1 00:00:07,850 --> 00:00:12,310 PROFESSOR: To mention, most everyone did 2 00:00:12,310 --> 00:00:13,830 extremely well on the quiz. 3 00:00:13,830 --> 00:00:19,280 But I sense that there's still some of you who have not yet 4 00:00:19,280 --> 00:00:24,160 come to terms with crystallographic directions 5 00:00:24,160 --> 00:00:29,090 and planes, and you feel a little bit awkward in 6 00:00:29,090 --> 00:00:33,330 distinguishing brackets around the HKL and 7 00:00:33,330 --> 00:00:35,650 parentheses around HKL. 8 00:00:35,650 --> 00:00:38,710 And there are some people who generally get that 9 00:00:38,710 --> 00:00:43,040 straightened out, but when I said point group, suddenly 10 00:00:43,040 --> 00:00:49,070 pictures of lattices with fourfold axes and twofold axes 11 00:00:49,070 --> 00:00:51,730 adorning them came in, and that isn't involved in a point 12 00:00:51,730 --> 00:00:52,790 group at also. 13 00:00:52,790 --> 00:00:55,640 Again, a point group the symmetry about point. 14 00:00:55,640 --> 00:00:59,340 A space group is symmetry spread out through all of 15 00:00:59,340 --> 00:01:01,210 space and infinite numbers. 16 00:01:01,210 --> 00:01:03,820 So let me say a little bit about resources. 17 00:01:03,820 --> 00:01:06,050 I don't know whether you've been following what we've been 18 00:01:06,050 --> 00:01:09,710 doing in the notes from Buerger's book 19 00:01:09,710 --> 00:01:11,030 that I passed out. 20 00:01:11,030 --> 00:01:13,610 That was hard to do is because we did the plane groups, and 21 00:01:13,610 --> 00:01:15,480 he doesn't touch them at all. 22 00:01:15,480 --> 00:01:19,560 So now we're back following once again Buerger's treatment 23 00:01:19,560 --> 00:01:20,540 quite closely. 24 00:01:20,540 --> 00:01:21,720 So read the book. 25 00:01:21,720 --> 00:01:24,250 And if you like, I can tell you with the end of each 26 00:01:24,250 --> 00:01:31,060 lecture, this stuff is on pages 57 through 62. 27 00:01:31,060 --> 00:01:31,955 The other thing. 28 00:01:31,955 --> 00:01:38,060 As you'll notice, this nonintrusive gentleman in the 29 00:01:38,060 --> 00:01:41,540 back is making videotapes of all the lectures. 30 00:01:41,540 --> 00:01:43,770 These are eventually going to go up on the website as 31 00:01:43,770 --> 00:01:45,830 OpenCourseWare. 32 00:01:45,830 --> 00:01:48,090 We were just speaking about that, and it takes a while 33 00:01:48,090 --> 00:01:51,140 before they get up, but I have a disk of every lecture. 34 00:01:51,140 --> 00:01:54,040 So if there's something you didn't follow or a place where 35 00:01:54,040 --> 00:01:57,020 I chewed my lines and you want to go back over it again-- not 36 00:01:57,020 --> 00:01:58,990 that that happens very often-- 37 00:01:58,990 --> 00:02:02,110 you are more than welcome to ask me to borrow and borrow 38 00:02:02,110 --> 00:02:03,790 the disk if you want to review it. 39 00:02:03,790 --> 00:02:05,530 So that's another resource. 40 00:02:05,530 --> 00:02:09,660 And then I will regularly throughout the term give 41 00:02:09,660 --> 00:02:13,270 hard-copy handouts of some of the things that we're doing, 42 00:02:13,270 --> 00:02:15,500 particularly when it involves geometry. 43 00:02:15,500 --> 00:02:17,760 And when we move on to three-dimensional geometry, 44 00:02:17,760 --> 00:02:21,070 unless of the graphics is really tight and precise, it's 45 00:02:21,070 --> 00:02:23,080 hard to follow what's going on. 46 00:02:23,080 --> 00:02:26,600 So in that vein, one of the first things I wanted to pass 47 00:02:26,600 --> 00:02:28,850 out-- the only other one for today-- 48 00:02:28,850 --> 00:02:35,310 is a demonstration that in fact in the Group 23 all you 49 00:02:35,310 --> 00:02:40,120 need is a single twofold axis oriented along the normal to a 50 00:02:40,120 --> 00:02:44,150 face and a single threefold axis coming 51 00:02:44,150 --> 00:02:46,450 out of one body diagonal. 52 00:02:46,450 --> 00:02:48,550 And that gives you all of the axes you are 53 00:02:48,550 --> 00:02:51,210 going to get into 23. 54 00:02:51,210 --> 00:02:55,230 So when this comes around, there are number of steps that 55 00:02:55,230 --> 00:02:59,130 you can perform letting the axes work on each other. 56 00:02:59,130 --> 00:03:02,400 And if you start with just the single twofold axis and the 57 00:03:02,400 --> 00:03:05,780 single threefold axis-- which the symbol suggests is all you 58 00:03:05,780 --> 00:03:09,010 need, there's only one kind of each-- 59 00:03:09,010 --> 00:03:12,770 if you look at a cube along its body diagonal, the twofold 60 00:03:12,770 --> 00:03:16,090 axis that's coming out of one face gets rotated into 61 00:03:16,090 --> 00:03:18,980 directions normal to all the other faces if you rotate by 62 00:03:18,980 --> 00:03:20,780 120 degrees. 63 00:03:20,780 --> 00:03:23,220 So the little diagram in the upper right hand corner of the 64 00:03:23,220 --> 00:03:26,000 sheet hopefully convinces you of this. 65 00:03:26,000 --> 00:03:30,700 Now we've got three mutually orthogonal twofold axes and 66 00:03:30,700 --> 00:03:34,150 one threefold axis coming out of a body diagonal. 67 00:03:34,150 --> 00:03:37,960 So the vertical twofold axis swings that around by 180 68 00:03:37,960 --> 00:03:41,120 degrees to give you another threefold axis 69 00:03:41,120 --> 00:03:42,870 along a body diagonal. 70 00:03:42,870 --> 00:03:45,060 And I labeled that one 3 prime in the 71 00:03:45,060 --> 00:03:48,480 middle diagram at right. 72 00:03:48,480 --> 00:03:56,110 And then if you take the axis 3 prime and repeat it by the 73 00:03:56,110 --> 00:03:59,930 second of the twofold axes that we have along face 74 00:03:59,930 --> 00:04:03,480 normals, that in the middle diagram on the right hand edge 75 00:04:03,480 --> 00:04:07,660 takes 3 prime and repeats it to 3 double prime. 76 00:04:07,660 --> 00:04:10,320 Then finally, the third twofold axis that we generated 77 00:04:10,320 --> 00:04:16,880 repeats the threefold prime axis to the remaining 78 00:04:16,880 --> 00:04:21,170 threefold axis along the fourth body diagonal. 79 00:04:21,170 --> 00:04:24,550 So the results start with one twofold axis oriented along 80 00:04:24,550 --> 00:04:30,280 the normal to a cube and one threefold axis along the 81 00:04:30,280 --> 00:04:34,280 diagonal of the cube, you get axes coming out of all faces 82 00:04:34,280 --> 00:04:36,370 and all diagonal. 83 00:04:36,370 --> 00:04:40,390 And there's a staple on that sheet for reasons that I don't 84 00:04:40,390 --> 00:04:43,470 understand, but it there was, probably on the surface of the 85 00:04:43,470 --> 00:04:45,734 Xerox machine when I went over there. 86 00:04:49,240 --> 00:04:58,160 So let me now return to our next step, and that is to add 87 00:04:58,160 --> 00:05:02,330 what in the language of group theory is called an extender, 88 00:05:02,330 --> 00:05:07,400 a new symmetry operation that can be added to a preexisting 89 00:05:07,400 --> 00:05:10,890 group that will generate new operations. 90 00:05:10,890 --> 00:05:14,630 And let's see what sort of theorems we need to describe 91 00:05:14,630 --> 00:05:20,120 what we should look for and in which particular orientation. 92 00:05:20,120 --> 00:05:24,380 We've got these 11 axial combinations, and these are 93 00:05:24,380 --> 00:05:27,270 frameworks that we can hang mirror planes on. 94 00:05:27,270 --> 00:05:30,700 So let's look at a first simple combination. 95 00:05:30,700 --> 00:05:35,490 Suppose we have a twofold axis, and the only nontrivial 96 00:05:35,490 --> 00:05:39,630 operation there is a rotation through 180 degrees. 97 00:05:39,630 --> 00:05:42,430 So this an axis A pi. 98 00:05:42,430 --> 00:05:47,600 And again, the ground rules are that if we're to add a 99 00:05:47,600 --> 00:05:51,490 mirror plane to this axis, which along with identity 100 00:05:51,490 --> 00:05:55,730 constitutes a group, we can't create any new axes. 101 00:05:55,730 --> 00:05:57,750 So there are two ways we can do this. 102 00:05:57,750 --> 00:06:03,380 One is the three-dimensional analog of something that we 103 00:06:03,380 --> 00:06:06,930 have already done, namely to pass a mirror plane through 104 00:06:06,930 --> 00:06:08,450 the twofold axis. 105 00:06:08,450 --> 00:06:11,560 And this is the group that we found as a two-dimensional 106 00:06:11,560 --> 00:06:14,980 Point Group, and we called it 2mm. 107 00:06:14,980 --> 00:06:18,310 And to do that, we used the theorem that says that if you 108 00:06:18,310 --> 00:06:22,390 take a rotation operation A alpha and combine it with a 109 00:06:22,390 --> 00:06:26,950 reflection operation that goes through it, you get a new 110 00:06:26,950 --> 00:06:31,410 reflection plane, sigma prime, that's at an angle alpha over 111 00:06:31,410 --> 00:06:33,040 2 to the first. 112 00:06:33,040 --> 00:06:37,940 So what gave us the second mirror line in two dimensions, 113 00:06:37,940 --> 00:06:41,220 in three dimensions that would give us another mirror plane 114 00:06:41,220 --> 00:06:43,890 that's at right angles to the first. 115 00:06:43,890 --> 00:06:46,540 And this will give us a three-dimensional symmetry, 116 00:06:46,540 --> 00:06:48,770 which is also called 2mm. 117 00:06:48,770 --> 00:06:51,290 So it's nothing more than taking the two- dimensional 118 00:06:51,290 --> 00:06:54,730 Point Group and letting it come out at the board at you-- 119 00:06:54,730 --> 00:06:56,570 Man, that'll give you nightmares when these things 120 00:06:56,570 --> 00:06:59,260 are coming out of the paper at you-- 121 00:06:59,260 --> 00:07:01,240 and that is a valid group 2mm. 122 00:07:04,060 --> 00:07:07,530 There's another way that we can add a mirror plane to a 123 00:07:07,530 --> 00:07:12,510 rotation axis though which will not create any new axes, 124 00:07:12,510 --> 00:07:16,730 and that's to add the mirror plane-- the reflection 125 00:07:16,730 --> 00:07:20,130 operation sigma I should say since it is a combinations of 126 00:07:20,130 --> 00:07:21,500 operations-- 127 00:07:21,500 --> 00:07:25,240 exactly perpendicular to the locus of 128 00:07:25,240 --> 00:07:27,370 the rotation operation. 129 00:07:27,370 --> 00:07:30,690 And that reflection operation sigma then just flips the 130 00:07:30,690 --> 00:07:33,370 rotation axis end to end. 131 00:07:33,370 --> 00:07:37,680 And the rotation operation just swirls the locus of the 132 00:07:37,680 --> 00:07:40,860 reflection plane around within its own locus and doesn't 133 00:07:40,860 --> 00:07:44,020 create any new reflection plane. 134 00:07:44,020 --> 00:07:48,350 So in the particular combination A pi, if we add a 135 00:07:48,350 --> 00:07:53,260 mirror plane perpendicular to that as the operation sigma, 136 00:07:53,260 --> 00:07:58,170 this would be then all of the operations of a twofold axis 137 00:07:58,170 --> 00:08:02,320 over all of the operations of a mirror plane. 138 00:08:02,320 --> 00:08:05,030 So we've got now a combination of a twofold axis with a 139 00:08:05,030 --> 00:08:07,640 mirror plane. 140 00:08:07,640 --> 00:08:10,960 We've got the same thing here. 141 00:08:10,960 --> 00:08:17,420 To distinguish these two combinations, we'll write this 142 00:08:17,420 --> 00:08:19,650 as a fraction 2/m. 143 00:08:19,650 --> 00:08:22,780 And that literally in words is the way we've added the 144 00:08:22,780 --> 00:08:23,660 twofold axis. 145 00:08:23,660 --> 00:08:27,760 It is sitting over the mirror plane and gets reflected down 146 00:08:27,760 --> 00:08:31,120 into its other end when the mirror plane act on. 147 00:08:31,120 --> 00:08:32,590 So it's just language. 148 00:08:32,590 --> 00:08:35,659 It's nice though, as we said some weeks ago, if our 149 00:08:35,659 --> 00:08:39,820 language have some descriptive content to so when we look at 150 00:08:39,820 --> 00:08:42,169 it we can remind ourselves of what it means. 151 00:08:42,169 --> 00:08:45,560 So two 2mm means the mirror planes are parallel to the 152 00:08:45,560 --> 00:08:46,960 axis that contain it. 153 00:08:46,960 --> 00:08:52,830 2/m means the twofold axis is over the mirror plane. 154 00:08:52,830 --> 00:08:54,320 It goes through and pierces it. 155 00:08:57,130 --> 00:08:59,900 What I would like to ask though is have 156 00:08:59,900 --> 00:09:02,770 we got a group yet? 157 00:09:02,770 --> 00:09:05,070 And let's take a first object-- 158 00:09:05,070 --> 00:09:06,880 let's call it right handed-- 159 00:09:06,880 --> 00:09:09,670 rotate it by 180 degrees. 160 00:09:09,670 --> 00:09:12,780 You get a second one, which will stay right handed. 161 00:09:12,780 --> 00:09:17,370 And then repeat it by a reflection operation in the 162 00:09:17,370 --> 00:09:22,500 mirror plane, and we'll get a third operation. 163 00:09:22,500 --> 00:09:24,840 Reflection changes chirality, so the 164 00:09:24,840 --> 00:09:26,270 third one is left handed. 165 00:09:29,450 --> 00:09:34,170 So we are performing the sequence of operations A pi 166 00:09:34,170 --> 00:09:36,010 followed by sigma. 167 00:09:36,010 --> 00:09:38,810 And let me append just so we make no mistake and not 168 00:09:38,810 --> 00:09:42,370 confuse it with 2mm that the reflection operation is normal 169 00:09:42,370 --> 00:09:45,060 to the mirror plane. 170 00:09:45,060 --> 00:09:48,565 So question, what is the net effect? 171 00:09:52,090 --> 00:09:55,980 And lo and behold, we have stumbled over-- if we had not 172 00:09:55,980 --> 00:09:59,240 been clever enough to invented it and suggested it early on-- 173 00:09:59,240 --> 00:10:05,810 the only way you can get from 1 to 3 in one shot is to turn 174 00:10:05,810 --> 00:10:12,330 it inside out and change its chirality by projecting it 175 00:10:12,330 --> 00:10:16,680 through a point which is the location where the twofold 176 00:10:16,680 --> 00:10:20,780 rotation pierces the mirror plane. 177 00:10:20,780 --> 00:10:24,560 And what this is going to do is to change the sense of all 178 00:10:24,560 --> 00:10:25,630 three coordinates. 179 00:10:25,630 --> 00:10:29,540 This is going to take the coordinates XYZ of object 180 00:10:29,540 --> 00:10:35,330 number 1 and change them into minus x, minus y, minus c. 181 00:10:35,330 --> 00:10:38,330 And what we're doing is inverting the motif, turning 182 00:10:38,330 --> 00:10:43,450 it inside out as it were, into an enantiomorph. 183 00:10:43,450 --> 00:10:47,900 And we have discovered as soon as we combine a pi with a 184 00:10:47,900 --> 00:10:51,650 perpendicular reflection plane, a new operation which 185 00:10:51,650 --> 00:10:53,265 we'll call in words inversion. 186 00:10:56,140 --> 00:11:02,340 And the symbol that used to describe this is a one with a 187 00:11:02,340 --> 00:11:05,430 bar over it, and we'll see why later on. 188 00:11:05,430 --> 00:11:08,820 But this is a onefold axis with an inversion center 189 00:11:08,820 --> 00:11:10,980 sitting on it, and that's what an inversion 190 00:11:10,980 --> 00:11:13,450 center by itself is. 191 00:11:13,450 --> 00:11:16,370 The implication is that they're going to be other axes 192 00:11:16,370 --> 00:11:21,620 that we can abbreviate such as 3-bar, 4-bar, and so on. 193 00:11:21,620 --> 00:11:25,160 So this is analogous to a situation that will come later 194 00:11:25,160 --> 00:11:27,660 where we really need a new notation. 195 00:11:27,660 --> 00:11:32,000 So we've fell headlong over a new type of symmetry 196 00:11:32,000 --> 00:11:37,380 operation, and we should consider taking inversion and 197 00:11:37,380 --> 00:11:39,690 adding that to the rotation axes by 198 00:11:39,690 --> 00:11:42,390 themselves as an extender. 199 00:11:42,390 --> 00:11:44,940 Obviously, if we take inversion and add it to a 200 00:11:44,940 --> 00:11:48,030 mirror plane, we're going to get A pi. 201 00:11:48,030 --> 00:11:54,260 If we take a twofold rotation, add it perpendicular to a 202 00:11:54,260 --> 00:11:55,860 mirror plane, we get inversion. 203 00:11:55,860 --> 00:11:59,970 If we put inversion and put it on a 180-degree rotation, 204 00:11:59,970 --> 00:12:01,630 we'll get the mirror plane back. 205 00:12:01,630 --> 00:12:05,540 So these things all permute one to another. 206 00:12:05,540 --> 00:12:09,160 You may even remember some time ago we asked in general 207 00:12:09,160 --> 00:12:13,270 terms when do two operations permute 208 00:12:13,270 --> 00:12:15,720 without changing anything. 209 00:12:15,720 --> 00:12:20,550 And the answer is if these operations to leave the locus 210 00:12:20,550 --> 00:12:22,330 of the other one alone. 211 00:12:22,330 --> 00:12:24,740 And the mirror plane obviously leaves the locus of the 212 00:12:24,740 --> 00:12:27,780 rotation operation unchanged. 213 00:12:27,780 --> 00:12:31,200 The rotation operation spins the mirror plane around in its 214 00:12:31,200 --> 00:12:34,660 own plane and doesn't create a new axis. 215 00:12:34,660 --> 00:12:39,640 And the inversion center leaves the mirror plane alone 216 00:12:39,640 --> 00:12:42,570 and takes the twofold axis top to bottom. 217 00:12:42,570 --> 00:12:51,720 So those three operations, inversion A pi, sigma are the 218 00:12:51,720 --> 00:12:56,030 three nontrivial operations that exist in the space. 219 00:12:56,030 --> 00:12:59,240 The fourth one is the identity operation. 220 00:12:59,240 --> 00:13:02,220 So here is the set of elements in the group that 221 00:13:02,220 --> 00:13:06,920 we will call 2/m. 222 00:13:06,920 --> 00:13:10,460 2/m implies three operations inversion, a 180-degree 223 00:13:10,460 --> 00:13:13,020 rotation, reflection in a plane perpendicular to the 224 00:13:13,020 --> 00:13:15,895 axis, and the identity operation. 225 00:13:18,620 --> 00:13:21,780 And I'll leave it to yourself for you to convince yourself 226 00:13:21,780 --> 00:13:25,580 that I can rotate and then reflect or I can reflect and 227 00:13:25,580 --> 00:13:26,530 then invert. 228 00:13:26,530 --> 00:13:30,410 And all of these operations do not create any new 229 00:13:30,410 --> 00:13:32,860 motifs in the set. 230 00:13:32,860 --> 00:13:35,100 The group multiplication table, in other words, 231 00:13:35,100 --> 00:13:37,830 contains just the four elements, 1, 232 00:13:37,830 --> 00:13:40,440 1-bar, A pi, and sigma. 233 00:13:43,300 --> 00:13:48,820 So the full pattern that corresponds to 2/m consists of 234 00:13:48,820 --> 00:13:52,800 four objects. 235 00:13:52,800 --> 00:13:54,810 It'll be a fourth one down here. 236 00:13:54,810 --> 00:13:57,710 The twofold axis tells you have this fellow is 237 00:13:57,710 --> 00:13:58,710 related to this one. 238 00:13:58,710 --> 00:14:01,880 Inversion tells you how this one is related to this one. 239 00:14:01,880 --> 00:14:04,460 And the mirror plane tells you how this one, number 1, is 240 00:14:04,460 --> 00:14:05,870 related to number 4. 241 00:14:05,870 --> 00:14:08,063 And the identity operation tells you how 1 242 00:14:08,063 --> 00:14:09,490 is related to itself. 243 00:14:09,490 --> 00:14:12,930 So, again, as we've seen in the set of operations that 244 00:14:12,930 --> 00:14:16,220 constitute a group, there's a one-to-one correspondence 245 00:14:16,220 --> 00:14:20,460 between the transformations that are elements of the group 246 00:14:20,460 --> 00:14:22,760 and the number of objects in the pattern. 247 00:14:30,500 --> 00:14:34,540 So we've made one combination, and what we found from this is 248 00:14:34,540 --> 00:14:38,950 a new transformation inversion that involves changing the 249 00:14:38,950 --> 00:14:43,350 sign of all the coordinates in a space through a point which 250 00:14:43,350 --> 00:14:44,635 is called the inversion center. 251 00:14:48,313 --> 00:14:49,563 Questions? 252 00:14:58,590 --> 00:15:05,470 If not, let me quickly rattle off other Point 253 00:15:05,470 --> 00:15:07,840 Groups in this family. 254 00:15:07,840 --> 00:15:13,975 We could take the operation A pi/2 in 90-degree rotation and 255 00:15:13,975 --> 00:15:18,135 add this perpendicular to mirror plane. 256 00:15:22,240 --> 00:15:24,840 Let me now say something that I've said 257 00:15:24,840 --> 00:15:27,260 again many times before. 258 00:15:27,260 --> 00:15:32,200 The pattern of objects that will result is the pattern of 259 00:15:32,200 --> 00:15:37,270 objects that's produced by the initial group-- 260 00:15:37,270 --> 00:15:39,460 let's say a fourfold axis-- 261 00:15:39,460 --> 00:15:41,590 repeated by the extender. 262 00:15:41,590 --> 00:15:45,570 And the operation sigma perpendicular is the extender. 263 00:15:48,430 --> 00:15:52,530 So the pattern, without making any big deal about it, is 264 00:15:52,530 --> 00:15:57,340 going to look like this square of objects reflected down 265 00:15:57,340 --> 00:15:59,390 below the mirror plane. 266 00:15:59,390 --> 00:16:00,840 So it'll be one going down like this. 267 00:16:00,840 --> 00:16:01,620 One like this. 268 00:16:01,620 --> 00:16:03,300 One like this. 269 00:16:03,300 --> 00:16:06,810 The operation A pi sits perpendicular to the operation 270 00:16:06,810 --> 00:16:10,360 of reflection, so there will be an inversion center that 271 00:16:10,360 --> 00:16:13,590 arises at the point of intersection. 272 00:16:13,590 --> 00:16:17,260 And indeed the square above can be inverted 273 00:16:17,260 --> 00:16:20,030 through this point-- 274 00:16:20,030 --> 00:16:22,350 little hasty repairs there-- 275 00:16:22,350 --> 00:16:26,690 and every one up above gets inverted down to an 276 00:16:26,690 --> 00:16:28,210 enantiomorph below. 277 00:16:28,210 --> 00:16:31,400 So all of these guys up on top are right handed. 278 00:16:31,400 --> 00:16:35,820 All these guys down below are left handed. 279 00:16:35,820 --> 00:16:37,340 So this is another group. 280 00:16:37,340 --> 00:16:44,070 This is 4/m in international notation, a fourfold axis 281 00:16:44,070 --> 00:16:45,810 perpendicular to a mirror plane. 282 00:16:48,710 --> 00:16:54,030 There is also, unfortunately, a Schoenflies notation. 283 00:16:54,030 --> 00:16:57,650 The international notation tells you what you've got, a 284 00:16:57,650 --> 00:16:59,770 twofold axis or a fourfold axis 285 00:16:59,770 --> 00:17:02,060 perpendicular to a mirror plane. 286 00:17:02,060 --> 00:17:05,490 The Schoenflies notation tells you how you derived it. 287 00:17:05,490 --> 00:17:11,079 And the symbol for a twofold axis is C2, so this is a 288 00:17:11,079 --> 00:17:13,180 twofold axis. 289 00:17:13,180 --> 00:17:18,930 And what we did was to add an extender consisting of a 290 00:17:18,930 --> 00:17:20,609 horizontal mirror plane. 291 00:17:20,609 --> 00:17:25,630 Schoenflies calls this one C2h; Group C2, which is a 292 00:17:25,630 --> 00:17:33,695 twofold axis; a horizontal m is the extender. 293 00:17:36,900 --> 00:17:39,820 So Schoenflies tells you how you make it. 294 00:17:39,820 --> 00:17:42,040 The international notation tells you what 295 00:17:42,040 --> 00:17:45,280 you get as a result. 296 00:17:45,280 --> 00:17:49,200 Schoenflies notation here would be C4, that's the symbol 297 00:17:49,200 --> 00:17:53,763 for a fourfold axis, and the extender is an h. 298 00:17:57,840 --> 00:18:00,480 And then without making any big fuss about it, if I do the 299 00:18:00,480 --> 00:18:06,510 same with a sixfold axis, I will have six objects related 300 00:18:06,510 --> 00:18:09,730 by a sixfold rotation axis. 301 00:18:09,730 --> 00:18:16,010 If I take that sixfold axis and put a mirror plane 302 00:18:16,010 --> 00:18:20,960 perpendicular to it, these will be reflected down to a 303 00:18:20,960 --> 00:18:25,400 hexagon of enantiomorph equidistant 304 00:18:25,400 --> 00:18:26,650 below the mirror plane. 305 00:18:36,040 --> 00:18:38,100 That's not terribly good, but it's not terribly bad either. 306 00:18:38,100 --> 00:18:43,693 So this would be called 6/m, Schoenflies notation C6h. 307 00:18:47,080 --> 00:18:53,240 And the operation A pi exists in a sixfold axis, so there is 308 00:18:53,240 --> 00:18:56,690 an inversion center but also arises as a new symmetry 309 00:18:56,690 --> 00:18:58,493 element at the point of intersection. 310 00:19:03,160 --> 00:19:05,750 So with reckless abandon, you can continue on here and 311 00:19:05,750 --> 00:19:10,360 derive noncrystallographic groups for all the even-fold 312 00:19:10,360 --> 00:19:16,740 axes and derive an 8/m and a 12/m and 16/m. 313 00:19:16,740 --> 00:19:17,760 Lovely symmetries. 314 00:19:17,760 --> 00:19:21,240 I wouldn't want to draw them, but they're still symmetries. 315 00:19:21,240 --> 00:19:24,210 They all have an inversion center in them, but they're 316 00:19:24,210 --> 00:19:25,340 noncrystallographic. 317 00:19:25,340 --> 00:19:27,460 So we don't have to worry about them for prism purposes. 318 00:19:32,910 --> 00:19:41,200 I left one out because it introduces a complication that 319 00:19:41,200 --> 00:19:43,360 is kind of curious and interesting. 320 00:19:43,360 --> 00:19:45,040 Any questions on what we've done here? 321 00:19:45,040 --> 00:19:45,340 Yes? 322 00:19:45,340 --> 00:19:48,770 AUDIENCE: The 2mm, it's just the same-- 323 00:19:48,770 --> 00:19:51,480 Schoenflies notation is just C2-- 324 00:19:51,480 --> 00:19:53,810 PROFESSOR: Schoenflies notation for three dimensions 325 00:19:53,810 --> 00:19:55,880 is exactly the same as in two. 326 00:19:55,880 --> 00:20:01,540 So the three-dimensional version where this extends in 327 00:20:01,540 --> 00:20:10,350 a direction that is normal to the two-dimensional space of 328 00:20:10,350 --> 00:20:11,080 our two dimensions. 329 00:20:11,080 --> 00:20:13,090 Two dimensions it was this. 330 00:20:13,090 --> 00:20:16,220 Now just imagine them coming out of the blackboard at you. 331 00:20:16,220 --> 00:20:17,970 The symbol for this one was 2mm. 332 00:20:20,550 --> 00:20:26,740 The symbol for this one is also 2mm, the same thing. 333 00:20:26,740 --> 00:20:29,590 The mirror plane is a vertical mirror plane. 334 00:20:32,730 --> 00:20:35,510 So the Schoenflies notation is exactly the same as what we 335 00:20:35,510 --> 00:20:37,580 used per two dimensions. 336 00:20:37,580 --> 00:20:38,830 It's called C2v. 337 00:20:42,205 --> 00:20:45,190 We've added a vertical mirror plane. 338 00:20:45,190 --> 00:20:47,090 And again, horizontal and vertical. 339 00:20:47,090 --> 00:20:50,300 Horizontal is horizontal with respect to the 340 00:20:50,300 --> 00:20:52,470 axis of higher symmetry. 341 00:20:52,470 --> 00:20:56,750 Vertical is vertical with respect to the two-dimensional 342 00:20:56,750 --> 00:21:00,240 space of the two-dimensional Point Group, parallel to the 343 00:21:00,240 --> 00:21:01,800 axis in three dimensions. 344 00:21:01,800 --> 00:21:03,455 So that's the vertical indication. 345 00:21:07,120 --> 00:21:10,100 So let's, though, tuck that away for future reference. 346 00:21:10,100 --> 00:21:13,340 We've got two kinds of extenders. 347 00:21:13,340 --> 00:21:18,060 We've got a horizontal mirror plane, and we've got a 348 00:21:18,060 --> 00:21:23,570 vertical mirror plane, and these are extenders that we 349 00:21:23,570 --> 00:21:25,760 should consider adding. 350 00:21:25,760 --> 00:21:31,520 So we've taken care of 2/m, 4/m and 6/m. 351 00:21:31,520 --> 00:21:38,420 2mm, 3m, 4mm, and 6mm are just the extensions into a third 352 00:21:38,420 --> 00:21:41,570 dimension of what we've seen and come to love in the 353 00:21:41,570 --> 00:21:42,820 two-dimensional space. 354 00:21:45,990 --> 00:21:49,050 Let me now turn to the threefold axis. 355 00:21:49,050 --> 00:21:50,920 And this is a curious one. 356 00:21:50,920 --> 00:21:56,030 Threefold axes require fewer symbols to indicate the 357 00:21:56,030 --> 00:21:58,700 vertical mirror planes because there's only 358 00:21:58,700 --> 00:22:00,890 one independent one. 359 00:22:00,890 --> 00:22:02,760 But let's see what would happen. 360 00:22:02,760 --> 00:22:06,740 And now I'm not going to attempt to draw these in three 361 00:22:06,740 --> 00:22:07,710 dimensions anymore. 362 00:22:07,710 --> 00:22:11,140 I'm going to use a stereographic projection. 363 00:22:11,140 --> 00:22:15,700 And what I'll do is use a solid dot for a point that's 364 00:22:15,700 --> 00:22:20,690 up above the equatorial plane and an open dot for one that's 365 00:22:20,690 --> 00:22:24,250 down below the equatorial plane. 366 00:22:24,250 --> 00:22:30,260 So my stereographic projection of 4mm would look like. 367 00:22:30,260 --> 00:22:31,780 This is the fourfold axis. 368 00:22:31,780 --> 00:22:33,770 This is the mirror plane. 369 00:22:33,770 --> 00:22:40,370 And I've got one up that gets reproduced by the axis to give 370 00:22:40,370 --> 00:22:41,730 me a set of four. 371 00:22:41,730 --> 00:22:44,450 All of these are, let's say, right handed. 372 00:22:44,450 --> 00:22:48,490 And then directly below them is another set of four 373 00:22:48,490 --> 00:22:53,750 repeated by reflection, and these are all left handed. 374 00:22:53,750 --> 00:22:57,270 And then there's an inversion center at the point of 375 00:22:57,270 --> 00:22:58,040 intersection. 376 00:22:58,040 --> 00:23:02,500 And I'll indicate that by the little open circle sitting 377 00:23:02,500 --> 00:23:04,120 right on the fourfold axis. 378 00:23:04,120 --> 00:23:07,310 So there is a projection of what 4/m looks like. 379 00:23:10,120 --> 00:23:15,740 So let me now do the same thing for a threefold axis. 380 00:23:15,740 --> 00:23:22,050 And I'll add to the triangle of points that a threefold 381 00:23:22,050 --> 00:23:24,460 axis would generate. 382 00:23:24,460 --> 00:23:26,800 So these guys are all of one chirality. 383 00:23:26,800 --> 00:23:28,050 Let's say right handed. 384 00:23:36,500 --> 00:23:41,170 Then I'll reflect them down, and I'll get three objects 385 00:23:41,170 --> 00:23:42,420 that are down. 386 00:23:46,850 --> 00:23:48,935 And that's what 3/m looks like. 387 00:23:54,040 --> 00:23:57,360 Is there an inversion center here? 388 00:23:57,360 --> 00:23:58,456 No. 389 00:23:58,456 --> 00:24:05,440 No, because the operation of A pi is missing. 390 00:24:05,440 --> 00:24:08,840 And it was the horizontal mirror plane combined with A 391 00:24:08,840 --> 00:24:15,620 pi that gave us the inversion center with all of the even 392 00:24:15,620 --> 00:24:17,340 rotation axis. 393 00:24:17,340 --> 00:24:20,980 So one of the things we have to say here is that there is 394 00:24:20,980 --> 00:24:30,490 no 1-bar that's present, which means in this instance, unlike 395 00:24:30,490 --> 00:24:34,200 the other ones, we have another option. 396 00:24:34,200 --> 00:24:39,730 So we can use the operation of inversion as an extender too. 397 00:24:48,920 --> 00:24:51,430 So we're going to get another group out of the threefold 398 00:24:51,430 --> 00:24:53,080 axis besides this one. 399 00:24:53,080 --> 00:25:00,060 And this one we will name 3/m or C3h 400 00:25:00,060 --> 00:25:01,310 in Schoenflies notation. 401 00:25:07,350 --> 00:25:12,150 They're six objects here, so there should be six operations 402 00:25:12,150 --> 00:25:13,420 in the group. 403 00:25:13,420 --> 00:25:18,590 So let me number these guys up on top as number 1, 404 00:25:18,590 --> 00:25:22,190 number 2, number 3. 405 00:25:22,190 --> 00:25:26,400 And 1 is related to itself by inversion. 406 00:25:26,400 --> 00:25:29,770 There's an operation A 2 pi/3. 407 00:25:29,770 --> 00:25:32,950 And that tells me how the one that's up is related to the 408 00:25:32,950 --> 00:25:36,260 second one that's up and how the left-handed one that's 409 00:25:36,260 --> 00:25:38,900 down is related to the one that's directly 410 00:25:38,900 --> 00:25:41,570 below number 2. 411 00:25:41,570 --> 00:25:46,250 There is an operation A 4 pi/3. 412 00:25:46,250 --> 00:25:50,970 And that's the same as saying 8 minus 2 pi/3. 413 00:25:50,970 --> 00:25:56,220 And that tells us how the things that are separated by 414 00:25:56,220 --> 00:25:59,370 240 degrees are related, both up and down. 415 00:26:06,950 --> 00:26:14,490 I know how 3 up is related to 3 down and how 1 up is related 416 00:26:14,490 --> 00:26:18,480 to 1 down and 2 up is related to 2 down. 417 00:26:18,480 --> 00:26:24,860 This is all with the horizontal mirror plane, which 418 00:26:24,860 --> 00:26:26,110 I'll call sigma h. 419 00:26:29,450 --> 00:26:32,540 That is a total of one, two, three, four-- 420 00:26:32,540 --> 00:26:36,730 whoops-- one, two, three four operations. 421 00:26:36,730 --> 00:26:37,980 I need six. 422 00:26:40,590 --> 00:26:49,430 Let's ask how is this one that's up related to this one 423 00:26:49,430 --> 00:26:50,680 that's down? 424 00:26:54,550 --> 00:26:58,310 I just got rotation operations and reflection. 425 00:26:58,310 --> 00:27:02,870 The only way I can get from this one number 1 to this one 426 00:27:02,870 --> 00:27:10,750 number 3 left that's down is to take two steps to do it. 427 00:27:10,750 --> 00:27:14,590 I can't get from this one up here to this one down here 428 00:27:14,590 --> 00:27:24,805 unless I rotate 60 degrees and then invert. 429 00:27:29,820 --> 00:27:32,530 If I move over to 3-bar. 430 00:27:37,950 --> 00:27:45,225 This is A 2 pi/3 with 1-bar as an extender. 431 00:27:51,960 --> 00:27:56,540 The pattern would, again, look like what are 432 00:27:56,540 --> 00:27:59,660 threefold axis does. 433 00:27:59,660 --> 00:28:04,080 But then if I repeat this set of three by inversion, the two 434 00:28:04,080 --> 00:28:07,410 triangles above and below are skewed. 435 00:28:07,410 --> 00:28:10,060 The ones down below are enantiomorphs. 436 00:28:10,060 --> 00:28:13,800 The three that are up are of opposite chirality. 437 00:28:13,800 --> 00:28:20,310 And this is a new type of pattern. 438 00:28:20,310 --> 00:28:24,850 And in international notation, what do we call this? 439 00:28:24,850 --> 00:28:26,290 It's a threefold axis. 440 00:28:26,290 --> 00:28:32,730 But how do we indicate a symbol for three with 441 00:28:32,730 --> 00:28:36,420 inversion sitting on it? 442 00:28:36,420 --> 00:28:41,090 Let's ask if we know how each of these objects is related to 443 00:28:41,090 --> 00:28:42,350 each of the other. 444 00:28:42,350 --> 00:28:53,040 So here's 1, 2, and 3; 1 goes to 2 by A 2 pi/3; 1 goes to 3 445 00:28:53,040 --> 00:28:55,130 by A minus 2 pi/3. 446 00:29:03,490 --> 00:29:06,350 Let's put some numbers on here for the ones down below. 447 00:29:06,350 --> 00:29:13,485 Let's call them 4, 5, and 6; 1 goes to 6 by an version. 448 00:29:19,540 --> 00:29:24,590 How do I get from 1 up to 4 that's down? 449 00:29:29,210 --> 00:29:33,160 I can do that only by taking two steps. 450 00:29:33,160 --> 00:29:36,520 Rotate 1 from here to number 2. 451 00:29:36,520 --> 00:29:38,450 Don't yet put it down. 452 00:29:38,450 --> 00:29:41,000 First invert it. 453 00:29:41,000 --> 00:29:48,990 So 1 to 4 involves the operation A 2 pi/3 followed 454 00:29:48,990 --> 00:29:50,240 immediately by inversion. 455 00:29:53,960 --> 00:30:05,530 And I go from 1 up to 5 down by doing the operation A minus 456 00:30:05,530 --> 00:30:09,240 2 pi/3 followed immediately by inversion. 457 00:30:11,800 --> 00:30:16,640 And then 1 goes to 1 and itself by 458 00:30:16,640 --> 00:30:18,020 the identity operation. 459 00:30:18,020 --> 00:30:21,170 So I have six objects, one, two, three, four, five, six 460 00:30:21,170 --> 00:30:22,810 operations. 461 00:30:22,810 --> 00:30:23,140 Yes? 462 00:30:23,140 --> 00:30:26,122 AUDIENCE: In the cases where you're rotating and inverting, 463 00:30:26,122 --> 00:30:30,098 does it matter which way to the other? 464 00:30:30,098 --> 00:30:32,930 PROFESSOR: No, it shouldn't because they 465 00:30:32,930 --> 00:30:33,940 leave each other alone. 466 00:30:33,940 --> 00:30:37,085 So I can rotate from here to here and invert. 467 00:30:37,085 --> 00:30:40,210 Or I can invert from here to here and then rotate. 468 00:30:40,210 --> 00:30:41,500 It's the same transformation. 469 00:30:41,500 --> 00:30:46,100 Again, they permute if the two loci of the two operations 470 00:30:46,100 --> 00:30:50,050 leave the other locus alone. 471 00:30:50,050 --> 00:30:52,640 Maybe the enormity of what we've shown here 472 00:30:52,640 --> 00:30:54,320 has not sunk in. 473 00:30:54,320 --> 00:30:58,090 This is a new two-step operation. 474 00:31:06,040 --> 00:31:09,220 We can't describe it any simpler than saying, rotate 475 00:31:09,220 --> 00:31:12,200 and not put it down yet, follow up by inversion. 476 00:31:12,200 --> 00:31:12,480 Yes, sir? 477 00:31:12,480 --> 00:31:13,896 AUDIENCE: Couldn't we express that in another way by sort of 478 00:31:13,896 --> 00:31:16,256 extending the three-directional glide plane 479 00:31:16,256 --> 00:31:21,692 by saying invert, then transform by some vector 480 00:31:21,692 --> 00:31:24,596 that's parallel to the glide plane? 481 00:31:24,596 --> 00:31:28,360 PROFESSOR: Maybe they do in space group, but as soon as we 482 00:31:28,360 --> 00:31:32,460 introduce a glide plane, you've got an operation that's 483 00:31:32,460 --> 00:31:34,525 half a lattice translation. 484 00:31:34,525 --> 00:31:37,010 And that means you've got to have a lattice translation and 485 00:31:37,010 --> 00:31:38,030 double the lattice translation, so-- 486 00:31:38,030 --> 00:31:38,990 AUDIENCE: Oh, we don't have to worry about that. 487 00:31:38,990 --> 00:31:41,180 PROFESSOR: --when we're in a space group, yeah. 488 00:31:41,180 --> 00:31:42,080 That could be present. 489 00:31:42,080 --> 00:31:44,550 But not for a point group because the ground rules are 490 00:31:44,550 --> 00:31:47,380 at least one point has to remain 491 00:31:47,380 --> 00:31:48,815 immutably fixed in space. 492 00:31:57,570 --> 00:32:00,530 So this is a two-step operation, and what we're 493 00:32:00,530 --> 00:32:02,470 going to call it is rotoinversion. 494 00:32:07,040 --> 00:32:12,930 It consists of as a first step an operation by rotating alpha 495 00:32:12,930 --> 00:32:16,720 from 0.1 to a virtual point number 2. 496 00:32:16,720 --> 00:32:21,510 But before you put it down, you will invert it to a new 497 00:32:21,510 --> 00:32:25,035 object number 2 which is of opposite chirality. 498 00:32:28,300 --> 00:32:33,630 So here then are the operation of the group that results when 499 00:32:33,630 --> 00:32:37,900 you combine a threefold rotation axis and add to it an 500 00:32:37,900 --> 00:32:45,210 version center as an extended; A 2 pi/3; A minus 2 pi/3; a 501 00:32:45,210 --> 00:32:50,960 rotoinversion operation through 2 pi/3 and then 502 00:32:50,960 --> 00:32:56,920 inverting; a rotoinversion operation of A minus 2 pi/3 503 00:32:56,920 --> 00:32:58,280 followed by inversion. 504 00:32:58,280 --> 00:33:01,390 And the symbol that is used to represent that new two-step 505 00:33:01,390 --> 00:33:06,730 operation is putting a bar over the top of the 506 00:33:06,730 --> 00:33:08,940 symbol for the axis. 507 00:33:08,940 --> 00:33:11,260 And then, finally, we have inversion by itself. 508 00:33:11,260 --> 00:33:12,840 So that's a group rank 6. 509 00:33:16,700 --> 00:33:26,790 The Schoenflies notation is called C3i because we got this 510 00:33:26,790 --> 00:33:31,830 group by adding an inversion to C3, the threefold axis. 511 00:33:31,830 --> 00:33:37,200 The international notation picks up on putting a bar over 512 00:33:37,200 --> 00:33:40,240 an axis to indicate a rotoinversion operation. 513 00:33:40,240 --> 00:33:43,700 So this is called 3-bar in the international notation. 514 00:33:43,700 --> 00:33:47,300 So there is a new group, and it is an oddball. 515 00:33:47,300 --> 00:33:51,070 It sort of stands alone from the other 516 00:33:51,070 --> 00:33:53,135 groups of the form C3h. 517 00:34:26,710 --> 00:34:34,500 This we derived by using the rotation of the threefold axis 518 00:34:34,500 --> 00:34:37,050 and adding 1-bar as an extender. 519 00:34:37,050 --> 00:34:38,600 So there's no mirror plane in this. 520 00:34:38,600 --> 00:34:40,290 AUDIENCE: That's not the same as-- 521 00:34:40,290 --> 00:34:43,239 PROFESSOR: That's the same as 3/m, no. 522 00:34:43,239 --> 00:34:46,210 3/m is C3h. 523 00:34:46,210 --> 00:34:52,389 3-bar is C3i, different extender added to the same 524 00:34:52,389 --> 00:34:53,639 subgroup 3C. 525 00:35:00,407 --> 00:35:03,500 AUDIENCE: What was the definition of 3/m? 526 00:35:03,500 --> 00:35:05,910 PROFESSOR: Oh, we never really finished that. 527 00:35:05,910 --> 00:35:10,090 That if we need the six operations that control the 528 00:35:10,090 --> 00:35:13,050 group, we'll have a sixfold rotoinversion axis. 529 00:35:13,050 --> 00:35:17,490 But this pattern looks just like the triangle produced by 530 00:35:17,490 --> 00:35:23,480 3, and we add an reflection operation as an inversion, and 531 00:35:23,480 --> 00:35:25,140 the 3 go down. 532 00:35:25,140 --> 00:35:28,070 So if we ask how every one of the top is related to one 533 00:35:28,070 --> 00:35:31,550 underneath, that's by this horizontal mirror plane. 534 00:35:31,550 --> 00:35:34,980 If I want to know how I get from this one that's up to 535 00:35:34,980 --> 00:35:38,800 this one that's down, then I've got to rotate through 60 536 00:35:38,800 --> 00:35:40,590 degrees and invert. 537 00:35:40,590 --> 00:35:42,460 So that would be a rotoinversion operation. 538 00:35:57,370 --> 00:36:04,530 Let us to extend this idea of a rotoinversion operation. 539 00:36:04,530 --> 00:36:12,670 And we would find this eventually in adding different 540 00:36:12,670 --> 00:36:16,930 extenders and falling headlong over this rotoinversion 541 00:36:16,930 --> 00:36:20,360 operation as we did here with 3-bar. 542 00:36:20,360 --> 00:36:29,440 But let me in this case start by defining a 4-bar operation. 543 00:36:32,560 --> 00:36:37,030 And this would contain the operation A pi/2 followed 544 00:36:37,030 --> 00:36:41,970 immediately by inversion. 545 00:36:41,970 --> 00:36:45,770 And we'll call this step A pi/2-bar. 546 00:36:49,720 --> 00:36:52,280 So let's try to do that and see what we get. 547 00:36:55,830 --> 00:36:59,790 Start with a first point, number 1. 548 00:36:59,790 --> 00:37:02,420 And that's up, so it's a solid dot. 549 00:37:02,420 --> 00:37:04,980 And let's say it's right handed. 550 00:37:04,980 --> 00:37:10,670 If we combine that with a rotation of 90 degrees. 551 00:37:10,670 --> 00:37:11,710 Not yet put it down. 552 00:37:11,710 --> 00:37:13,170 That's a virtual motif. 553 00:37:13,170 --> 00:37:16,160 Before putting it down, we inverted it. 554 00:37:16,160 --> 00:37:21,650 We would get one that's down, and it would be left handed. 555 00:37:21,650 --> 00:37:23,060 Do the operation again. 556 00:37:23,060 --> 00:37:25,200 I'll put the little tadpole inside. 557 00:37:25,200 --> 00:37:27,360 Do the operation again. 558 00:37:27,360 --> 00:37:29,530 Rotate 90 degrees and invert. 559 00:37:29,530 --> 00:37:31,680 We're back up again. 560 00:37:31,680 --> 00:37:32,780 So this was 1. 561 00:37:32,780 --> 00:37:34,350 This is 2. 562 00:37:34,350 --> 00:37:36,080 This was 3. 563 00:37:36,080 --> 00:37:37,210 And that's up. 564 00:37:37,210 --> 00:37:38,900 Do the operation again. 565 00:37:38,900 --> 00:37:40,515 Rotate and invert. 566 00:37:40,515 --> 00:37:43,790 And here is number 4, and it's down. 567 00:37:43,790 --> 00:37:46,030 Do it a fifth time, and we're back to where we started. 568 00:37:48,750 --> 00:37:51,790 So this is a crazy pattern. 569 00:37:51,790 --> 00:37:55,220 It's a pair of objects that's up and a pair of objects 570 00:37:55,220 --> 00:37:57,750 that's down. 571 00:37:57,750 --> 00:38:00,260 So there's a twofold axis in there. 572 00:38:00,260 --> 00:38:04,380 That twofold axis A pi leave the pattern invariant. 573 00:38:04,380 --> 00:38:07,460 But there is no way of specifying the relation 574 00:38:07,460 --> 00:38:11,500 between the two that are up and the two that are down 575 00:38:11,500 --> 00:38:15,450 other than doing this two-step process of rotating 90 degrees 576 00:38:15,450 --> 00:38:17,360 and then inverting. 577 00:38:17,360 --> 00:38:21,680 So there is actually in this pattern a new type of 578 00:38:21,680 --> 00:38:26,730 operation analogous to 3-bar, and it's called a 4-bar axis. 579 00:38:26,730 --> 00:38:30,870 And it's indicated geometrically by drawing a 580 00:38:30,870 --> 00:38:33,690 square because there's a 90-degree 581 00:38:33,690 --> 00:38:36,290 angular symmetry to this. 582 00:38:36,290 --> 00:38:41,740 But a twofold axis inscribed inside of it because this is a 583 00:38:41,740 --> 00:38:43,360 pattern that has a twofold symmetry. 584 00:38:45,930 --> 00:38:54,410 So something that has this symmetry is the symmetry of a 585 00:38:54,410 --> 00:38:55,660 tetrahedron. 586 00:38:58,340 --> 00:39:02,310 And if we draw a line from the upper edge to the lower edge, 587 00:39:02,310 --> 00:39:05,785 this is the locus of a 4-bar axis. 588 00:39:13,540 --> 00:39:19,250 International notation this is called 4-bar. 589 00:39:19,250 --> 00:39:21,500 That's how we generated the pattern. 590 00:39:21,500 --> 00:39:31,610 The Schoenflies notation is an S, little bit of exotica. 591 00:39:31,610 --> 00:39:35,570 This geometric solid is something 592 00:39:35,570 --> 00:39:36,820 that's called a sphenoid. 593 00:39:40,040 --> 00:39:41,790 And sphenoid. 594 00:39:41,790 --> 00:39:43,850 Is the Greek word for axe. 595 00:39:46,570 --> 00:39:52,050 And you can imagine a handle put onto this thing, and it 596 00:39:52,050 --> 00:39:54,090 does look kind of like an axe. 597 00:39:54,090 --> 00:39:56,550 You could splits firewood with a thing like that. 598 00:39:56,550 --> 00:40:00,070 It looks like a tetrahedron, but in a tetrahedron, it's 599 00:40:00,070 --> 00:40:03,650 either elongated along the 4-bar axis are squished. 600 00:40:03,650 --> 00:40:07,090 It doesn't have to be regular. 601 00:40:07,090 --> 00:40:12,290 So this is called S4, and the S stands for sphenoid. 602 00:40:17,600 --> 00:40:19,492 AUDIENCE: Is it part of a regular tetrahedron? 603 00:40:19,492 --> 00:40:20,930 PROFESSOR: No, no. 604 00:40:20,930 --> 00:40:24,660 A regular tetrahedron would be something where all of the 605 00:40:24,660 --> 00:40:26,940 edges had equal length. 606 00:40:26,940 --> 00:40:32,050 And what we're doing is taking one edge and the edge that's 607 00:40:32,050 --> 00:40:38,090 opposite it and either stretching it or squishing it. 608 00:40:38,090 --> 00:40:41,050 So there are two edges. 609 00:40:41,050 --> 00:40:43,420 This one, and this one, which are the same length. 610 00:40:43,420 --> 00:40:48,260 And then these four inclined edges have a different length. 611 00:40:48,260 --> 00:40:50,330 It could be either elongated or squished. 612 00:40:50,330 --> 00:40:51,895 But it's not a regular tetrahedron. 613 00:40:54,460 --> 00:40:58,220 If those three distances were equal, then geometrically it 614 00:40:58,220 --> 00:40:59,270 would be a tetrahedron. 615 00:40:59,270 --> 00:41:01,540 But strictly speaking, a tetrahedron is not a 616 00:41:01,540 --> 00:41:06,980 tetrahedron, just as a square prism with eight sides 617 00:41:06,980 --> 00:41:09,740 approximately equal can't claim to be a cube unless 618 00:41:09,740 --> 00:41:12,620 there's symmetry present that demands that this be true. 619 00:41:12,620 --> 00:41:17,920 In this case, the 4-bar requires that these four edges 620 00:41:17,920 --> 00:41:21,590 inclined to the 4-bar axis be of one length. 621 00:41:21,590 --> 00:41:23,450 And this have to have the same length. 622 00:41:23,450 --> 00:41:26,570 But there's nothing that constrains all six to the 623 00:41:26,570 --> 00:41:29,540 edges to be of identical length. 624 00:41:29,540 --> 00:41:32,780 So it's not a tetrahedron, so squished or deformed 625 00:41:32,780 --> 00:41:34,030 tetrahedron. 626 00:41:39,600 --> 00:41:47,200 So there is another two-step symmetry element that we would 627 00:41:47,200 --> 00:41:51,630 not have been clever enough to think of had we not discovered 628 00:41:51,630 --> 00:41:55,880 this sort of rotoinversion operation when we added 629 00:41:55,880 --> 00:41:59,340 inversion to a threefold axis. 630 00:41:59,340 --> 00:42:03,960 A 3-bar axis is a step that's present when you add inversion 631 00:42:03,960 --> 00:42:07,320 to a threefold axis. 632 00:42:07,320 --> 00:42:11,430 So 3-bar, what we call it for short, is identical to a 633 00:42:11,430 --> 00:42:14,280 threefold axis plus inversion sitting on it. 634 00:42:14,280 --> 00:42:20,390 A 4-bar is not equal to a fourfold axis with inversion 635 00:42:20,390 --> 00:42:21,640 added to it. 636 00:42:23,790 --> 00:42:26,540 A 4-bar is something that you cannot describe any more 637 00:42:26,540 --> 00:42:30,770 simply than saying there is a two-step operation in there, 638 00:42:30,770 --> 00:42:33,450 and it's a group of rank 4. 639 00:42:39,390 --> 00:42:44,690 Let me finish by setting up the task of going through this 640 00:42:44,690 --> 00:42:45,940 systematically. 641 00:42:50,540 --> 00:42:57,464 We have 11 axial combinations 1, 2, 3, 4, 6, 222, 32, 422, 642 00:42:57,464 --> 00:43:03,140 622, 23, and 432. 643 00:43:03,140 --> 00:43:05,930 So there are 11 of those. 644 00:43:05,930 --> 00:43:11,550 We want to examine as extenders a vertical mirror 645 00:43:11,550 --> 00:43:17,690 plane that would be one extender. 646 00:43:17,690 --> 00:43:19,830 We should add that to each of these symmetries. 647 00:43:19,830 --> 00:43:21,510 We already done a lot of these. 648 00:43:21,510 --> 00:43:28,190 We've done pretty much up here. 649 00:43:28,190 --> 00:43:30,110 We could add a horizontal mirror plane. 650 00:43:38,700 --> 00:43:44,710 Or we've encountered inversion when we added a mirror plane 651 00:43:44,710 --> 00:43:46,820 perpendicular to an even-fold axis. 652 00:43:46,820 --> 00:43:48,615 We could add inversion as an extender. 653 00:43:51,810 --> 00:43:55,970 And to be complete, we should add to our list of axes in 654 00:43:55,970 --> 00:43:59,700 quotation marks, the 4-bar axis, having discovered it. 655 00:44:06,030 --> 00:44:08,710 And does that do it? 656 00:44:08,710 --> 00:44:11,940 Is there anything else we could do to these axes that 657 00:44:11,940 --> 00:44:15,196 would leave them invariant? 658 00:44:15,196 --> 00:44:16,142 . 659 00:44:16,142 --> 00:44:17,392 AUDIENCE: What about 2-bar? 660 00:44:19,930 --> 00:44:25,300 PROFESSOR: 2-bar; 2-bar would be rotate 661 00:44:25,300 --> 00:44:28,510 180 degrees and invert. 662 00:44:28,510 --> 00:44:35,310 So 2-bar is identical to a horizontal mirror plane. 663 00:44:35,310 --> 00:44:36,560 So that's nothing new. 664 00:44:39,410 --> 00:44:42,035 We're already running a little over time so-- 665 00:44:42,035 --> 00:44:42,250 Yeah? 666 00:44:42,250 --> 00:44:43,530 AUDIENCE: 3-bar? 667 00:44:43,530 --> 00:44:47,100 PROFESSOR: 3-bar is 3 plus 1, and we call at 3i, so 668 00:44:47,100 --> 00:44:50,180 this one down here. 669 00:44:50,180 --> 00:44:51,520 This is 3-bar. 670 00:44:51,520 --> 00:44:53,800 We describe it for short as that, but it really is a 671 00:44:53,800 --> 00:44:55,350 threefold axis with an inversion 672 00:44:55,350 --> 00:44:56,960 center sitting on it. 673 00:44:56,960 --> 00:45:00,070 This thing is distinct because it's not a fourfold axis with 674 00:45:00,070 --> 00:45:02,130 inversion sitting on it. 675 00:45:02,130 --> 00:45:04,190 A 4-bar is a 4-bar is a 4-bar. 676 00:45:04,190 --> 00:45:09,050 You can't decompose it as a twofold axis is a subgroup. 677 00:45:09,050 --> 00:45:12,040 That's only half the story. 678 00:45:12,040 --> 00:45:16,510 I don't want to keep you anxious, not anxious to find 679 00:45:16,510 --> 00:45:18,175 out what the answer is but anxious to get on 680 00:45:18,175 --> 00:45:19,350 your way and go home. 681 00:45:19,350 --> 00:45:29,170 So let me submit that when we have more than one rotation 682 00:45:29,170 --> 00:45:49,440 axis, such as 222 or as in 32, if we put the mirror plane in 683 00:45:49,440 --> 00:45:56,510 normal to the principal axis, we'll call that a horizontal 684 00:45:56,510 --> 00:45:59,084 mirror plane. 685 00:45:59,084 --> 00:46:04,930 If we add the mirror plane through the principal axis, we 686 00:46:04,930 --> 00:46:08,550 could pass it through the threefold axis and the twofold 687 00:46:08,550 --> 00:46:12,100 axis, pass it through the vertical twofold axis and the 688 00:46:12,100 --> 00:46:13,770 horizontal twofold axis. 689 00:46:13,770 --> 00:46:17,330 We will call this a vertical mirror plane. 690 00:46:17,330 --> 00:46:20,260 And that's all we could say for a single axis, the mirror 691 00:46:20,260 --> 00:46:23,200 plane was perpendicular to the axis or passed through it. 692 00:46:23,200 --> 00:46:26,930 But when there's more than one axis, another thing we could 693 00:46:26,930 --> 00:46:33,310 do would be to snake the mirror plane in between the 694 00:46:33,310 --> 00:46:34,860 twofold axis. 695 00:46:34,860 --> 00:46:37,370 In that case, this twofold axis gets 696 00:46:37,370 --> 00:46:39,100 reflected into this one. 697 00:46:39,100 --> 00:46:42,750 But I haven't created any new axes. 698 00:46:42,750 --> 00:46:44,980 So that is going to leave the results of Euler's 699 00:46:44,980 --> 00:46:46,700 construction unchanged. 700 00:46:46,700 --> 00:46:50,500 I can't similarly put a vertical mirror plane through 701 00:46:50,500 --> 00:46:54,800 this first twofold axis but in between the other two. 702 00:46:54,800 --> 00:46:58,740 In that case, this is no longer 222 because these two 703 00:46:58,740 --> 00:47:01,220 mirror planes are equivalent by reflection, so I want to 704 00:47:01,220 --> 00:47:02,820 drop that at very least. 705 00:47:02,820 --> 00:47:04,440 So in any case, without belaboring 706 00:47:04,440 --> 00:47:05,860 the point, it's late. 707 00:47:05,860 --> 00:47:12,290 I could do for each of the groups that involved more than 708 00:47:12,290 --> 00:47:19,885 one axis I could add a diagonal mirror plane, or I 709 00:47:19,885 --> 00:47:21,500 should try to add a diagonal mirror planes. 710 00:47:21,500 --> 00:47:26,520 And this means interleaved between axes that are present 711 00:47:26,520 --> 00:47:29,010 in these combinations, added such that 712 00:47:29,010 --> 00:47:32,370 no new axis is created. 713 00:47:32,370 --> 00:47:35,930 But the addition clearly is going to be a new disposition 714 00:47:35,930 --> 00:47:38,030 of symmetry elements arranged in any 715 00:47:38,030 --> 00:47:39,890 different fashion and space. 716 00:47:42,400 --> 00:47:43,620 So the game's afoot. 717 00:47:43,620 --> 00:47:45,920 This is what remains to be done next. 718 00:47:48,540 --> 00:47:52,050 What I'll do for next time is prepare a chart that looks 719 00:47:52,050 --> 00:47:55,680 like this that has the results of all of the unique 720 00:47:55,680 --> 00:48:00,530 combinations shown and then hand out pictures of 721 00:48:00,530 --> 00:48:02,880 stereographic projections of all the results. 722 00:48:02,880 --> 00:48:06,910 I think once you know how to play the game to go through 723 00:48:06,910 --> 00:48:11,020 and do every single one in detail is 724 00:48:11,020 --> 00:48:12,400 probably not necessary. 725 00:48:12,400 --> 00:48:15,010 If you know how to do some of them and you know all the 726 00:48:15,010 --> 00:48:19,930 tricks for adding extenders, you could do it if you had to. 727 00:48:19,930 --> 00:48:20,270 All right. 728 00:48:20,270 --> 00:48:24,350 So, again, sorry we started late and sorry that we last 729 00:48:24,350 --> 00:48:25,600 long as well.