,690 --> 00:10:28,600 another one there. 126 00:10:28,600 --> 00:10:32,790 There should be a combination of these things. 127 00:10:32,790 --> 00:10:39,840 And what I can do in order to get the corresponding u 128 00:10:39,840 --> 00:10:45,080 is to superimpose solutions that correspond to single ones. 129 00:10:45,080 --> 00:10:48,180 As you can see that this is very much 130 00:10:48,180 --> 00:10:51,720 like the potential that I would have 131 00:10:51,720 --> 00:10:54,260 for a charge at the origin, and then 132 00:10:54,260 --> 00:10:57,220 taking the derivative to create the field. 133 00:10:57,220 --> 00:11:00,930 And you know that as long as things are linear, 134 00:11:00,930 --> 00:11:02,770 and there aren't too many of them, 135 00:11:02,770 --> 00:11:07,560 you can superimpose solutions for different charges. 136 00:11:07,560 --> 00:11:10,260 You could just add up the electric fields. 137 00:11:10,260 --> 00:11:14,600 So what I'm claiming is that I can write u 138 00:11:14,600 --> 00:11:25,280 as minus n curl of z hat, times some potential u of r, where 139 00:11:25,280 --> 00:11:32,920 psi of r is essentially the generalization of this log. 140 00:11:32,920 --> 00:11:39,000 I can write it as a sum over all topological defects. 141 00:11:39,000 --> 00:11:45,565 And I will have the n of that topological defect times log 142 00:11:45,565 --> 00:11:50,480 of r minus ri divided by a, where 143 00:11:50,480 --> 00:11:53,960 ri are the locations of these. 144 00:11:53,960 --> 00:11:59,350 So there could be a vortex here at r1 with charge n1, 145 00:11:59,350 --> 00:12:04,350 and other topological defect here at r2 with charge n2, 146 00:12:04,350 --> 00:12:06,960 and so forth. 147 00:12:06,960 --> 00:12:12,270 And I can construct a potential that basically looks 148 00:12:12,270 --> 00:12:17,460 at the log of r minus ri for each individual one, 149 00:12:17,460 --> 00:12:20,790 and then do this. 150 00:12:20,790 --> 00:12:21,650 OK? 151 00:12:21,650 --> 00:12:27,100 I will sometimes write this in a slightly different fashion. 152 00:12:27,100 --> 00:12:34,930 Recall that we had the Coulomb potential, which 153 00:12:34,930 --> 00:12:41,550 was related to log by just a factor of 1 over 2 pi. 154 00:12:41,550 --> 00:12:44,830 So the correct version of defining the Coulomb potential 155 00:12:44,830 --> 00:12:46,030 is this. 156 00:12:46,030 --> 00:12:51,330 So this I can write as the Coulomb potential, 157 00:12:51,330 --> 00:12:55,200 provided that I multiply the 2 pi ni. 158 00:12:55,200 --> 00:12:58,190 And I sometimes will call that qi. 159 00:12:58,190 --> 00:13:03,520 So essentially, qi is 2 pi and i is 160 00:13:03,520 --> 00:13:06,770 the charge of the topological defect. 161 00:13:06,770 --> 00:13:09,610 It can be plus or minus 2 pi. 162 00:13:09,610 --> 00:13:12,450 And then, the potential is constructed 163 00:13:12,450 --> 00:13:18,160 by constructing superposition of those charges divided 164 00:13:18,160 --> 00:13:21,611 or multiplied with appropriate Coulomb potential. 165 00:13:21,611 --> 00:13:22,110 OK? 166 00:13:26,520 --> 00:13:27,020 All right. 167 00:13:29,980 --> 00:13:39,190 So I can construct a cost for creating a configuration now. 168 00:13:39,190 --> 00:13:43,580 Previously, I had this integral gradient 169 00:13:43,580 --> 00:13:47,376 of theta squared in the continuum. 170 00:13:47,376 --> 00:13:54,400 And my gradient of theta squared has now 171 00:13:54,400 --> 00:13:59,920 a part that is the gradient of a regular, well-behaved 172 00:13:59,920 --> 00:14:04,890 potential, and a part that is this field 173 00:14:04,890 --> 00:14:13,200 u, which is minus-- oops. 174 00:14:13,200 --> 00:14:15,560 Then I don't need the ni's because I 175 00:14:15,560 --> 00:14:18,470 put the ni as part of the psi. 176 00:14:18,470 --> 00:14:25,760 Curl of z hat psi of r. 177 00:14:25,760 --> 00:14:28,070 So phi is a regular function. 178 00:14:28,070 --> 00:14:33,060 Psi with curl will give me the contribution 179 00:14:33,060 --> 00:14:36,430 of the topological defect involves 180 00:14:36,430 --> 00:14:39,500 both the charges and the positions 181 00:14:39,500 --> 00:14:42,022 of these topological defects. 182 00:14:42,022 --> 00:14:44,990 OK? 183 00:14:44,990 --> 00:14:48,090 And this whole thing has to be squared, of course. 184 00:14:48,090 --> 00:14:52,720 This is my gradient squared. 185 00:14:52,720 --> 00:14:55,810 And if I expand this, I will have three terms. 186 00:14:59,040 --> 00:15:01,540 I have a gradient of this 5 squared. 187 00:15:04,340 --> 00:15:09,980 I have a term, which is minus 2 gradient of phi dot producted 188 00:15:09,980 --> 00:15:14,540 with curl of z hat psi. 189 00:15:17,830 --> 00:15:25,800 And I have a term that is curl of z hat psi squared. 190 00:15:29,180 --> 00:15:29,680 OK? 191 00:15:36,000 --> 00:15:39,470 Again, if you think of this as vector, 192 00:15:39,470 --> 00:15:41,450 this is a vector whose components 193 00:15:41,450 --> 00:15:49,740 are the xy and the y phi, whereas this 194 00:15:49,740 --> 00:15:53,450 is a vector whose components are, let's say, 195 00:15:53,450 --> 00:15:57,380 dy psi minus dx psi. 196 00:15:57,380 --> 00:16:01,340 Because of the curl operation-- the x and y components-- one 197 00:16:01,340 --> 00:16:02,470 of them gets a minus sign. 198 00:16:02,470 --> 00:16:05,950 Maybe I got the minus wrong, but it's essentially 199 00:16:05,950 --> 00:16:06,650 that structure. 200 00:16:09,320 --> 00:16:14,880 Now you can see that if I were to do the integration here, 201 00:16:14,880 --> 00:16:18,220 there is a dx psi, dy psi. 202 00:16:18,220 --> 00:16:22,310 I can do that integration by parts and have, 203 00:16:22,310 --> 00:16:26,340 let's say phi dx dy psi. 204 00:16:26,340 --> 00:16:29,150 And then, I can do the same integration by parts here. 205 00:16:29,150 --> 00:16:33,270 And I will have phi minus dx dy psi. 206 00:16:33,270 --> 00:16:37,230 So if I do integration by part, this will disappear. 207 00:16:37,230 --> 00:16:41,260 Another way of seeing that is that the gradient 208 00:16:41,260 --> 00:16:42,990 will act on the curl. 209 00:16:42,990 --> 00:16:45,570 And the gradient of the curl of a vector is 0, 210 00:16:45,570 --> 00:16:48,830 or otherwise, the curl will act on the gradient 211 00:16:48,830 --> 00:16:50,150 with [INAUDIBLE]. 212 00:16:50,150 --> 00:16:56,890 So basically, this term does not contribute. 213 00:16:56,890 --> 00:17:03,360 And the contribution of this part and the part 214 00:17:03,360 --> 00:17:08,069 from topological defects are decoupled from each other. 215 00:17:08,069 --> 00:17:11,869 So there's essentially the Gaussian type of stuff 216 00:17:11,869 --> 00:17:14,579 that we calculated before is here. 217 00:17:14,579 --> 00:17:18,150 On top of that, there is this part 218 00:17:18,150 --> 00:17:20,969 that is due to these topological defects. 219 00:17:23,849 --> 00:17:29,170 Again, this vector is this squared. 220 00:17:29,170 --> 00:17:30,950 You can see that if I square it, I 221 00:17:30,950 --> 00:17:34,980 will get dy psi squared plus dx psi squared. 222 00:17:34,980 --> 00:17:37,580 So to all intents and purposes, this thing 223 00:17:37,580 --> 00:17:44,050 is the same thing as a gradient of psi squared. 224 00:17:44,050 --> 00:17:46,510 Essentially, gradient of psi and curl of psi 225 00:17:46,510 --> 00:17:49,980 are the same vector, just rotated by 90 degrees. 226 00:17:49,980 --> 00:17:52,890 Integrating the square of one over the whole space 227 00:17:52,890 --> 00:17:56,430 is the same as integrating the square of the other. 228 00:17:56,430 --> 00:17:58,430 OK? 229 00:17:58,430 --> 00:18:04,020 So now, let's calculate this contribution and what it is. 230 00:18:04,020 --> 00:18:11,250 Integral d2 x gradient of psi squared with K over 2 231 00:18:11,250 --> 00:18:16,280 out front-- actually you already know that. 232 00:18:16,280 --> 00:18:22,590 Because psi we see is the potential 233 00:18:22,590 --> 00:18:23,945 due to a bunch of charges. 234 00:18:26,690 --> 00:18:29,630 So this is essentially the electric field 235 00:18:29,630 --> 00:18:32,370 due to this combination of charges 236 00:18:32,370 --> 00:18:34,760 integrated over the entire space. 237 00:18:34,760 --> 00:18:37,530 It's the electrostatic image. 238 00:18:37,530 --> 00:18:41,090 But let's go through that step by step. 239 00:18:41,090 --> 00:18:45,320 Let's do the integration by parts. 240 00:18:45,320 --> 00:18:49,790 So this becomes minus k over 2. 241 00:18:49,790 --> 00:18:57,900 Integral d2 x psi the gradient acting on this 242 00:18:57,900 --> 00:19:01,500 will give me Laplacian of psi. 243 00:19:01,500 --> 00:19:06,250 Of course, whenever I do integration by parts, 244 00:19:06,250 --> 00:19:08,620 I have to worry about boundary terms. 245 00:19:15,360 --> 00:19:17,550 And essentially, if you think of what 246 00:19:17,550 --> 00:19:21,260 you will be seeing at the boundary, far, 247 00:19:21,260 --> 00:19:26,260 far away from there all of these charges are, let's say. 248 00:19:26,260 --> 00:19:30,120 Essentially, you will see the electric field 249 00:19:30,120 --> 00:19:34,910 due to the combination of all of those charges. 250 00:19:34,910 --> 00:19:42,170 So for a single one, I will have a large electric field 251 00:19:42,170 --> 00:19:44,750 that will go as 1 over r. 252 00:19:44,750 --> 00:19:48,480 And we saw that integrating that will give me the log. 253 00:19:48,480 --> 00:19:50,990 So that was not particularly nice. 254 00:19:50,990 --> 00:19:54,390 So similarly, what these boundary terms 255 00:19:54,390 --> 00:19:58,120 would amount to would give you some kind 256 00:19:58,120 --> 00:20:01,470 of a logarithmic energy that depends on the next charge 257 00:20:01,470 --> 00:20:03,470 that you have enclosed. 258 00:20:03,470 --> 00:20:17,070 And you can get rid of it by setting the next charge 259 00:20:17,070 --> 00:20:18,225 to be zero. 260 00:20:23,050 --> 00:20:28,390 So essentially, any configuration 261 00:20:28,390 --> 00:20:33,930 in which the sum total of our topological charges is non-zero 262 00:20:33,930 --> 00:20:38,270 will get a huge energy cost as we go to large distances 263 00:20:38,270 --> 00:20:40,140 from the self-energy, if you like, 264 00:20:40,140 --> 00:20:42,980 of creating this huge monopole. 265 00:20:42,980 --> 00:20:45,600 So we are going to use this condition 266 00:20:45,600 --> 00:20:48,140 and focus only on configurations that 267 00:20:48,140 --> 00:20:52,390 are charged topological charge neutral. 268 00:20:52,390 --> 00:20:53,530 OK. 269 00:20:53,530 --> 00:20:59,050 Now our psi is what I have over here. 270 00:20:59,050 --> 00:21:03,950 It is sum over i qi. 271 00:21:03,950 --> 00:21:06,930 This Coulomb interaction-- r minus ri. 272 00:21:10,740 --> 00:21:18,560 And therefore, Laplacian of psi is essentially 273 00:21:18,560 --> 00:21:21,300 taking the Laplacian of this expression 274 00:21:21,300 --> 00:21:25,590 is the sum over j qu. 275 00:21:25,590 --> 00:21:28,395 Laplacian of this is the delta function. 276 00:21:33,150 --> 00:21:35,700 So basically, that was the condition 277 00:21:35,700 --> 00:21:37,100 for the Coulomb potential. 278 00:21:37,100 --> 00:21:40,900 Or alternatively, you take 2 derivative of the log, 279 00:21:40,900 --> 00:21:45,390 and you will generate the delta function. 280 00:21:45,390 --> 00:21:47,430 OK? 281 00:21:47,430 --> 00:21:56,990 So, what you see is that you generate the following. 282 00:21:56,990 --> 00:22:12,210 You will get a minus k over 2 sum over pairs i and j, qi, qj. 283 00:22:12,210 --> 00:22:15,610 And then I have the integral over x or r-- 284 00:22:15,610 --> 00:22:17,240 they're basically the same thing. 285 00:22:17,240 --> 00:22:18,985 Maybe I should have written this as x. 286 00:22:23,860 --> 00:22:29,710 And the delta function insures that x 287 00:22:29,710 --> 00:22:33,462 is set to be the other i. 288 00:22:33,462 --> 00:22:35,890 So I will get the Coulomb interaction 289 00:22:35,890 --> 00:22:40,010 between ri minus rj. 290 00:22:40,010 --> 00:22:46,710 So basically, what you have is that these topological defects 291 00:22:46,710 --> 00:22:51,730 that are characterized by these integers n, or by the charges 292 00:22:51,730 --> 00:22:56,540 2 pi n, have exactly this logarithmic Coulomb 293 00:22:56,540 --> 00:22:57,500 interaction. 294 00:22:57,500 --> 00:22:58,770 in two dimensions. 295 00:22:58,770 --> 00:23:01,750 And as I said, this thing is none other 296 00:23:01,750 --> 00:23:03,990 than the electrostatic energy. 297 00:23:03,990 --> 00:23:06,180 The electrostatic energy you can write either 298 00:23:06,180 --> 00:23:08,930 as an integral of the electric field squared. 299 00:23:08,930 --> 00:23:11,640 Or you can write as the interaction 300 00:23:11,640 --> 00:23:16,900 among the charges that give rise to that electric field. 301 00:23:16,900 --> 00:23:19,620 OK? 302 00:23:19,620 --> 00:23:26,990 So, what I can do is I can write this as follows. 303 00:23:26,990 --> 00:23:32,160 First of all, I can maybe re-cast it in terms of the n's. 304 00:23:32,160 --> 00:23:36,820 So I will have 2 pi ni, 2 pi nj. 305 00:23:36,820 --> 00:23:43,330 So I will get minus 4pi squared k. 306 00:23:43,330 --> 00:23:46,010 There's a factor of one-half. 307 00:23:46,010 --> 00:23:49,870 But this is a sum over i and j-- so every pair is now 308 00:23:49,870 --> 00:23:51,700 counted twice. 309 00:23:51,700 --> 00:23:54,080 So I get rid of that factor of one-half 310 00:23:54,080 --> 00:24:00,180 by essentially counting each pair only once. 311 00:24:00,180 --> 00:24:04,450 So I have the Coulomb interaction 312 00:24:04,450 --> 00:24:08,610 between ri and rj, which is this 1 over 2 pi 313 00:24:08,610 --> 00:24:13,390 log of ri minus rj with some cut-off. 314 00:24:13,390 --> 00:24:17,320 And then, there's the term that corresponds to i equals 2j. 315 00:24:17,320 --> 00:24:30,340 So I will have a minus, let's say, 4pi squared k sum over i. 316 00:24:30,340 --> 00:24:33,040 And I forgot here to put n, i, and j. 317 00:24:36,470 --> 00:24:39,730 I will have ni squared. 318 00:24:39,730 --> 00:24:43,334 The Coulomb interaction at zero. 319 00:24:43,334 --> 00:24:44,250 ri equals [INAUDIBLE]. 320 00:24:46,970 --> 00:24:53,240 Now clearly, this expression does not make sense. 321 00:24:53,240 --> 00:24:58,640 What it is trying to tell me is that there 322 00:24:58,640 --> 00:25:06,340 is a cost to creating one of these topological charges. 323 00:25:06,340 --> 00:25:11,810 And all of this theory-- again, in order to make sense, 324 00:25:11,810 --> 00:25:15,220 we should remember to put some kind of a short distance 325 00:25:15,220 --> 00:25:16,670 cut-off a. 326 00:25:16,670 --> 00:25:18,550 All right? 327 00:25:18,550 --> 00:25:26,110 And basically, replacing this original discrete lattice 328 00:25:26,110 --> 00:25:31,040 with a continuum will only work as long as 329 00:25:31,040 --> 00:25:35,830 I keep in mind that I cannot regard things at the level 330 00:25:35,830 --> 00:25:40,640 of lattice spacing, and replace it by that formula, as we saw, 331 00:25:40,640 --> 00:25:41,800 for example, here. 332 00:25:41,800 --> 00:25:45,340 If I want to draw a topological defect, 333 00:25:45,340 --> 00:25:48,430 I would need right at the center to do something 334 00:25:48,430 --> 00:25:52,630 like this-- where replacing the cosines with the gradient 335 00:25:52,630 --> 00:25:55,120 squared kind of doesn't make sense. 336 00:25:55,120 --> 00:25:57,030 So basically, what this theory is 337 00:25:57,030 --> 00:26:03,440 telling me is that once you get to a very small distance, 338 00:26:03,440 --> 00:26:08,550 you have to keep track of the existence 339 00:26:08,550 --> 00:26:13,520 of some underlying lattice and the corresponding things. 340 00:26:13,520 --> 00:26:16,270 And what's really this is describing 341 00:26:16,270 --> 00:26:22,720 for you is the core energy of creating 342 00:26:22,720 --> 00:26:26,670 a defect that has object ni. 343 00:26:26,670 --> 00:26:27,470 OK. 344 00:26:27,470 --> 00:26:37,660 What do I mean by that is that over here, I 345 00:26:37,660 --> 00:26:43,485 can calculate what the partition function is for one defect. 346 00:26:43,485 --> 00:26:46,550 This we already did last time around. 347 00:26:46,550 --> 00:26:50,780 And for that, I can integrate out this energy 348 00:26:50,780 --> 00:26:56,650 that I have for the distortions. 349 00:26:56,650 --> 00:27:02,470 It's an integral of n over r squared. 350 00:27:02,470 --> 00:27:07,980 And this integration gave me this factor of e 351 00:27:07,980 --> 00:27:20,752 to the minus pi k log of r over a-- actually, that was 2 pi k. 352 00:27:20,752 --> 00:27:25,380 Actually, let's do this correctly once. 353 00:27:29,320 --> 00:27:32,100 I should have done it earlier, and I forgot. 354 00:27:32,100 --> 00:27:37,130 So you have one defect. 355 00:27:37,130 --> 00:27:45,460 And we saw that for one defect, the field at the distance r 356 00:27:45,460 --> 00:27:50,140 has n over r in magnitude. 357 00:27:53,830 --> 00:28:00,370 And then, the net energy cost for one of these defects-- 358 00:28:00,370 --> 00:28:05,120 if I say that I believe this formula starting 359 00:28:05,120 --> 00:28:14,380 from a distance a is the k over 2 integral from a. 360 00:28:14,380 --> 00:28:17,925 Let's say all the way up to the size of my system. 361 00:28:20,780 --> 00:28:29,630 I have 2 pi r dr from a shell at radius r 362 00:28:29,630 --> 00:28:32,880 magnitude of this u squared. 363 00:28:32,880 --> 00:28:37,830 So I have n squared over r squared. 364 00:28:37,830 --> 00:28:41,860 But then, I have to worry about all of the actual things 365 00:28:41,860 --> 00:28:45,320 that I have off the distance a. 366 00:28:45,320 --> 00:28:50,510 So on top of this, there is a core energy 367 00:28:50,510 --> 00:28:56,760 for creating this object that certainly explicitly depends on 368 00:28:56,760 --> 00:29:00,320 where I sit this parameter a. 369 00:29:00,320 --> 00:29:02,120 OK? 370 00:29:02,120 --> 00:29:06,740 This part is easy. 371 00:29:06,740 --> 00:29:13,510 It simply gives me pi km squared. 372 00:29:13,510 --> 00:29:16,200 And then I have the integral of 1 373 00:29:16,200 --> 00:29:21,340 over r, which gives me log of L over a. 374 00:29:26,290 --> 00:29:31,790 So if I want to imagine what the partition function of this 375 00:29:31,790 --> 00:29:38,560 is-- one defect in a system of size L-- 376 00:29:38,560 --> 00:29:46,160 I would say that z of one defect is Boltzmann weight responding 377 00:29:46,160 --> 00:29:47,660 to creating this entity. 378 00:29:47,660 --> 00:29:54,570 So I have e to the minus pi k m squared log of L over a. 379 00:29:54,570 --> 00:30:02,360 And then I have the core energy that corresponds to this. 380 00:30:02,360 --> 00:30:07,190 And then, as we discussed, I can place this anywhere 381 00:30:07,190 --> 00:30:10,750 in the system if I'm calculating the partition function. 382 00:30:10,750 --> 00:30:14,130 So there's an integration over the position 383 00:30:14,130 --> 00:30:16,570 of this that is implicit. 384 00:30:16,570 --> 00:30:19,480 And so, that's going to give me the square 385 00:30:19,480 --> 00:30:27,770 of the size of my system, except that I am unsure as 386 00:30:27,770 --> 00:30:33,330 to where I have placed things up to this cut-off a. 387 00:30:33,330 --> 00:30:37,310 So really, the number of distinct 388 00:30:37,310 --> 00:30:43,710 positions that I have scales like L over a squared. 389 00:30:43,710 --> 00:30:48,870 So the whole thing we can see scales like L 390 00:30:48,870 --> 00:30:52,790 over a 2 minus pi km squared. 391 00:30:55,470 --> 00:31:03,660 And then, there is this factor of e to the minus 392 00:31:03,660 --> 00:31:08,180 this core energy evaluated at the distance 393 00:31:08,180 --> 00:31:10,250 a that I will call y. 394 00:31:13,550 --> 00:31:15,480 Because again, in some sense, there's 395 00:31:15,480 --> 00:31:19,280 some arbitrariness in where I choose a. 396 00:31:19,280 --> 00:31:24,590 So this y would be a function of a, if we depend on that choice. 397 00:31:24,590 --> 00:31:28,190 But the most important thing is that if I 398 00:31:28,190 --> 00:31:34,830 have a huge system, whether or not this partition function, 399 00:31:34,830 --> 00:31:38,630 as a function of the size of the system, goes to infinity 400 00:31:38,630 --> 00:31:45,470 or goes to 0 is controlled by this exponent 2 minus pi k. 401 00:31:45,470 --> 00:31:49,040 Let's say we focus on the simplest of topological defects 402 00:31:49,040 --> 00:31:53,030 corresponding to n equal 2 minus plus 1. 403 00:31:53,030 --> 00:31:56,650 You expect that there is some potentially critical value 404 00:31:56,650 --> 00:32:02,940 of k, which is 2 over pi, that distinguishes the two 405 00:32:02,940 --> 00:32:06,830 types of behavior. 406 00:32:06,830 --> 00:32:09,460 OK? 407 00:32:09,460 --> 00:32:16,060 But this picture is nice, but certainly incomplete. 408 00:32:16,060 --> 00:32:22,270 Because who said that there's any legitimacy in calculating 409 00:32:22,270 --> 00:32:24,390 the partition function that corresponds 410 00:32:24,390 --> 00:32:27,700 to just a single topological defect. 411 00:32:27,700 --> 00:32:31,680 If I integrate over all the configurations of my angle 412 00:32:31,680 --> 00:32:38,280 field, I should really be doing something 413 00:32:38,280 --> 00:32:43,700 that is analogous to this and calculating a partition 414 00:32:43,700 --> 00:32:47,270 function that corresponds to many defects. 415 00:32:47,270 --> 00:32:52,080 And actually what I calculated over here was in some sense 416 00:32:52,080 --> 00:32:54,960 the configuration of spins given that there 417 00:32:54,960 --> 00:32:59,170 is a topological defects that has the lowest energy. 418 00:32:59,170 --> 00:33:01,900 Once I start with this configuration-- let's 419 00:33:01,900 --> 00:33:04,270 say, with everybody radiating out-- 420 00:33:04,270 --> 00:33:07,620 I can start to distort them a little bit which 421 00:33:07,620 --> 00:33:13,060 amounts to adding this gradient of phi to that. 422 00:33:13,060 --> 00:33:15,940 So really, the partition function 423 00:33:15,940 --> 00:33:19,900 that I want to calculate and wrote down at the beginning-- 424 00:33:19,900 --> 00:33:23,680 if I want to calculate correctly, 425 00:33:23,680 --> 00:33:28,970 I have to include both these fluctuations 426 00:33:28,970 --> 00:33:31,900 and these fluctuations corresponding 427 00:33:31,900 --> 00:33:38,910 to an arbitrary set of these topological defects. 428 00:33:38,910 --> 00:33:44,820 And what we see is that actually, the partition 429 00:33:44,820 --> 00:33:49,460 functions and the energy costs of the two components 430 00:33:49,460 --> 00:33:51,200 really separate out. 431 00:33:51,200 --> 00:33:53,360 And what we are trying to calculate 432 00:33:53,360 --> 00:33:58,000 is the contribution that is due to the topological defects. 433 00:33:58,000 --> 00:34:02,400 And what we see is that once I tell you 434 00:34:02,400 --> 00:34:06,500 where the topological defects are located, 435 00:34:06,500 --> 00:34:12,790 the partition function for them has an energy component that 436 00:34:12,790 --> 00:34:16,560 is this Coulomb interaction among the defect. 437 00:34:16,560 --> 00:34:21,320 But there is a part that really is 438 00:34:21,320 --> 00:34:28,400 a remnant of this core energy that we 439 00:34:28,400 --> 00:34:31,610 were calculating before. 440 00:34:31,610 --> 00:34:35,969 So when I was sort of following my nose here, 441 00:34:35,969 --> 00:34:39,949 I had forgotten a little bit about the short distance 442 00:34:39,949 --> 00:34:40,940 cut-off. 443 00:34:40,940 --> 00:34:44,739 And then, when I encountered this C of zero, 444 00:34:44,739 --> 00:34:48,690 it told me that I have to think about the limit 445 00:34:48,690 --> 00:34:51,380 when two things come close to each other. 446 00:34:51,380 --> 00:34:56,360 And I know that that limit is constrained 447 00:34:56,360 --> 00:34:59,190 by my original lattice, and more importantly, 448 00:34:59,190 --> 00:35:02,560 by the place where I am willing to do 449 00:35:02,560 --> 00:35:10,140 self-averaging and replace this sum with a gradient. 450 00:35:10,140 --> 00:35:15,740 OK, so basically, this is the explanation of this term. 451 00:35:15,740 --> 00:35:18,280 So the only thing that we have established so far 452 00:35:18,280 --> 00:35:22,950 is that this partition function that I wrote down 453 00:35:22,950 --> 00:35:28,530 at the beginning gets decomposed into a part 454 00:35:28,530 --> 00:35:33,130 that we have calculated before, which was the Gaussian term, 455 00:35:33,130 --> 00:35:38,540 and is caused, really, the contribution due to spin waves. 456 00:35:38,540 --> 00:35:44,340 So this is when we just consider these [INAUDIBLE] modes, 457 00:35:44,340 --> 00:35:47,470 we said that essentially you can have an energy 458 00:35:47,470 --> 00:35:49,400 cost that is the gradient squared. 459 00:35:49,400 --> 00:35:54,900 So this is the part that corresponds to integral d phi 460 00:35:54,900 --> 00:36:00,150 into the minus k over 2 integral d2 x gradient of phi squared, 461 00:36:00,150 --> 00:36:03,305 where phi is a well-behaved, ordinary function. 462 00:36:11,300 --> 00:36:18,970 And what we find is that the actual partition function also 463 00:36:18,970 --> 00:36:25,100 has the contribution from the topological defects. 464 00:36:25,100 --> 00:36:31,670 And that I will indicate by ZQ. 465 00:36:31,670 --> 00:36:34,250 And Q stands for Coulomb gas. 466 00:36:39,260 --> 00:36:46,340 Because this partition function Z sub Q 467 00:36:46,340 --> 00:36:53,550 is like I'm trying to calculate this system of degrees 468 00:36:53,550 --> 00:37:00,080 of freedom that are characterized by charges n that 469 00:37:00,080 --> 00:37:04,270 can be anywhere in this two-dimensional space. 470 00:37:04,270 --> 00:37:08,300 And the interaction between them is governed by the Coulomb 471 00:37:08,300 --> 00:37:10,990 interaction in two dimensions. 472 00:37:10,990 --> 00:37:15,640 So to calculate this, I have to sum over 473 00:37:15,640 --> 00:37:19,040 all configuration of charges. 474 00:37:22,110 --> 00:37:26,520 The number of these charges could be zero, could be two, 475 00:37:26,520 --> 00:37:30,590 could be four, could be six, could be any number. 476 00:37:30,590 --> 00:37:33,540 But I say even numbers because I want 477 00:37:33,540 --> 00:37:37,040 to maintain the constraint of neutrality. 478 00:37:37,040 --> 00:37:39,450 Sum over ni should be zero. 479 00:37:39,450 --> 00:37:42,310 So I want to do that constrained sum. 480 00:37:42,310 --> 00:37:47,410 So I only want to look at neutral configurations. 481 00:37:47,410 --> 00:37:49,530 Once I have specified-- let's say 482 00:37:49,530 --> 00:37:57,310 that I have eight charges-- four plus and four minus-- well, 483 00:37:57,310 --> 00:38:01,540 there is a term that is going to come from here 484 00:38:01,540 --> 00:38:06,170 and I kind of said that the exponential of this term I'm 485 00:38:06,170 --> 00:38:08,700 going to call y. 486 00:38:08,700 --> 00:38:13,110 So I have essentially y raised to the power 487 00:38:13,110 --> 00:38:15,630 of the number of charges. 488 00:38:15,630 --> 00:38:19,190 Let's call this sum over i ni squared. 489 00:38:19,190 --> 00:38:21,730 And I'm actually just going to constrain ni 490 00:38:21,730 --> 00:38:23,480 to be minus plus 1. 491 00:38:23,480 --> 00:38:27,300 I'm going to only look at these primary charges. 492 00:38:27,300 --> 00:38:29,930 So the sum over i and i squared is just 493 00:38:29,930 --> 00:38:32,970 the total number of charges irrespective 494 00:38:32,970 --> 00:38:35,135 of whether they are plus or minus. 495 00:38:35,135 --> 00:38:39,390 It basically is replacing this. 496 00:38:39,390 --> 00:38:44,610 And then, I have to integrate over 497 00:38:44,610 --> 00:38:46,880 the positions of these charges. 498 00:38:46,880 --> 00:38:49,570 Let's call this total number n. 499 00:38:49,570 --> 00:38:56,400 So I have to integrate i1 2n d2 xi 500 00:38:56,400 --> 00:39:00,110 the position of where this charge is 501 00:39:00,110 --> 00:39:05,440 and then interaction which is exponential of minus 502 00:39:05,440 --> 00:39:11,610 4phi squared k sum over i less than j. 503 00:39:11,610 --> 00:39:17,130 And i and j the Coulomb interaction between location 504 00:39:17,130 --> 00:39:18,810 let's say xi and xj. 505 00:39:27,580 --> 00:39:32,240 Actually, I want to also emphasize that throughout, 506 00:39:32,240 --> 00:39:33,770 I have this cut-off. 507 00:39:33,770 --> 00:39:36,790 So when I was integrating over one, 508 00:39:36,790 --> 00:39:38,990 I said that the number of positions that I had 509 00:39:38,990 --> 00:39:42,760 was not L squared, but L over a squared to make it 510 00:39:42,760 --> 00:39:44,500 dimensionless. 511 00:39:44,500 --> 00:39:47,505 I will similarly make these interactions dimensioned 512 00:39:47,505 --> 00:39:49,180 as I divide by a squared. 513 00:39:53,310 --> 00:40:00,580 And so basically, this is the more interesting thing 514 00:40:00,580 --> 00:40:02,220 that we want to calculate. 515 00:40:08,172 --> 00:40:12,080 Also, again, remember I wrote this a squared down here, 516 00:40:12,080 --> 00:40:19,750 also to emphasize that within this expression, 517 00:40:19,750 --> 00:40:22,130 the minimal separation that I'm going 518 00:40:22,130 --> 00:40:26,720 to allow between any pair of charges is off the order of a. 519 00:40:26,720 --> 00:40:33,490 I have integrated out or moved into some continuum description 520 00:40:33,490 --> 00:40:38,055 any configuration in which the topological charges are 521 00:40:38,055 --> 00:40:39,908 less than distance a. 522 00:40:39,908 --> 00:40:40,408 OK? 523 00:40:43,800 --> 00:40:45,998 Yes? 524 00:40:45,998 --> 00:40:48,820 AUDIENCE: Essentially, when we were 525 00:40:48,820 --> 00:40:53,656 during [INAUDIBLE] it was canonical potential, 526 00:40:53,656 --> 00:40:57,002 [INAUDIBLE], canonical ensemble. 527 00:40:57,002 --> 00:41:00,030 And this is more like grand canonical ensemble? 528 00:41:00,030 --> 00:41:00,660 PROFESSOR: Yes. 529 00:41:00,660 --> 00:41:07,225 So, as far as the original two-dimensional xy model 530 00:41:07,225 --> 00:41:11,310 is concerned, I'm calculating a canonical partition function 531 00:41:11,310 --> 00:41:14,820 for this spin or angle degrees of freedom. 532 00:41:14,820 --> 00:41:20,590 And I find that that integration over spin angle 533 00:41:20,590 --> 00:41:23,830 degrees of freedom can be decomposed 534 00:41:23,830 --> 00:41:30,000 into a Gaussian part and a part that as you correctly point out 535 00:41:30,000 --> 00:41:36,670 corresponds to a grand canonical system of charges. 536 00:41:36,670 --> 00:41:38,720 So the number of charges that are 537 00:41:38,720 --> 00:41:41,910 going to appear in the system I have not 538 00:41:41,910 --> 00:41:45,630 specified whether it is determined implicitly 539 00:41:45,630 --> 00:41:49,211 by how strong these parameter was. 540 00:41:49,211 --> 00:41:55,175 AUDIENCE: [INAUDIBLE] of canonical potential? 541 00:41:55,175 --> 00:41:58,080 PROFESSOR: y plays the role of E to the beta mu. 542 00:42:02,700 --> 00:42:05,650 The quantity that in 8333 we were 543 00:42:05,650 --> 00:42:09,750 writing as z-- E to the beta mu small z. 544 00:42:12,743 --> 00:42:13,243 OK? 545 00:42:19,240 --> 00:42:26,990 So, we thought we were solving the xy model. 546 00:42:26,990 --> 00:42:32,090 We ended up, indeed, with this grand canonical system, 547 00:42:32,090 --> 00:42:36,240 which is currently parametrized by two things. 548 00:42:36,240 --> 00:42:43,080 One is this k, which is this strength of the potential. 549 00:42:43,080 --> 00:42:46,260 The other is this y. 550 00:42:46,260 --> 00:42:49,590 Of course, since this system originally 551 00:42:49,590 --> 00:42:54,180 came from an xy model that went only one parameter, 552 00:42:54,180 --> 00:42:59,300 I expect this y to also be related to k. 553 00:42:59,300 --> 00:43:03,350 But just as an expression, we can certainly 554 00:43:03,350 --> 00:43:06,770 regard it as a system that is parametrized 555 00:43:06,770 --> 00:43:10,260 by two things-- the k and the y. 556 00:43:10,260 --> 00:43:12,120 For the case of the xy model, there 557 00:43:12,120 --> 00:43:15,530 will be some additional constraint between the two. 558 00:43:15,530 --> 00:43:19,900 But more generally, we can look at this system with its two 559 00:43:19,900 --> 00:43:21,460 parameters. 560 00:43:21,460 --> 00:43:29,110 And essentially, we will try to make an expansion in y. 561 00:43:29,110 --> 00:43:33,360 You'll say that, OK, presumable, I 562 00:43:33,360 --> 00:43:38,700 know what is going to happen when y is very, very small. 563 00:43:38,700 --> 00:43:47,210 Because then, in the system I will create only a few charges. 564 00:43:47,210 --> 00:43:50,110 If I create many charges, I'm going 565 00:43:50,110 --> 00:43:54,580 to penalize by more and more factors of y. 566 00:43:54,580 --> 00:43:57,420 So maybe through leading order, the system 567 00:43:57,420 --> 00:43:59,570 would be free of charge. 568 00:43:59,570 --> 00:44:01,410 And then, there would be a few pairs 569 00:44:01,410 --> 00:44:03,800 that would appear here and there. 570 00:44:03,800 --> 00:44:06,600 In fact, there should be a small density of them, 571 00:44:06,600 --> 00:44:09,870 even no matter how small I make y. 572 00:44:09,870 --> 00:44:12,170 There will be a very small density 573 00:44:12,170 --> 00:44:14,310 of these things that will appear. 574 00:44:14,310 --> 00:44:18,090 And presumably, these things will always 575 00:44:18,090 --> 00:44:20,490 appear close to each other. 576 00:44:20,490 --> 00:44:26,270 So I will have lots and lots of these pairs-- well, 577 00:44:26,270 --> 00:44:27,960 not lots and lots of these pairs-- 578 00:44:27,960 --> 00:44:33,270 a density of them that is controlled by how big y is. 579 00:44:33,270 --> 00:44:42,470 And as I make y larger-- so this is y becoming larger-- then 580 00:44:42,470 --> 00:44:46,930 presumably, I will generate more and more of these pairs. 581 00:44:46,930 --> 00:44:50,170 And once I have more and more of these pairs, 582 00:44:50,170 --> 00:44:54,480 they could, in principle, get into each other's way. 583 00:44:54,480 --> 00:44:56,530 And when they get into each other's way, 584 00:44:56,530 --> 00:44:59,890 then it's not clear who is paired with whom. 585 00:44:59,890 --> 00:45:06,450 And at some point, I should trade my picture 586 00:45:06,450 --> 00:45:11,240 of having a gas of pairs of these objects 587 00:45:11,240 --> 00:45:14,340 to a plasma of charges, plus and minus, 588 00:45:14,340 --> 00:45:18,380 that are moving all over the place. 589 00:45:18,380 --> 00:45:23,650 So as I tune this parameter y, I expect my system 590 00:45:23,650 --> 00:45:29,840 to go from a low density phase of atoms of plus-minus bound 591 00:45:29,840 --> 00:45:34,470 to each other to a high density phase where 592 00:45:34,470 --> 00:45:36,950 I have a plasma of plus and minuses 593 00:45:36,950 --> 00:45:38,230 moving all over the place. 594 00:45:38,230 --> 00:45:39,030 Yes? 595 00:45:39,030 --> 00:45:41,965 AUDIENCE: So, y is related to the core energy. 596 00:45:41,965 --> 00:45:42,800 PROFESSOR: Yes. 597 00:45:42,800 --> 00:45:46,370 AUDIENCE: And core energy is defined through [INAUDIBLE] 598 00:45:46,370 --> 00:45:49,960 direction at zero separation-- 599 00:45:49,960 --> 00:45:51,890 PROFESSOR: Well, no. 600 00:45:51,890 --> 00:45:54,590 Because the Coulomb description is only 601 00:45:54,590 --> 00:45:57,290 valid large separations. 602 00:45:57,290 --> 00:46:02,550 When I get to short distances, who knows what's going on? 603 00:46:02,550 --> 00:46:07,100 So there is some underlying microscopic picture 604 00:46:07,100 --> 00:46:10,320 that determines what the core energy is. 605 00:46:10,320 --> 00:46:12,800 Very roughly, yes, you would expect 606 00:46:12,800 --> 00:46:16,850 it to have a form that is of e to the minus k 607 00:46:16,850 --> 00:46:19,710 with some coefficient that comes from adding 608 00:46:19,710 --> 00:46:21,040 all of those interactions here. 609 00:46:23,610 --> 00:46:24,718 Yes? 610 00:46:24,718 --> 00:46:26,570 AUDIENCE: Just based on the sign convention, 611 00:46:26,570 --> 00:46:30,199 you're saying if you increase or decrease y, 612 00:46:30,199 --> 00:46:32,011 that it will go from a low density-- 613 00:46:32,011 --> 00:46:36,200 PROFESSOR: OK, so y is the exponential of something. 614 00:46:36,200 --> 00:46:42,010 y equals to zero means I will not create any of these things. 615 00:46:42,010 --> 00:46:45,800 y approaching 1-- I will create a lot of them. 616 00:46:45,800 --> 00:46:48,060 There's no cost at y equals to one. 617 00:46:48,060 --> 00:46:50,360 There's no core energy. 618 00:46:50,360 --> 00:46:52,730 I can create them as I want. 619 00:46:52,730 --> 00:46:56,814 AUDIENCE: So this would be like y equals minus epsilon c. 620 00:46:56,814 --> 00:46:57,730 Is that right? 621 00:46:57,730 --> 00:46:59,610 PROFESSOR: Yeah. 622 00:46:59,610 --> 00:47:00,510 Didn't I have that? 623 00:47:00,510 --> 00:47:03,650 You see in the exponential it is with the minus. 624 00:47:10,290 --> 00:47:10,790 OK. 625 00:47:10,790 --> 00:47:13,190 But in any case, that is the expectation. 626 00:47:13,190 --> 00:47:14,010 Right? 627 00:47:14,010 --> 00:47:17,330 So I expect that when I calculate, 628 00:47:17,330 --> 00:47:19,020 I create one of these defects. 629 00:47:19,020 --> 00:47:23,730 There is an energy cost which is mostly from outside. 630 00:47:23,730 --> 00:47:27,790 And then, there's an additional piece on the inside. 631 00:47:27,790 --> 00:47:30,247 So the exponential of that additional piece 632 00:47:30,247 --> 00:47:31,830 would be a number that is less than 1. 633 00:47:31,830 --> 00:47:32,734 AUDIENCE: [INAUDIBLE] 634 00:47:43,684 --> 00:47:44,350 PROFESSOR: Yeah. 635 00:47:44,350 --> 00:47:48,260 I mean, the original model has some particular form. 636 00:47:48,260 --> 00:47:51,240 And actually, the interactions of the original model, I 637 00:47:51,240 --> 00:47:52,730 can make more complicated. 638 00:47:52,730 --> 00:47:57,030 I can add the full spin interaction, for example. 639 00:47:57,030 --> 00:48:01,480 It doesn't affect the overall form much, 640 00:48:01,480 --> 00:48:05,120 just modifies what an effective k is, 641 00:48:05,120 --> 00:48:08,175 and what the core energy is independent. 642 00:48:11,420 --> 00:48:11,920 OK? 643 00:48:14,500 --> 00:48:15,380 All right. 644 00:48:15,380 --> 00:48:19,850 But the key point is that this system potentially 645 00:48:19,850 --> 00:48:25,520 has a phase transition as you change the parameter of y. 646 00:48:25,520 --> 00:48:29,270 And another way of looking at this transition 647 00:48:29,270 --> 00:48:35,460 is that what is happening here in different languages, 648 00:48:35,460 --> 00:48:38,680 you can either call it insulator or a dielectric. 649 00:48:42,840 --> 00:48:45,830 But what is happening here in different languages, 650 00:48:45,830 --> 00:48:50,780 you can either call, say, a metal or, as I said, 651 00:48:50,780 --> 00:48:51,550 maybe a plasma. 652 00:48:54,616 --> 00:48:59,960 The point is that here you have free charges. 653 00:48:59,960 --> 00:49:03,670 Here you have bound pairs of charges. 654 00:49:03,670 --> 00:49:08,090 And they respond differently to, let's say, 655 00:49:08,090 --> 00:49:10,150 an external electromagnetic field. 656 00:49:10,150 --> 00:49:15,850 So once we have this picture, let's kind of expand our view. 657 00:49:15,850 --> 00:49:18,120 Forget about the xy model. 658 00:49:18,120 --> 00:49:20,490 Think of a system of charges. 659 00:49:20,490 --> 00:49:25,536 And notice that in this low-density phase, 660 00:49:25,536 --> 00:49:29,220 it behaves like a dielectric in the sense 661 00:49:29,220 --> 00:49:32,730 that there are no free charges. 662 00:49:32,730 --> 00:49:37,900 And here, there will be lots of mobile charges. 663 00:49:37,900 --> 00:49:40,650 And it behaves like a metal. 664 00:49:40,650 --> 00:49:42,280 What do I mean by that? 665 00:49:42,280 --> 00:49:45,400 Well, here, if I, let's say, bring 666 00:49:45,400 --> 00:49:48,180 in an external electric field. 667 00:49:48,180 --> 00:49:54,360 Or maybe if I put a huge charge, what is going to happen 668 00:49:54,360 --> 00:50:00,290 is that opposite charges will accumulate. 669 00:50:00,290 --> 00:50:04,880 Or there will be, essentially, opposite charges for the field. 670 00:50:04,880 --> 00:50:08,590 So that once you go inside, the fact 671 00:50:08,590 --> 00:50:13,160 that you have an external electric field or a charge 672 00:50:13,160 --> 00:50:14,880 is completely screen. 673 00:50:14,880 --> 00:50:16,800 You won't see it. 674 00:50:16,800 --> 00:50:19,860 Whereas here, what is going to happen 675 00:50:19,860 --> 00:50:23,380 is that if you put in an electric field, 676 00:50:23,380 --> 00:50:26,170 it will penetrate into the system 677 00:50:26,170 --> 00:50:28,970 although it will be weakened a little bit 678 00:50:28,970 --> 00:50:32,220 by the re-orientation of these charges. 679 00:50:32,220 --> 00:50:38,650 Now, if you put a plus charge, the effect of that plus charge 680 00:50:38,650 --> 00:50:42,170 would be felt throughout, although weakened a little bit. 681 00:50:42,170 --> 00:50:47,790 Because again, some of these dipoles will re-orient in that. 682 00:50:47,790 --> 00:50:49,720 OK? 683 00:50:49,720 --> 00:50:56,380 So, this low-density phase we can actually 684 00:50:56,380 --> 00:51:06,050 try to parametrize in terms of a weakening of the interactions 685 00:51:06,050 --> 00:51:10,800 through a dielectric constant epsilon. 686 00:51:10,800 --> 00:51:13,140 And so, what I'm going to try to calculate 687 00:51:13,140 --> 00:51:18,580 for you is to imagine that I'm in the limit of low density 688 00:51:18,580 --> 00:51:25,640 or small y and calculate what the weakening is, what 689 00:51:25,640 --> 00:51:29,340 the dielectric function is, perturbatively in y. 690 00:51:29,340 --> 00:51:29,840 Yes? 691 00:51:29,840 --> 00:51:33,644 AUDIENCE: If you were talking about the real electric charges 692 00:51:33,644 --> 00:51:36,204 and the way to act on that [INAUDIBLE] 693 00:51:36,204 --> 00:51:38,060 real electric field or charge. 694 00:51:38,060 --> 00:51:42,214 But if we are talking about topological charges, what 695 00:51:42,214 --> 00:51:46,507 would be kind of conjugate force to that? 696 00:51:46,507 --> 00:51:47,480 PROFESSOR: OK. 697 00:51:50,640 --> 00:51:52,280 It's not going to be easy. 698 00:51:52,280 --> 00:51:54,710 I have to do something about say, 699 00:51:54,710 --> 00:51:58,530 re-orienting all of the spins on the boundaries, et cetera. 700 00:51:58,530 --> 00:52:00,550 So let's forget about that. 701 00:52:00,550 --> 00:52:03,780 The point is that mathematically, the problem 702 00:52:03,780 --> 00:52:06,620 is reduced to this system. 703 00:52:06,620 --> 00:52:11,040 And I can much more easily do the mathematics 704 00:52:11,040 --> 00:52:15,950 if I change my perspective and think about this picture. 705 00:52:15,950 --> 00:52:18,100 OK? 706 00:52:18,100 --> 00:52:22,890 And that's the thing you have to do in theoretical physics. 707 00:52:22,890 --> 00:52:25,650 You basically take advantage of mappings 708 00:52:25,650 --> 00:52:29,280 of one model to another model in order 709 00:52:29,280 --> 00:52:35,900 to refine your intuition using some other picture. 710 00:52:35,900 --> 00:52:38,370 So that's what we are going to do. 711 00:52:38,370 --> 00:52:44,820 So completely different picture from the original spin models-- 712 00:52:44,820 --> 00:52:52,330 imagine that you have indeed a box of this material. 713 00:52:52,330 --> 00:52:56,120 And this box of material has, because you're wise, 714 00:52:56,120 --> 00:53:00,130 more some combination of these plus and minus charges in it. 715 00:53:02,650 --> 00:53:07,320 And then, what I do is that I bring externally 716 00:53:07,320 --> 00:53:10,655 a uniform electric field in this direction. 717 00:53:13,870 --> 00:53:19,780 And I expect that once inside the material, 718 00:53:19,780 --> 00:53:24,220 the electric field will be reduced to a smaller value 719 00:53:24,220 --> 00:53:31,240 that I will call E prime because of the dielectric function. 720 00:53:31,240 --> 00:53:34,790 Now, if you ever calculated dielectric functions, 721 00:53:34,790 --> 00:53:37,250 that's exactly what I'm going to do now. 722 00:53:37,250 --> 00:53:38,970 It's a simple process. 723 00:53:38,970 --> 00:53:42,310 What you do, for example, is you do 724 00:53:42,310 --> 00:53:46,390 the analog of Gauss' theorem. 725 00:53:46,390 --> 00:53:53,150 Let's imagine that we draw a circuit such as this 726 00:53:53,150 --> 00:53:59,930 that is partly on the inside, and partly on the outside. 727 00:53:59,930 --> 00:54:06,070 So I can calculate what the flux of the electric field 728 00:54:06,070 --> 00:54:12,070 is through this circuit, the analog of the Gaussian pillbox. 729 00:54:12,070 --> 00:54:14,660 And so, what I have is that what is going on 730 00:54:14,660 --> 00:54:20,140 is E. If I call this distance to be L, 731 00:54:20,140 --> 00:54:26,710 the flux integrated through the entire thing 732 00:54:26,710 --> 00:54:30,872 is E minus E prime times f. 733 00:54:30,872 --> 00:54:35,040 So this is the integral of the divergence of the electric 734 00:54:35,040 --> 00:54:36,880 field . 735 00:54:36,880 --> 00:54:43,140 And by Gauss' theorem, this has to be charge enclosed inside. 736 00:54:49,588 --> 00:54:52,570 OK. 737 00:54:52,570 --> 00:54:55,810 Now, why should there be any charge enclosed 738 00:54:55,810 --> 00:55:01,045 inside when you have a bunch of plus and minuses. 739 00:55:01,045 --> 00:55:02,630 I mean, there will be some pluses 740 00:55:02,630 --> 00:55:05,190 and minuses out here as I have indicated. 741 00:55:05,190 --> 00:55:08,920 There will be some pluses and minuses that are inside. 742 00:55:08,920 --> 00:55:12,510 But the net of these would be zero. 743 00:55:12,510 --> 00:55:17,560 So the only place that you get a net charge 744 00:55:17,560 --> 00:55:20,934 is those dipoles that happen to be sitting right 745 00:55:20,934 --> 00:55:21,600 at the boundary. 746 00:55:26,230 --> 00:55:32,860 And then, I have to count how many of them are inside. 747 00:55:32,860 --> 00:55:35,270 And some of them will have the plus inside. 748 00:55:35,270 --> 00:55:38,550 And some of them will have the minus inside. 749 00:55:38,550 --> 00:55:41,640 And then, I have to calculate the net. 750 00:55:41,640 --> 00:55:50,490 The thing is that my dipoles do not have a fixed size. 751 00:55:50,490 --> 00:55:58,810 The size of these plus/minus molecules r 752 00:55:58,810 --> 00:56:00,890 can be variable itself. 753 00:56:00,890 --> 00:56:02,820 OK? 754 00:56:02,820 --> 00:56:05,670 So there will be some that are tightly bound to each other. 755 00:56:05,670 --> 00:56:10,160 There may be some that are further apart, et cetera. 756 00:56:10,160 --> 00:56:16,530 So let's look at pairs that are at the distance r 757 00:56:16,530 --> 00:56:20,350 and ask how many of them hit this boundary so that one 758 00:56:20,350 --> 00:56:23,990 of them would be inside, one of them will be outside. 759 00:56:23,990 --> 00:56:25,370 OK? 760 00:56:25,370 --> 00:56:30,270 So, that number has to be proportional 761 00:56:30,270 --> 00:56:36,960 to essentially this area. 762 00:56:36,960 --> 00:56:39,100 What is that area? 763 00:56:39,100 --> 00:56:44,730 On one side, it is L. On the other side, it is R. 764 00:56:44,730 --> 00:56:51,310 But if the dipole is oriented at an angle theta, 765 00:56:51,310 --> 00:56:56,250 it is, in fact r cosine theta. 766 00:56:56,250 --> 00:56:56,750 OK? 767 00:56:59,310 --> 00:57:05,320 So that's the number. 768 00:57:05,320 --> 00:57:12,360 Now, what I will have here would be the charge 2 pi. 769 00:57:12,360 --> 00:57:13,170 So this is qi. 770 00:57:19,880 --> 00:57:23,600 Actually, it could be plus or minus. 771 00:57:23,600 --> 00:57:25,750 The reason that there's going to be more 772 00:57:25,750 --> 00:57:31,500 plus as opposed to minus is because the dipole 773 00:57:31,500 --> 00:57:35,880 gets oriented by the electric field. 774 00:57:35,880 --> 00:57:45,090 So I will have a term here that is E to the E prime times q 775 00:57:45,090 --> 00:57:50,660 ir-- so that's 2 pi r. 776 00:57:50,660 --> 00:57:57,280 So this is qr again, times cosine of theta. 777 00:57:57,280 --> 00:58:00,150 So we can see that, depending on cosine of theta 778 00:58:00,150 --> 00:58:04,150 being larger than pi or less than pi, 779 00:58:04,150 --> 00:58:07,440 this number will be positive or negative. 780 00:58:07,440 --> 00:58:11,075 And that's going to be modified by this number also. 781 00:58:11,075 --> 00:58:14,300 And of course, the strength of this whole thing 782 00:58:14,300 --> 00:58:16,870 is set by this parameter k. 783 00:58:21,230 --> 00:58:28,480 And also how likely it is for me to have created 784 00:58:28,480 --> 00:58:36,840 a dipole of size r is controlled by precisely this factor. 785 00:58:36,840 --> 00:58:42,030 A dipole is something that has two cores. 786 00:58:42,030 --> 00:58:45,280 So it is something that will appear at order of y squared. 787 00:58:48,570 --> 00:58:51,050 And there is the energy, according 788 00:58:51,050 --> 00:58:54,810 to this formula, of separating two things. 789 00:58:54,810 --> 00:58:57,675 And so you can see that essentially, n of r-- 790 00:58:57,675 --> 00:59:01,320 maybe I will write it separately over here-- 791 00:59:01,320 --> 00:59:10,600 is y squared times E to the minus 4pi squared k. 792 00:59:10,600 --> 00:59:15,520 And from here, I have log of r divided by a. 793 00:59:15,520 --> 00:59:17,430 And then there's a factor of 2 pi 794 00:59:17,430 --> 00:59:19,610 because the Coulomb potential is this. 795 00:59:22,240 --> 00:59:27,960 So, this is going to be y squared 796 00:59:27,960 --> 00:59:33,430 a over r to the power of 2 pi k. 797 00:59:33,430 --> 00:59:38,720 The further you try to separate these things, the more 798 00:59:38,720 --> 00:59:40,300 cost you have to pay. 799 00:59:46,024 --> 00:59:48,900 OK. 800 00:59:48,900 --> 00:59:52,700 So if you were trying to calculate 801 00:59:52,700 --> 00:59:57,750 the contribution of, say, polarizable atoms 802 00:59:57,750 --> 01:00:02,150 or dipoles to the dielectric function of a solid, 803 01:00:02,150 --> 01:00:06,630 you would be doing exactly this same calculation. 804 01:00:06,630 --> 01:00:13,090 The only difference is that the size of your dipole 805 01:00:13,090 --> 01:00:16,580 would be set by the size of your molecule 806 01:00:16,580 --> 01:00:20,590 and ultimately, related to its polarizability. 807 01:00:20,590 --> 01:00:23,720 And rather than having this Coulomb interaction, 808 01:00:23,720 --> 01:00:26,755 you would have some dissociation energy or something 809 01:00:26,755 --> 01:00:31,800 else, or the density itself would come over here. 810 01:00:31,800 --> 01:00:36,630 So, the only final step is that I 811 01:00:36,630 --> 01:00:43,470 have to regard my system having a composition 812 01:00:43,470 --> 01:00:46,110 of these things of different sizes. 813 01:00:46,110 --> 01:00:52,000 So I have to do an integral over r, as well as orientation. 814 01:00:52,000 --> 01:00:57,060 So I have to do an integral over E theta. 815 01:00:57,060 --> 01:00:58,910 Of course, the integration will go 816 01:00:58,910 --> 01:01:03,678 from a through essentially, the size of the system or infinity. 817 01:01:07,670 --> 01:01:11,760 I forgot one other thing, which is 818 01:01:11,760 --> 01:01:18,240 that when I'm calculating how many places I can put this, 819 01:01:18,240 --> 01:01:21,570 again, I have been calculating things 820 01:01:21,570 --> 01:01:26,020 per unit area of a squared. 821 01:01:26,020 --> 01:01:29,800 So I would have to divide all of these places 822 01:01:29,800 --> 01:01:34,629 where r and L appear by corresponding factors of a. 823 01:01:37,552 --> 01:01:38,052 OK? 824 01:01:42,950 --> 01:01:45,650 So, the last step of the calculation 825 01:01:45,650 --> 01:01:48,145 is you expand this quantity. 826 01:01:48,145 --> 01:01:50,120 It is 1. 827 01:01:50,120 --> 01:01:52,670 For small values of the electric field, 828 01:01:52,670 --> 01:02:01,000 it is 2 pi r E prime cosine of theta k plus higher order 829 01:02:01,000 --> 01:02:03,240 terms. 830 01:02:03,240 --> 01:02:07,160 And then, you can do the various integrations. 831 01:02:07,160 --> 01:02:12,570 First of all, 1 the integration against 1 832 01:02:12,570 --> 01:02:14,960 will disappear because you are integrating 833 01:02:14,960 --> 01:02:18,740 over all values of cosine of theta. 834 01:02:18,740 --> 01:02:21,870 Integral of cosine of theta gives you zero. 835 01:02:21,870 --> 01:02:25,220 Essentially, it says that if there was no electric field, 836 01:02:25,220 --> 01:02:30,400 there was no reason for there to be an additional net charge 837 01:02:30,400 --> 01:02:32,920 on one side or the other. 838 01:02:32,920 --> 01:02:35,780 So the first term that will be non-zero 839 01:02:35,780 --> 01:02:38,930 is the average of cosine theta squared, which 840 01:02:38,930 --> 01:02:41,160 will give you a factor of one-half. 841 01:02:41,160 --> 01:02:50,970 And so, what you will get is that E minus E prime times 842 01:02:50,970 --> 01:03:04,400 L is-- well, there's going to be a factor of L. 843 01:03:04,400 --> 01:03:07,420 The integral of the theta cosine of theta 844 01:03:07,420 --> 01:03:16,340 squared-- the integral of cosine of theta squared 845 01:03:16,340 --> 01:03:20,780 is going to give you 2 pi, which is the integration times 846 01:03:20,780 --> 01:03:21,900 one-half. 847 01:03:21,900 --> 01:03:24,790 So this is the integral the theta cosine 848 01:03:24,790 --> 01:03:28,350 square theta will give you this. 849 01:03:28,350 --> 01:03:31,000 So we did this. 850 01:03:31,000 --> 01:03:33,700 We have two factors of y. 851 01:03:33,700 --> 01:03:36,330 y is our expansion parameter. 852 01:03:36,330 --> 01:03:38,510 We are at a low density limit. 853 01:03:38,510 --> 01:03:42,310 We've calculated things assuming that essentially, I 854 01:03:42,310 --> 01:03:47,050 have to look at one value of these diplodes. 855 01:03:47,050 --> 01:03:50,860 In principal, I can imagine that there will be multiple dipoles. 856 01:03:50,860 --> 01:03:54,560 And you can see that ultimately, therefore, potentially, I 857 01:03:54,560 --> 01:03:59,830 have order of y to the fourth that I haven't calculated. 858 01:03:59,830 --> 01:04:02,325 OK, so we got rid of the y squared. 859 01:04:05,340 --> 01:04:11,230 We have a factor of E prime on the expansion here. 860 01:04:23,550 --> 01:04:27,595 This factor is bothering me a little bit-- let me check. 861 01:04:27,595 --> 01:04:29,796 No, that's correct. 862 01:04:29,796 --> 01:04:31,940 OK, so I have the factor of k. 863 01:04:37,300 --> 01:04:41,010 I have a factor of 2 pi here that came from the charge. 864 01:04:41,010 --> 01:04:44,435 I have another 2 pi here-- so I have 4pi squared. 865 01:04:51,470 --> 01:04:54,900 I think I got everything except the integration 866 01:04:54,900 --> 01:05:04,110 over a to infinity dr. There is this r dr, which 867 01:05:04,110 --> 01:05:07,650 is from the two dimensional integration. 868 01:05:07,650 --> 01:05:11,495 There was another r here, and another r here. 869 01:05:11,495 --> 01:05:15,360 So this becomes r to the three. 870 01:05:15,360 --> 01:05:18,400 From here, I have minus 2 pi k. 871 01:05:20,930 --> 01:05:23,650 And then, I have the corresponding factors 872 01:05:23,650 --> 01:05:27,230 of a to the power of 2 pi k minus 4. 873 01:05:34,200 --> 01:05:34,700 OK. 874 01:05:37,690 --> 01:05:44,690 So you can see that the L's cancel. 875 01:05:44,690 --> 01:05:52,750 And what I get is that E-- once I 876 01:05:52,750 --> 01:05:56,210 take the E prime to the other side-- 877 01:05:56,210 --> 01:06:10,010 becomes E prime 1 plus I have 4pi cubed k y squared-- again, 878 01:06:10,010 --> 01:06:16,290 y squared is my small expansion parameter. 879 01:06:16,290 --> 01:06:22,460 And then, I have the integral from a to infinity, the r, r 880 01:06:22,460 --> 01:06:26,140 to the power of 3 minus 2 pi k, a 881 01:06:26,140 --> 01:06:33,050 to the power of 2 pi k minus 4, and then order of y squared, 882 01:06:33,050 --> 01:06:34,366 y to the fourth. 883 01:06:37,852 --> 01:06:40,840 OK. 884 01:06:40,840 --> 01:06:51,450 So basically, you see that the internal electric field 885 01:06:51,450 --> 01:06:57,700 is smaller than the external electric field 886 01:06:57,700 --> 01:07:03,610 by this factor, which takes into account the re-orientation 887 01:07:03,610 --> 01:07:08,080 of the dipoles in order to screen the electric field. 888 01:07:08,080 --> 01:07:10,210 And it is proportional in some sense 889 01:07:10,210 --> 01:07:15,000 to the density of these dipoles. 890 01:07:15,000 --> 01:07:18,610 And the twist is that the dipoles that we have 891 01:07:18,610 --> 01:07:21,850 can have a range of sizes that we 892 01:07:21,850 --> 01:07:24,940 have to integrate [INAUDIBLE]. 893 01:07:24,940 --> 01:07:31,170 So typically, you would write E prime to the E over epsilon. 894 01:07:31,170 --> 01:07:36,580 And so this is the inverse of your epsilon. 895 01:07:36,580 --> 01:07:45,500 And essentially, this is a reduction in everything 896 01:07:45,500 --> 01:07:49,110 that has to do with electric interactions because 897 01:07:49,110 --> 01:07:53,280 of the screening of other things. 898 01:07:53,280 --> 01:07:56,120 I can write it in the following fashion. 899 01:07:56,120 --> 01:08:02,150 I can say that there is an effective k-- that's 900 01:08:02,150 --> 01:08:08,870 called k effective-- which is different from the original k 901 01:08:08,870 --> 01:08:11,950 that I have. 902 01:08:11,950 --> 01:08:14,250 It is reduced by a factor of epsilon. 903 01:08:16,760 --> 01:08:23,960 So we were worried when we were doing the nonlinear sigma 904 01:08:23,960 --> 01:08:26,090 model that for any [INAUDIBLE], we 905 01:08:26,090 --> 01:08:31,689 saw that the parameter k was not getting modified because 906 01:08:31,689 --> 01:08:37,090 of the interactions among the spin modes, and that's correct. 907 01:08:37,090 --> 01:08:39,080 But really, at high temperatures, 908 01:08:39,080 --> 01:08:40,460 it should disappear. 909 01:08:40,460 --> 01:08:42,870 We saw that the correlations had to go away 910 01:08:42,870 --> 01:08:47,029 from power law form to exponential form. 911 01:08:47,029 --> 01:08:50,220 And so, we needed some mechanism for reducing 912 01:08:50,220 --> 01:08:52,399 the coupling constant. 913 01:08:52,399 --> 01:08:57,140 And what we find here is that this topological defects 914 01:08:57,140 --> 01:09:00,910 and their screening provide the right mechanism. 915 01:09:00,910 --> 01:09:03,540 So the effective k that I have is 916 01:09:03,540 --> 01:09:06,660 going to be reduced from the original k 917 01:09:06,660 --> 01:09:08,080 by the inverse of this. 918 01:09:08,080 --> 01:09:10,240 Since I'm doing an expansion in y, 919 01:09:10,240 --> 01:09:14,704 it is simply minus 4pi cubed ky squared, 920 01:09:14,704 --> 01:09:20,870 integral a to infinity dr, r to the 3 minus 2 pi k, 921 01:09:20,870 --> 01:09:28,210 a to the 2 pi k minus 4, plus order or y to the fourteenth. 922 01:09:28,210 --> 01:09:28,710 OK. 923 01:09:31,920 --> 01:09:36,550 Now actually, in the lecture notes that I have given you, 924 01:09:36,550 --> 01:09:42,210 I calculate this formula in an entirely different way. 925 01:09:42,210 --> 01:09:49,080 What I do is I assume that I have two topological defects-- 926 01:09:49,080 --> 01:09:53,689 so there I sort of maintain the picture of topological defect. 927 01:09:53,689 --> 01:09:58,290 And their interaction between them 928 01:09:58,290 --> 01:10:03,440 is this logarithmic interaction that has coefficient k. 929 01:10:03,440 --> 01:10:06,050 But then, we say that this [INAUDIBLE] interaction 930 01:10:06,050 --> 01:10:13,640 is modified because I can create pairs of topological defect, 931 01:10:13,640 --> 01:10:15,860 such as this, that will partially 932 01:10:15,860 --> 01:10:19,060 screen the interaction. 933 01:10:19,060 --> 01:10:22,120 And in the notes, we calculate what 934 01:10:22,120 --> 01:10:25,610 the effect of those pairs at lowest order 935 01:10:25,610 --> 01:10:29,970 is on their interaction that you have between them. 936 01:10:29,970 --> 01:10:32,860 And you find that the effect is to modify 937 01:10:32,860 --> 01:10:35,370 the coefficient of the logarithm, which 938 01:10:35,370 --> 01:10:38,670 is k, to a reduced k. 939 01:10:38,670 --> 01:10:42,230 And that reduced k is given exactly by this form. 940 01:10:42,230 --> 01:10:44,771 So the same thing you can get different ways. 941 01:10:44,771 --> 01:10:45,270 Yes? 942 01:10:45,270 --> 01:10:47,635 AUDIENCE: What if k is too small-- 943 01:10:47,635 --> 01:10:48,910 PROFESSOR: A-ha. 944 01:10:48,910 --> 01:10:50,280 Good. 945 01:10:50,280 --> 01:10:55,410 Because I framed the entire thing as if I'm 946 01:10:55,410 --> 01:10:58,364 doing a preservation theory for you 947 01:10:58,364 --> 01:11:02,140 in y being a small parameter. 948 01:11:02,140 --> 01:11:03,850 OK? 949 01:11:03,850 --> 01:11:07,720 But now, we see that no matter how 950 01:11:07,720 --> 01:11:20,510 small y is, if k is in fact less than 2 over pi-- 951 01:11:20,510 --> 01:11:24,890 so this has dimensions of r to the 4 minus 2 pi k. 952 01:11:24,890 --> 01:11:32,240 So if k is less than 2 over pi-- which incidentally is something 953 01:11:32,240 --> 01:11:41,920 that we saw earlier-- if k is less than that, 954 01:11:41,920 --> 01:11:43,940 this integral diverges. 955 01:11:46,750 --> 01:11:53,310 So I thought I was controlling my expansion 956 01:11:53,310 --> 01:11:58,950 by making y arbitrarily small, but what 957 01:11:58,950 --> 01:12:04,990 we see is that no matter how small I make y, 958 01:12:04,990 --> 01:12:09,440 if k becomes too small, the perturbation acuity 959 01:12:09,440 --> 01:12:12,600 blows up on me. 960 01:12:12,600 --> 01:12:16,990 So this is yet another example of a singular perturbation 961 01:12:16,990 --> 01:12:20,810 theory, which is what we had encountered when we were 962 01:12:20,810 --> 01:12:23,310 doing the Landau-Ginzburg model. 963 01:12:23,310 --> 01:12:27,070 We thought that our co-efficient of phi to the fourth u 964 01:12:27,070 --> 01:12:29,020 was a small parameter. 965 01:12:29,020 --> 01:12:32,810 You are making an expansion naively in powers of u. 966 01:12:32,810 --> 01:12:35,380 And then we found an expression in which 967 01:12:35,380 --> 01:12:38,230 the coeffecient-- the thing that was multiplying u 968 01:12:38,230 --> 01:12:41,240 at the critical point was blowing up on us. 969 01:12:41,240 --> 01:12:44,490 And so the perturbation theory inherently 970 01:12:44,490 --> 01:12:47,210 became singular, despite your thinking 971 01:12:47,210 --> 01:12:50,840 that you had a small parameter. 972 01:12:50,840 --> 01:12:55,200 So we are going to use the same trick 973 01:12:55,200 --> 01:13:04,300 that we used for the case of the Landau-Ginzburg model-- 974 01:13:04,300 --> 01:13:15,350 this is deal with singular perturbations 975 01:13:15,350 --> 01:13:18,080 by renormalization group. 976 01:13:22,020 --> 01:13:28,110 So what we see is that the origin of the problem 977 01:13:28,110 --> 01:13:31,520 is the divergence that we get over here when 978 01:13:31,520 --> 01:13:34,670 we try to integrate all the way to infinity 979 01:13:34,670 --> 01:13:37,880 or the size of the system. 980 01:13:37,880 --> 01:13:43,460 So what we do instead is we said, OK, let's not 981 01:13:43,460 --> 01:13:45,890 integrate all the way. 982 01:13:45,890 --> 01:13:51,400 Let's replace the short distance cut-off 983 01:13:51,400 --> 01:13:58,270 that we had with something that is larger-- ba-- 984 01:13:58,270 --> 01:14:03,470 and rather than integrating all of a to infinity, we integrate 985 01:14:03,470 --> 01:14:10,450 only over short distance fluctuations between a and ba. 986 01:14:10,450 --> 01:14:14,450 This is our usual [INAUDIBLE]. 987 01:14:14,450 --> 01:14:19,790 So what we therefore get is that the k effective is 988 01:14:19,790 --> 01:14:25,580 k 1 minus 4pi q ky squared integral 989 01:14:25,580 --> 01:14:37,530 from a to ba br r to the 3 minus 2 pi k a to the 2 pi k minus 4. 990 01:14:37,530 --> 01:14:42,820 And then, I have to still deal with 4pi cubed ky 991 01:14:42,820 --> 01:14:46,660 squared, integral from ba infinity dr 992 01:14:46,660 --> 01:14:53,840 r to the 3 minus 2 pi k, a to the 2 pi k minus 4, 993 01:14:53,840 --> 01:14:57,770 plus order of y to the fourth. 994 01:14:57,770 --> 01:15:00,728 OK? 995 01:15:00,728 --> 01:15:01,228 All right. 996 01:15:04,690 --> 01:15:14,990 So, you can see that the effect of integrating this much 997 01:15:14,990 --> 01:15:22,500 is to modify the decoupling to a new value which 998 01:15:22,500 --> 01:15:29,450 depends on b, which is just k minus 4pi cubed k squared 999 01:15:29,450 --> 01:15:37,730 y squared, a to ba br r to the 3 minus 2 pi k. 1000 01:15:37,730 --> 01:15:42,471 a to the 2 pi k minus 4. 1001 01:15:42,471 --> 01:15:42,971 OK? 1002 01:15:46,430 --> 01:15:52,060 And then, I can rewrite the expression for k 1003 01:15:52,060 --> 01:16:00,130 effective to be this k tilde. 1004 01:16:00,130 --> 01:16:07,530 And then, whatever is left, which is 4pi cubed k 1005 01:16:07,530 --> 01:16:14,220 squared y squared integral ba to infinity dr 1006 01:16:14,220 --> 01:16:24,647 r to the 3 minus 2 pi k, a to the 2 pi k minus 4, order of y 1007 01:16:24,647 --> 01:16:25,230 to the fourth. 1008 01:16:29,530 --> 01:16:35,480 You see that k has been shifted through this transformation 1009 01:16:35,480 --> 01:16:39,700 by an amount that is order of y squared. 1010 01:16:39,700 --> 01:16:45,320 So at order of y squared in this new expression, 1011 01:16:45,320 --> 01:16:53,470 I can replace all the k's that are carrying with k tilde 1012 01:16:53,470 --> 01:16:56,625 and it would still be correct for this order. 1013 01:16:59,950 --> 01:17:05,320 Now I compare this expression and the original expression 1014 01:17:05,320 --> 01:17:07,750 that I had. 1015 01:17:07,750 --> 01:17:12,510 And I see that they are pretty much the same expression, 1016 01:17:12,510 --> 01:17:19,120 except that in this one, the cut-off is ba. 1017 01:17:19,120 --> 01:17:21,290 So I do step two of origin. 1018 01:17:21,290 --> 01:17:32,480 I define my R prime to be dr so that my new cut-off will 1019 01:17:32,480 --> 01:17:35,300 be back to a. 1020 01:17:35,300 --> 01:17:38,270 So then, this whole thing becomes 1021 01:17:38,270 --> 01:17:45,850 k effective is k tilde minus 4pi cubed k 1022 01:17:45,850 --> 01:17:49,740 tilde squared y squared. 1023 01:17:49,740 --> 01:17:53,430 Because of the transformation that I did over here, 1024 01:17:53,430 --> 01:17:59,760 I will get a factor of b to the 4 minus 2 pi k tilde, 1025 01:17:59,760 --> 01:18:05,040 integral from a' to infinity-- the r prime-- r prime to the 3 1026 01:18:05,040 --> 01:18:11,950 minus 2 pi k tilde, a to the 2 pi k tilde, minus 4 1027 01:18:11,950 --> 01:18:13,629 plus order of y to the fourteenth. 1028 01:18:20,120 --> 01:18:27,820 So we see that the same effective interaction 1029 01:18:27,820 --> 01:18:32,810 can be obtained from two theories that 1030 01:18:32,810 --> 01:18:39,780 have exactly the same cut-off, a, except that in one case, 1031 01:18:39,780 --> 01:18:42,100 I had k and y. 1032 01:18:42,100 --> 01:18:47,082 In the new case, I have this tilde or k prime at scale b. 1033 01:18:47,082 --> 01:18:49,390 And I have to replace where I had 1034 01:18:49,390 --> 01:18:53,920 y with y with this additional factor. 1035 01:18:53,920 --> 01:18:58,370 So the two theories are equivalent provided 1036 01:18:58,370 --> 01:19:03,430 that I say that the new interaction at scale b 1037 01:19:03,430 --> 01:19:11,440 is the old interaction minus 4pi cubed k squared y squared. 1038 01:19:11,440 --> 01:19:14,570 This integral is easy to perform. 1039 01:19:14,570 --> 01:19:16,000 It is just the power law. 1040 01:19:16,000 --> 01:19:21,190 It is b to the fourth minus 2 pi k minus 1. 1041 01:19:21,190 --> 01:19:28,820 And then, I have 4 minus 2 pi k order of y to the fourth. 1042 01:19:28,820 --> 01:19:33,910 And my y prime is y-- from here I 1043 01:19:33,910 --> 01:19:38,116 see b to the power of 2 minus pi k. 1044 01:19:43,462 --> 01:19:44,434 AUDIENCE: [INAUDIBLE] 1045 01:19:48,322 --> 01:19:50,090 PROFESSOR: This k squared? 1046 01:19:50,090 --> 01:19:51,550 AUDIENCE: Oh, I see. 1047 01:19:51,550 --> 01:19:52,050 Sorry. 1048 01:19:58,525 --> 01:19:59,400 PROFESSOR: All right. 1049 01:20:03,820 --> 01:20:13,200 So, our theory is described in terms of two parameters-- 1050 01:20:13,200 --> 01:20:17,780 this y and this k. 1051 01:20:17,780 --> 01:20:22,970 or let's say, it's inverse-- k inverse, 1052 01:20:22,970 --> 01:20:25,910 which is more like temperature. 1053 01:20:25,910 --> 01:20:29,100 And what we will show next time is 1054 01:20:29,100 --> 01:20:34,950 that these recursion relations, when I draw it here, 1055 01:20:34,950 --> 01:20:38,170 will give me two types of behavior. 1056 01:20:38,170 --> 01:20:41,470 One set of behavior that parameterizes 1057 01:20:41,470 --> 01:20:47,700 the low temperature dilute limit that corresponds 1058 01:20:47,700 --> 01:20:51,890 to flows in which y goes through zero. 1059 01:20:51,890 --> 01:20:55,400 So that when you look at the system at larger and larger 1060 01:20:55,400 --> 01:20:59,830 lens scales, essentially it becomes less and less depleted 1061 01:20:59,830 --> 01:21:04,030 of these excitations. 1062 01:21:04,030 --> 01:21:07,030 So, once you have integrated the very essentially, 1063 01:21:07,030 --> 01:21:09,960 you don't see any excitations. 1064 01:21:09,960 --> 01:21:12,210 And then there's another phase, which 1065 01:21:12,210 --> 01:21:18,810 as you do this removal of short distance fluctuations. 1066 01:21:18,810 --> 01:21:22,550 You tend to flow to high temperatures 1067 01:21:22,550 --> 01:21:24,690 and large densities. 1068 01:21:24,690 --> 01:21:29,451 And so, that corresponds to this kind of face. 1069 01:21:29,451 --> 01:21:33,150 Now the beauty of this whole thing 1070 01:21:33,150 --> 01:21:38,600 is that these recursion relations are exact and allow 1071 01:21:38,600 --> 01:21:43,650 us to exactly determine the behavior of these space 1072 01:21:43,650 --> 01:21:46,140 transition in two dimensions. 1073 01:21:46,140 --> 01:21:49,830 And that's actually one of the other triumphs 1074 01:21:49,830 --> 01:21:54,040 of renormalization group is to elucidate 1075 01:21:54,040 --> 01:21:56,950 exactly the critical behavior of this transition, 1076 01:21:56,950 --> 01:22:00,000 as we will discuss next time.