1 00:00:00,050 --> 00:00:02,500 The following content is provided under a Creative 2 00:00:02,500 --> 00:00:04,010 Commons license. 3 00:00:04,010 --> 00:00:06,350 Your support will help MIT OpenCourseWare 4 00:00:06,350 --> 00:00:10,720 continue to offer high-quality educational resources for free. 5 00:00:10,720 --> 00:00:13,330 To make a donation or view additional materials 6 00:00:13,330 --> 00:00:17,226 from hundreds of MIT courses, visit MIT OpenCourseWare 7 00:00:17,226 --> 00:00:17,851 at ocw.mit.edu. 8 00:00:25,950 --> 00:00:28,740 PROFESSOR: So we have an interesting class today. 9 00:00:28,740 --> 00:00:31,410 We're going to be taking this IV curve that we've so 10 00:00:31,410 --> 00:00:34,300 laboriously set up and understood-- sorry about that. 11 00:00:34,300 --> 00:00:38,110 And now we will subject it to illumination. 12 00:00:38,110 --> 00:00:40,760 So that's the essence of our lecture today, 13 00:00:40,760 --> 00:00:42,710 the diode under illumination. 14 00:00:42,710 --> 00:00:45,020 And as part of today's lecture, we 15 00:00:45,020 --> 00:00:46,770 have some wonderful little kits over there 16 00:00:46,770 --> 00:00:48,970 in the corner where we'll actually be testing 17 00:00:48,970 --> 00:00:51,300 IV curves of solar cells. 18 00:00:51,300 --> 00:00:53,620 So I hope some of you brought the computers today, 19 00:00:53,620 --> 00:00:56,480 and if not, we have some extras up here as well we can use. 20 00:00:56,480 --> 00:00:57,980 So again, just to situate ourselves. 21 00:00:57,980 --> 00:00:59,230 We're here in fundamentals. 22 00:00:59,230 --> 00:01:01,489 We're approaching the end of our fundamental section, 23 00:01:01,489 --> 00:01:03,530 but we still have a few really important lectures 24 00:01:03,530 --> 00:01:04,269 to get through. 25 00:01:04,269 --> 00:01:05,519 After we get through the fundamentals, 26 00:01:05,519 --> 00:01:06,890 we'll be in a good position to understand 27 00:01:06,890 --> 00:01:08,473 the different technologies and finally 28 00:01:08,473 --> 00:01:09,880 the cross-cutting themes. 29 00:01:09,880 --> 00:01:12,020 And our goal is to, at least for the fundamentals, 30 00:01:12,020 --> 00:01:13,820 to understand solar cell conversion 31 00:01:13,820 --> 00:01:17,280 efficiency, which is the ratio of output to input energy. 32 00:01:17,280 --> 00:01:19,100 And for most solar cells, this breaks down 33 00:01:19,100 --> 00:01:21,610 to the following progression, from the solar spectrum 34 00:01:21,610 --> 00:01:22,940 to charge collection. 35 00:01:22,940 --> 00:01:25,880 And we're going to be focusing on charge separation, 36 00:01:25,880 --> 00:01:28,240 incorporating elements of either side 37 00:01:28,240 --> 00:01:30,980 but mostly focused on charge separation today. 38 00:01:30,980 --> 00:01:33,410 reminding everybody, of course, that the total system 39 00:01:33,410 --> 00:01:36,180 efficiency is the product of each individual efficiency. 40 00:01:36,180 --> 00:01:39,520 And if any one of these is low, the efficiency 41 00:01:39,520 --> 00:01:41,120 for the entire system is low. 42 00:01:41,120 --> 00:01:43,870 And since folks are tired of looking at this chart by now, 43 00:01:43,870 --> 00:01:48,690 every single lecture I intend to introduce something new that 44 00:01:48,690 --> 00:01:51,010 follows a similar pattern. 45 00:01:51,010 --> 00:01:54,930 Does anybody recognize what this is about? 46 00:01:54,930 --> 00:01:59,620 So you have over here some H2O going 47 00:01:59,620 --> 00:02:02,890 into an oxygen-evolving complex, and light is coming in, 48 00:02:02,890 --> 00:02:04,640 essentially exciting up an electron, 49 00:02:04,640 --> 00:02:06,390 which is being stored in some form of chemical energy. 50 00:02:06,390 --> 00:02:06,980 What is that? 51 00:02:06,980 --> 00:02:07,480 AUDIENCE: Photosynthesis. 52 00:02:07,480 --> 00:02:08,940 PROFESSOR: Photosynthesis, right? 53 00:02:08,940 --> 00:02:15,220 And just like a solar cell, the photosynthesis conversion 54 00:02:15,220 --> 00:02:17,060 efficiency of the entire system is 55 00:02:17,060 --> 00:02:19,550 dictated by the efficiency of each individual part. 56 00:02:19,550 --> 00:02:22,660 Roughly it can be broken down to this little pie chart up here. 57 00:02:22,660 --> 00:02:24,620 The total system efficiency in blue 58 00:02:24,620 --> 00:02:28,060 is somewhere, depending on the plant, somewhere 59 00:02:28,060 --> 00:02:31,430 around 1%, maybe as high as 7% or 8%, 60 00:02:31,430 --> 00:02:33,570 depending on very specialized plants that 61 00:02:33,570 --> 00:02:36,700 are experts at converting sunlight into usable chemical 62 00:02:36,700 --> 00:02:37,460 energy. 63 00:02:37,460 --> 00:02:40,600 And that, in part, is largely due to optical losses. 64 00:02:40,600 --> 00:02:43,610 If you can see the absorption spectrum of chlorophyll, 65 00:02:43,610 --> 00:02:45,574 of the different types of chlorophyll here, 66 00:02:45,574 --> 00:02:47,740 you'll see large portions of the solar spectrum that 67 00:02:47,740 --> 00:02:49,810 go underutilized. 68 00:02:49,810 --> 00:02:53,190 So again, another system that's similar to a solar cell, 69 00:02:53,190 --> 00:02:56,030 that the total system efficiency is 70 00:02:56,030 --> 00:02:59,680 the product of each individual component going on here. 71 00:02:59,680 --> 00:03:00,180 All right. 72 00:03:00,180 --> 00:03:02,670 So now what we're going to do is just quickly 73 00:03:02,670 --> 00:03:05,840 revisit the diode in the dark and construct the energy band 74 00:03:05,840 --> 00:03:09,030 diagram for pn-junction in the dark. 75 00:03:09,030 --> 00:03:11,670 Each of you should have on your desk these sheets. 76 00:03:11,670 --> 00:03:13,170 Oh, we don't have them on the desks. 77 00:03:13,170 --> 00:03:15,222 We need to pass those out. 78 00:03:15,222 --> 00:03:17,310 We need to pass those out. 79 00:03:17,310 --> 00:03:21,040 So we should have sheets that describe 80 00:03:21,040 --> 00:03:23,670 essentially the equivalent circuit diagram, the IV 81 00:03:23,670 --> 00:03:25,340 characteristics, and the energy band 82 00:03:25,340 --> 00:03:27,930 diagram for our pn-junction in the dark. 83 00:03:27,930 --> 00:03:30,129 We laboriously filled this out last class. 84 00:03:30,129 --> 00:03:31,670 We're just going to refresh ourselves 85 00:03:31,670 --> 00:03:33,250 to make sure we're all on the same page 86 00:03:33,250 --> 00:03:34,880 and redo it this class right at the beginning 87 00:03:34,880 --> 00:03:36,160 because it's that important. 88 00:03:36,160 --> 00:03:37,570 Thank you, thank you, thank you for those 89 00:03:37,570 --> 00:03:39,370 who came to our office hours and for those 90 00:03:39,370 --> 00:03:41,970 who came to the recitations, and we really 91 00:03:41,970 --> 00:03:43,850 tried to get this across. 92 00:03:43,850 --> 00:03:45,810 For those who are still struggling, 93 00:03:45,810 --> 00:03:48,710 let's make sure that you get this sometime between now 94 00:03:48,710 --> 00:03:50,500 and, say, the next two weeks because this 95 00:03:50,500 --> 00:03:54,090 will feature prominently on the exam, 96 00:03:54,090 --> 00:03:56,050 and it's pretty important for understanding 97 00:03:56,050 --> 00:03:57,620 how a solar cell works. 98 00:03:57,620 --> 00:04:01,350 So if you would not mind working directly with your partner, 99 00:04:01,350 --> 00:04:03,940 the person who's sitting directly next to you. 100 00:04:03,940 --> 00:04:06,287 Let's walk through the diode in the dark 101 00:04:06,287 --> 00:04:07,870 and construct the energy band diagrams 102 00:04:07,870 --> 00:04:09,211 for the diode in the dark. 103 00:04:09,211 --> 00:04:11,210 I'll walk you through it as soon as you've done. 104 00:04:11,210 --> 00:04:13,600 Maybe I'll give you three minutes to complete that. 105 00:04:13,600 --> 00:04:16,092 And then we'll progress to the diode under illumination. 106 00:04:16,092 --> 00:04:17,050 Should be a lot of fun. 107 00:04:23,730 --> 00:04:29,800 I see convergence among several of you, so let's move forward. 108 00:04:29,800 --> 00:04:32,119 Just to review quickly, the way I typically 109 00:04:32,119 --> 00:04:34,660 think about it, if we set up in the model circuit right here, 110 00:04:34,660 --> 00:04:36,100 we have our pn-junction. 111 00:04:36,100 --> 00:04:37,705 We have our space-charge region, also 112 00:04:37,705 --> 00:04:39,580 known as the quasi-neutral region, also known 113 00:04:39,580 --> 00:04:41,730 as the depletion zone. 114 00:04:41,730 --> 00:04:44,080 So we have this region right here 115 00:04:44,080 --> 00:04:47,710 that represents the space-charge region. 116 00:04:47,710 --> 00:04:49,202 So this is in the dark. 117 00:04:49,202 --> 00:04:50,660 Now we have the energy band diagram 118 00:04:50,660 --> 00:04:54,000 shown right here, where this dashed blue line represents 119 00:04:54,000 --> 00:04:57,390 the chemical potential, also called the Fermi energy, 120 00:04:57,390 --> 00:05:01,310 throughout the entire device right here in cross-section. 121 00:05:01,310 --> 00:05:03,900 And just to be very, very clear, we've 122 00:05:03,900 --> 00:05:05,470 so far described the solar cell as 123 00:05:05,470 --> 00:05:07,080 like coming in through the top. 124 00:05:07,080 --> 00:05:09,642 And now we've rotated this structure by 90 degrees 125 00:05:09,642 --> 00:05:10,850 to represent the pn-junction. 126 00:05:10,850 --> 00:05:12,766 That's been a little confusing for some folks. 127 00:05:12,766 --> 00:05:15,410 So just to be totally clear, in a device like this one, 128 00:05:15,410 --> 00:05:17,780 if it were subject to illumination 129 00:05:17,780 --> 00:05:20,020 you would have light coming in from the side, right, 130 00:05:20,020 --> 00:05:22,790 either from the p side or from the n side. 131 00:05:22,790 --> 00:05:24,520 So to transfer this into what we've 132 00:05:24,520 --> 00:05:27,270 seen so far with the solar cell devices facing up 133 00:05:27,270 --> 00:05:30,010 toward the sun, you'd have to rotate this by 90 degrees, 134 00:05:30,010 --> 00:05:30,670 right? 135 00:05:30,670 --> 00:05:32,837 Just to make sure we're all clear with orientations. 136 00:05:32,837 --> 00:05:34,919 [? Because ?] we have the Fermi energy right here. 137 00:05:34,919 --> 00:05:37,410 The drift and diffusion currents for electrons-- electron 138 00:05:37,410 --> 00:05:38,940 diffusion, electron drift-- there 139 00:05:38,940 --> 00:05:42,052 is an abundance of electrons over here in the n-type side, 140 00:05:42,052 --> 00:05:44,010 and so they want to diffuse over to the p-type. 141 00:05:44,010 --> 00:05:46,490 That's why the diffusion current is pointing left. 142 00:05:46,490 --> 00:05:47,990 Once they do to a certain degree, 143 00:05:47,990 --> 00:05:50,450 they set up a field, the electrons and holes, 144 00:05:50,450 --> 00:05:52,100 the mobile charges set up a field, 145 00:05:52,100 --> 00:05:55,377 and that creates a drift current that counteracts the diffusion. 146 00:05:55,377 --> 00:05:56,960 And once these two are in equilibrium, 147 00:05:56,960 --> 00:05:58,876 there's no current flowing through our device. 148 00:05:58,876 --> 00:06:01,244 That's why current is equal to 0 right here. 149 00:06:01,244 --> 00:06:02,910 And there's also no potential difference 150 00:06:02,910 --> 00:06:05,870 because the Fermi energy, the chemical potential, 151 00:06:05,870 --> 00:06:08,027 is the same on either side of that device, 152 00:06:08,027 --> 00:06:09,860 and so the voltage output of that solar cell 153 00:06:09,860 --> 00:06:12,650 would also be 0. 154 00:06:12,650 --> 00:06:18,164 When we forward bias our device, now we're forcing a separation, 155 00:06:18,164 --> 00:06:20,455 or we're forcing a separation of the chemical potential 156 00:06:20,455 --> 00:06:22,770 on either side of the device. 157 00:06:22,770 --> 00:06:26,130 If you connected this to an external circuit, 158 00:06:26,130 --> 00:06:29,470 the electrons would want to flow from this side to that side. 159 00:06:29,470 --> 00:06:33,320 But since we're forcing this condition here with a battery, 160 00:06:33,320 --> 00:06:36,360 we are reducing the barrier height here. 161 00:06:36,360 --> 00:06:38,380 Electrons can now diffuse over from the n-type 162 00:06:38,380 --> 00:06:40,610 into the p-type side, and they do. 163 00:06:40,610 --> 00:06:42,650 And the diffusion current increases. 164 00:06:42,650 --> 00:06:45,680 And that's why we have current now a positive value. 165 00:06:45,680 --> 00:06:49,440 We've defined the electrons traveling to the left 166 00:06:49,440 --> 00:06:51,010 as being a positive current. 167 00:06:51,010 --> 00:06:54,510 We have now electrons traveling from the n-type 168 00:06:54,510 --> 00:06:56,000 to the p-type material. 169 00:06:56,000 --> 00:06:59,114 When we reverse bias our device, notice the separation 170 00:06:59,114 --> 00:07:00,280 of the quasi-Fermi energies. 171 00:07:00,280 --> 00:07:04,130 Again, we have here one sign of voltage 172 00:07:04,130 --> 00:07:06,344 because the right side is higher than the left. 173 00:07:06,344 --> 00:07:08,260 And now the right side is lower than the left, 174 00:07:08,260 --> 00:07:10,490 so our voltage sign flips from right 175 00:07:10,490 --> 00:07:13,210 to left over here from positive to negative values. 176 00:07:13,210 --> 00:07:14,290 So notice the voltage. 177 00:07:14,290 --> 00:07:15,830 And now the current as well. 178 00:07:15,830 --> 00:07:19,220 The drift current will outweigh the diffusion current 179 00:07:19,220 --> 00:07:23,442 in this particular case because now the barrier for electrons 180 00:07:23,442 --> 00:07:24,900 to diffuse from the n to the p-type 181 00:07:24,900 --> 00:07:27,790 is very large they'll have difficulty going from that side 182 00:07:27,790 --> 00:07:28,820 to that side. 183 00:07:28,820 --> 00:07:31,590 Whereas the drift current is larger because 184 00:07:31,590 --> 00:07:33,450 of the larger electric field. 185 00:07:33,450 --> 00:07:35,806 And as a result, the drift current will dominate. 186 00:07:35,806 --> 00:07:37,430 And so now instead of electrons flowing 187 00:07:37,430 --> 00:07:39,900 from n-type to p-type, where we had defined 188 00:07:39,900 --> 00:07:42,260 as positive current, electrons are flowing from p-type 189 00:07:42,260 --> 00:07:45,340 to n-type in that, which we defined as negative current. 190 00:07:45,340 --> 00:07:47,930 And that's why our current has changed signs. 191 00:07:47,930 --> 00:07:50,560 Over here, notice that we're in positive current territory, 192 00:07:50,560 --> 00:07:53,957 and over here, notice we're in negative current territory. 193 00:07:53,957 --> 00:07:56,290 Also, you'll notice the width of the space-charge region 194 00:07:56,290 --> 00:07:59,130 changing as we forward and reverse bias our device. 195 00:07:59,130 --> 00:08:01,530 As the barrier height decreases, we 196 00:08:01,530 --> 00:08:03,530 have a decrease of the built-in electric field. 197 00:08:03,530 --> 00:08:05,280 We have a decrease of the amount of charge 198 00:08:05,280 --> 00:08:06,800 on either side of the junction. 199 00:08:06,800 --> 00:08:09,140 That's why the depletion width decreases. 200 00:08:09,140 --> 00:08:13,640 And the opposite happens here under reverse bias. 201 00:08:13,640 --> 00:08:17,690 So getting to the point where you can set up a pn-junction 202 00:08:17,690 --> 00:08:20,350 and understand how drift and diffusion currents come 203 00:08:20,350 --> 00:08:21,970 into being in the first place and then 204 00:08:21,970 --> 00:08:25,700 being able to bias your diode under different conditions 205 00:08:25,700 --> 00:08:28,240 is a really important fundamental skill 206 00:08:28,240 --> 00:08:30,280 for understanding how a solar cell works. 207 00:08:30,280 --> 00:08:30,793 Question. 208 00:08:30,793 --> 00:08:32,542 AUDIENCE: On the forward and reverse bias, 209 00:08:32,542 --> 00:08:34,434 does the Fermi energy actually continuous, 210 00:08:34,434 --> 00:08:36,799 or does it actually [INAUDIBLE]? 211 00:08:36,799 --> 00:08:40,965 PROFESSOR: So the Fermi energy, which we defined here 212 00:08:40,965 --> 00:08:42,482 as the chemical potential, notice 213 00:08:42,482 --> 00:08:43,940 we're avoiding talking about what's 214 00:08:43,940 --> 00:08:46,231 happening here in the middle until a couple of lectures 215 00:08:46,231 --> 00:08:46,910 from now. 216 00:08:46,910 --> 00:08:49,650 That gets into a gray zone where we talk 217 00:08:49,650 --> 00:08:51,051 about quasi-Fermi energies. 218 00:08:51,051 --> 00:08:53,550 We'll get to that in a minute or maybe a couple of lectures. 219 00:08:53,550 --> 00:08:57,057 But yes, the Fermi energy in the extreme sides right here 220 00:08:57,057 --> 00:08:58,473 near the contacts, so your contact 221 00:08:58,473 --> 00:09:00,806 in your device over here and your contact in your device 222 00:09:00,806 --> 00:09:02,290 over here, those Fermi energies are 223 00:09:02,290 --> 00:09:05,370 different on an absolute energy scale. 224 00:09:05,370 --> 00:09:07,547 So there is an energy difference when 225 00:09:07,547 --> 00:09:09,880 you're driving the electrons from one side to the other. 226 00:09:12,780 --> 00:09:14,651 Notice in this case right here, you 227 00:09:14,651 --> 00:09:16,150 would think that the electrons would 228 00:09:16,150 --> 00:09:18,120 want to travel through an external circuit 229 00:09:18,120 --> 00:09:20,411 to come back to this side because their energy's higher 230 00:09:20,411 --> 00:09:22,240 in this side and lower over here. 231 00:09:22,240 --> 00:09:25,700 But we're not illuminating the solar cell yet. 232 00:09:25,700 --> 00:09:27,950 We're biasing it using a battery. 233 00:09:27,950 --> 00:09:30,515 And this is why we have current flow coming from this side 234 00:09:30,515 --> 00:09:31,140 into that side. 235 00:09:31,140 --> 00:09:33,870 We're essentially forcing the electrons from the n-type 236 00:09:33,870 --> 00:09:35,390 into the p-type material. 237 00:09:35,390 --> 00:09:37,490 We're pushing them up that hill with a battery. 238 00:09:37,490 --> 00:09:41,020 And that's why we have this diffusion current dominating 239 00:09:41,020 --> 00:09:43,180 in the dark, in the dark. 240 00:09:43,180 --> 00:09:47,160 So we have a current flowing from right to left. 241 00:09:47,160 --> 00:09:49,150 In the illuminated case, we'll have 242 00:09:49,150 --> 00:09:52,630 all of our carriers traveling from left to right. 243 00:09:52,630 --> 00:09:54,330 And in the dark, this is the only case 244 00:09:54,330 --> 00:09:57,040 in which we have carriers traveling from right to left. 245 00:09:57,040 --> 00:10:00,050 And it's happening because we're using that battery in the dark 246 00:10:00,050 --> 00:10:03,300 to change the chemical potential on either side, which, 247 00:10:03,300 --> 00:10:05,320 in effect, reduces this barrier height 248 00:10:05,320 --> 00:10:08,940 and allows carriers to diffuse from the n-type into p-type. 249 00:10:08,940 --> 00:10:11,390 So you can think about it as forcing carriers 250 00:10:11,390 --> 00:10:13,640 up the junction. 251 00:10:13,640 --> 00:10:15,232 And this is a very useful technique 252 00:10:15,232 --> 00:10:17,440 because, in effect, what it's doing in a real device, 253 00:10:17,440 --> 00:10:19,148 when we you have a two-dimensional device 254 00:10:19,148 --> 00:10:21,020 within homogeneities, the current 255 00:10:21,020 --> 00:10:24,150 will travel through the weakest point of that pn-junction. 256 00:10:24,150 --> 00:10:26,230 Wherever the barrier height is lowest, current 257 00:10:26,230 --> 00:10:28,260 will begin crowding through that spot. 258 00:10:28,260 --> 00:10:30,800 And so it's a way of probing or testing 259 00:10:30,800 --> 00:10:35,311 the quality of your junction characteristic in the dark. 260 00:10:35,311 --> 00:10:35,810 OK. 261 00:10:35,810 --> 00:10:40,870 So this is the basics of pn-junction in the dark. 262 00:10:40,870 --> 00:10:43,350 Let's flip our page over and now let's 263 00:10:43,350 --> 00:10:47,550 try to imagine what will happen under illuminated conditions, 264 00:10:47,550 --> 00:10:50,270 and let's start out in a very simple case. 265 00:10:50,270 --> 00:10:52,830 We'll assume that the principle of superposition 266 00:10:52,830 --> 00:10:55,815 applies here, that the photo-excited carriers-- 267 00:10:55,815 --> 00:10:57,940 in other words, when light shines into our device-- 268 00:10:57,940 --> 00:11:00,420 I'm looking at this one right now or this one right here-- 269 00:11:00,420 --> 00:11:03,830 and light's coming in and generating electron-hole pairs, 270 00:11:03,830 --> 00:11:06,180 essentially exciting electrons across the band gap 271 00:11:06,180 --> 00:11:09,810 like we described in lecture 3, so we have carriers now being 272 00:11:09,810 --> 00:11:11,520 excited across the band gap, what 273 00:11:11,520 --> 00:11:13,060 will happen to those electrons now 274 00:11:13,060 --> 00:11:14,559 that they're in the conduction band? 275 00:11:14,559 --> 00:11:16,362 Where will they want to go? 276 00:11:16,362 --> 00:11:17,320 AUDIENCE: To the right. 277 00:11:17,320 --> 00:11:18,450 PROFESSOR: To the right, right? 278 00:11:18,450 --> 00:11:18,950 OK. 279 00:11:18,950 --> 00:11:21,089 So what you'll do is set up what's 280 00:11:21,089 --> 00:11:22,380 called an illumination current. 281 00:11:22,380 --> 00:11:26,250 Notice now at the bottom of the second row here, 282 00:11:26,250 --> 00:11:29,020 you have electron diffusion, electron drift, and IL current. 283 00:11:29,020 --> 00:11:30,992 IL stands for illumination current. 284 00:11:30,992 --> 00:11:32,450 So you have a third arrow here that 285 00:11:32,450 --> 00:11:35,390 will have to be implemented in some way. 286 00:11:35,390 --> 00:11:38,720 And that will-- by the principle of superposition 287 00:11:38,720 --> 00:11:41,145 you should think what happens to your IV curve as well. 288 00:11:41,145 --> 00:11:43,520 So let's make an estimate of what we think should happen, 289 00:11:43,520 --> 00:11:45,228 and then I'll confer some notes, and then 290 00:11:45,228 --> 00:11:48,334 we'll measure what actually does happen under illumination. 291 00:11:48,334 --> 00:11:49,500 Why don't we give it a shot? 292 00:11:54,980 --> 00:11:56,550 What does forward and reverse bias 293 00:11:56,550 --> 00:11:58,690 mean when there's no battery? 294 00:11:58,690 --> 00:12:00,360 This is a very interesting question. 295 00:12:00,360 --> 00:12:03,390 So once you start illuminating your solar cell device 296 00:12:03,390 --> 00:12:08,900 and you start injecting carriers into it, what will happen is, 297 00:12:08,900 --> 00:12:11,429 very naturally, this band alignment 298 00:12:11,429 --> 00:12:13,220 that you see right here, this band diagram, 299 00:12:13,220 --> 00:12:16,820 will begin to shift toward the forward bias condition. 300 00:12:16,820 --> 00:12:17,530 Rationale? 301 00:12:17,530 --> 00:12:18,780 You'll be generating carriers. 302 00:12:18,780 --> 00:12:20,570 They'll be swept over into this region here. 303 00:12:20,570 --> 00:12:21,860 One way to think about is that you'll 304 00:12:21,860 --> 00:12:23,969 be increasing the number of electrons over here 305 00:12:23,969 --> 00:12:26,260 and the number of holes over here, which will naturally 306 00:12:26,260 --> 00:12:28,430 cause the energy of those electrons 307 00:12:28,430 --> 00:12:30,430 to increase on this side, the chemical potential 308 00:12:30,430 --> 00:12:31,910 on this side, to increase. 309 00:12:31,910 --> 00:12:33,660 So one way to think about it is, as you're 310 00:12:33,660 --> 00:12:36,580 illuminating your solar cell more and more and more, 311 00:12:36,580 --> 00:12:40,280 you're forcing a forward bias condition on your device. 312 00:12:40,280 --> 00:12:42,430 To get the solar cell to go into reverse bias, 313 00:12:42,430 --> 00:12:44,390 you really do need to bias your device. 314 00:12:44,390 --> 00:12:45,710 You physically need to bias it. 315 00:12:53,590 --> 00:12:54,090 Yeah. 316 00:12:54,090 --> 00:12:56,324 So when I mentioned illumination current here, 317 00:12:56,324 --> 00:12:58,490 we're really talking about the electron illumination 318 00:12:58,490 --> 00:13:01,100 current, right, what direction of travel 319 00:13:01,100 --> 00:13:03,270 the electrons are taking inside of our system. 320 00:13:03,270 --> 00:13:06,930 So yes, the electrons would be traveling from left to right. 321 00:13:06,930 --> 00:13:09,500 Very astute observation. 322 00:13:09,500 --> 00:13:12,210 Current is generally described as a flow of positive charge. 323 00:13:12,210 --> 00:13:18,200 And in the absence of a definer or, say, electrons or holes, 324 00:13:18,200 --> 00:13:19,952 you rightly could assume that it would be 325 00:13:19,952 --> 00:13:21,160 the flow of positive charges. 326 00:13:21,160 --> 00:13:22,766 We're assuming electrons are flowing here 327 00:13:22,766 --> 00:13:23,974 in the illumination. current. 328 00:13:27,360 --> 00:13:28,420 Good. 329 00:13:28,420 --> 00:13:28,920 All right. 330 00:13:28,920 --> 00:13:31,170 So This is very positive. 331 00:13:31,170 --> 00:13:35,410 I see everybody has settled on the notion 332 00:13:35,410 --> 00:13:38,990 that illumination will shift our IV curve down. 333 00:13:38,990 --> 00:13:41,660 Because of the way we've defined current, 334 00:13:41,660 --> 00:13:45,450 that if current flows from left to right that lands us 335 00:13:45,450 --> 00:13:47,260 in negative current territory. 336 00:13:47,260 --> 00:13:48,520 So that makes sense. 337 00:13:48,520 --> 00:13:50,850 If we shine light on our system, we 338 00:13:50,850 --> 00:13:53,365 have electrons flowing from left to right here. 339 00:13:53,365 --> 00:13:54,990 That'll put us into negative territory. 340 00:13:54,990 --> 00:13:56,820 So that shifts the entire thing down. 341 00:13:56,820 --> 00:14:00,160 And we would add illumination current, an arrow pointing 342 00:14:00,160 --> 00:14:02,010 to the right right here, which would 343 00:14:02,010 --> 00:14:05,410 mean that we would have current flowing through our device, 344 00:14:05,410 --> 00:14:08,615 but there's still no difference in the chemical potential 345 00:14:08,615 --> 00:14:09,310 on either side. 346 00:14:09,310 --> 00:14:11,060 There's still a difference in Fermi energy 347 00:14:11,060 --> 00:14:12,518 in the p-type and the n-type, which 348 00:14:12,518 --> 00:14:16,670 means our voltage is equal to 0, which means we're intersecting 349 00:14:16,670 --> 00:14:18,840 the y-axis right here, and our little x 350 00:14:18,840 --> 00:14:20,870 should be marked right down here. 351 00:14:20,870 --> 00:14:23,350 So it's really just a superposition. 352 00:14:23,350 --> 00:14:24,210 Great. 353 00:14:24,210 --> 00:14:24,800 OK. 354 00:14:24,800 --> 00:14:31,610 Now what happens if we forward bias our device either 355 00:14:31,610 --> 00:14:36,214 because we're adding a resistor in series to our solar cell? 356 00:14:36,214 --> 00:14:37,630 So instead of a battery there, you 357 00:14:37,630 --> 00:14:40,300 would replace that with a resistor. 358 00:14:40,300 --> 00:14:43,280 Or if we're applying a bias voltage as well, 359 00:14:43,280 --> 00:14:45,255 we could also do that under illumination. 360 00:14:45,255 --> 00:14:47,380 So we'd still have the illumination current, right? 361 00:14:47,380 --> 00:14:50,590 And we, through superposition, shift this entire curve down, 362 00:14:50,590 --> 00:14:54,200 we'd be operating somewhere in this quadrant right there, 363 00:14:54,200 --> 00:14:55,090 right? 364 00:14:55,090 --> 00:14:58,990 So this we call IV quadrant, typically I, II, III, IV, IV 365 00:14:58,990 --> 00:14:59,790 quadrant. 366 00:14:59,790 --> 00:15:02,720 This is where power is coming out of the solar cell device. 367 00:15:02,720 --> 00:15:05,053 Because if we imagine instead of having a battery there, 368 00:15:05,053 --> 00:15:06,960 we have a resistor, the electrons 369 00:15:06,960 --> 00:15:08,850 will travel from the n-type material 370 00:15:08,850 --> 00:15:11,816 through that external load to get work the p-type material 371 00:15:11,816 --> 00:15:13,690 where the chemical potential is lower, right, 372 00:15:13,690 --> 00:15:17,010 because they'll desire to minimize their free energy. 373 00:15:17,010 --> 00:15:19,550 And as a result, they'll deposit that power 374 00:15:19,550 --> 00:15:22,215 across that resistor, across that external load, 375 00:15:22,215 --> 00:15:23,840 in order to get back to this other side 376 00:15:23,840 --> 00:15:26,821 because that's the only path that they can travel easily, 377 00:15:26,821 --> 00:15:27,320 right? 378 00:15:27,320 --> 00:15:29,170 And so this entire curve shifts down. 379 00:15:29,170 --> 00:15:32,030 You have your red x somewhere in the quadrant over here. 380 00:15:32,030 --> 00:15:35,840 And power is flowing out of the solar cell 381 00:15:35,840 --> 00:15:37,590 across that external load. 382 00:15:37,590 --> 00:15:39,500 So in the next slide, pretty much everything 383 00:15:39,500 --> 00:15:41,754 is right, except that, mea culpa, 384 00:15:41,754 --> 00:15:43,420 I forgot to replace the battery up there 385 00:15:43,420 --> 00:15:44,420 with a little resistor. 386 00:15:44,420 --> 00:15:46,170 So you'll want to correct that in your notes. 387 00:15:46,170 --> 00:15:48,190 Instead of having the little batteries up there, 388 00:15:48,190 --> 00:15:50,800 you can replace those with resistors 389 00:15:50,800 --> 00:15:55,360 or a resistor in series with a battery, if you prefer. 390 00:15:55,360 --> 00:15:57,840 Since depending on the illumination condition, 391 00:15:57,840 --> 00:16:00,290 the intensity we may have natural for a bias condition, 392 00:16:00,290 --> 00:16:02,101 we may need to apply a bias voltage. 393 00:16:02,101 --> 00:16:02,600 OK. 394 00:16:02,600 --> 00:16:05,200 So we have our IV characteristic like this. 395 00:16:05,200 --> 00:16:07,750 We have our red x under forward bias conditions 396 00:16:07,750 --> 00:16:10,310 in the IV quadrant, denoting that power 397 00:16:10,310 --> 00:16:12,690 would be flowing out of this solar cell device 398 00:16:12,690 --> 00:16:14,480 under these conditions. 399 00:16:14,480 --> 00:16:17,420 And now the bias is inverted. 400 00:16:17,420 --> 00:16:19,230 We have reverse bias conditions. 401 00:16:19,230 --> 00:16:22,760 And notice that the current still has the same sign. 402 00:16:22,760 --> 00:16:25,440 So the current is negative here, negative here, 403 00:16:25,440 --> 00:16:26,300 and negative here. 404 00:16:26,300 --> 00:16:30,070 So the net current is always flowing in the same direction 405 00:16:30,070 --> 00:16:33,190 in all cases because we have this illumination current, 406 00:16:33,190 --> 00:16:35,290 because we have this generation of carriers 407 00:16:35,290 --> 00:16:36,860 inside of the material. 408 00:16:36,860 --> 00:16:37,990 That's pretty cool. 409 00:16:37,990 --> 00:16:41,250 That wasn't the case when we had the device in the dark. 410 00:16:41,250 --> 00:16:43,740 Here, in the forward bias conditions, 411 00:16:43,740 --> 00:16:46,690 we're actually forcing carriers from the n-type material 412 00:16:46,690 --> 00:16:48,930 into the p-type material. 413 00:16:48,930 --> 00:16:51,060 But under illumination, now we have 414 00:16:51,060 --> 00:16:53,650 all of our carriers traveling from the p-type 415 00:16:53,650 --> 00:16:55,100 into the n-type. 416 00:16:55,100 --> 00:16:59,270 What's varying is the potential that the carriers have 417 00:16:59,270 --> 00:17:01,140 and, of course, the total amount of current. 418 00:17:01,140 --> 00:17:03,940 As you forward bias more and more and more, 419 00:17:03,940 --> 00:17:08,170 this downhill slope here decreases, right? 420 00:17:08,170 --> 00:17:11,200 So there's less of a driving force for the carriers 421 00:17:11,200 --> 00:17:13,410 to be going from the p-type to the n-type, 422 00:17:13,410 --> 00:17:16,400 and that's why the current approaches 0. 423 00:17:16,400 --> 00:17:18,859 Eventually at some point, if you keep forward biasing here, 424 00:17:18,859 --> 00:17:20,500 the current will be 0. 425 00:17:20,500 --> 00:17:22,740 There will be no net current flow 426 00:17:22,740 --> 00:17:25,357 because there will be no driving force for the carriers 427 00:17:25,357 --> 00:17:26,940 to go from the p-type into the n-type. 428 00:17:26,940 --> 00:17:31,110 There will be no more built-in field. 429 00:17:31,110 --> 00:17:31,870 Kind of cool. 430 00:17:31,870 --> 00:17:32,570 OK. 431 00:17:32,570 --> 00:17:35,950 So now we're beginning to wrap our heads around what's 432 00:17:35,950 --> 00:17:37,450 happening to the electrons and holes 433 00:17:37,450 --> 00:17:40,530 during solar cell operation. 434 00:17:40,530 --> 00:17:43,490 Let me put a little bit of mathematics to this. 435 00:17:43,490 --> 00:17:45,220 These are your IV curves. 436 00:17:45,220 --> 00:17:48,730 The blue is in the dark, and the red is under illumination. 437 00:17:48,730 --> 00:17:50,915 And we're focused on this IV quadrant 438 00:17:50,915 --> 00:17:53,165 right here because this is the quadrant in which power 439 00:17:53,165 --> 00:17:55,070 is coming out of our solar cell device, 440 00:17:55,070 --> 00:17:56,880 which usable power is coming out that we 441 00:17:56,880 --> 00:17:58,160 can power an external load. 442 00:17:58,160 --> 00:17:59,360 Why? 443 00:17:59,360 --> 00:18:02,520 Well, first off, the voltage is such 444 00:18:02,520 --> 00:18:03,979 that we can power an external load. 445 00:18:03,979 --> 00:18:05,061 We have charge separation. 446 00:18:05,061 --> 00:18:06,790 The electrons are accumulated over here. 447 00:18:06,790 --> 00:18:08,456 And they have higher potential than they 448 00:18:08,456 --> 00:18:10,490 do on the other side, which means that there's 449 00:18:10,490 --> 00:18:12,865 an incentive for them to go through the external circuit, 450 00:18:12,865 --> 00:18:15,780 deposit the power across that external load 451 00:18:15,780 --> 00:18:18,670 to get back to this other side where their potential is lower, 452 00:18:18,670 --> 00:18:19,170 right? 453 00:18:19,170 --> 00:18:20,560 So the voltage is favorable. 454 00:18:20,560 --> 00:18:22,000 And the current is also favorable 455 00:18:22,000 --> 00:18:23,670 because now we have light coming in. 456 00:18:23,670 --> 00:18:27,732 And this generation current is driving the carriers-- well, 457 00:18:27,732 --> 00:18:29,690 or is creating carriers here in the p-type that 458 00:18:29,690 --> 00:18:31,523 can then be driven toward the n-type because 459 00:18:31,523 --> 00:18:33,260 of the built-in field. 460 00:18:33,260 --> 00:18:36,480 So the conditions are just right under illuminated forward bias 461 00:18:36,480 --> 00:18:40,310 conditions to drive power through our external load. 462 00:18:40,310 --> 00:18:42,910 Under all other conditions of operations of the solar cell, 463 00:18:42,910 --> 00:18:45,970 we're putting power into the device, not getting power out 464 00:18:45,970 --> 00:18:46,990 of it. 465 00:18:46,990 --> 00:18:49,700 This IV quadrant over here, this forward bias 466 00:18:49,700 --> 00:18:52,670 illuminated case is the only case in which power is coming, 467 00:18:52,670 --> 00:18:57,190 usable power is coming out of our solar cell that we can use. 468 00:18:57,190 --> 00:19:00,440 So that's why we focus on this IV quadrant right here. 469 00:19:00,440 --> 00:19:04,340 The illuminated IV curve is, to the first order, 470 00:19:04,340 --> 00:19:07,860 is just your dark IV curve with a superposition, which 471 00:19:07,860 --> 00:19:11,380 we call the illumination current, I sub L. 472 00:19:11,380 --> 00:19:14,980 And that's what shifts our entire curve down by this I sub 473 00:19:14,980 --> 00:19:19,380 L right here, so this I sub L, that one right there or that 474 00:19:19,380 --> 00:19:22,220 right there. 475 00:19:22,220 --> 00:19:23,730 Kind of cool. 476 00:19:23,730 --> 00:19:24,870 All right. 477 00:19:24,870 --> 00:19:28,450 What do we think will happen if our light intensity goes down 478 00:19:28,450 --> 00:19:29,410 by a factor of 2? 479 00:19:31,970 --> 00:19:34,870 So now if the amount of sunlight falling on our solar cell 480 00:19:34,870 --> 00:19:37,860 drops by 1/2, what will happen? 481 00:19:37,860 --> 00:19:40,526 What do we predict will happen based on this right here? 482 00:19:40,526 --> 00:19:41,810 AUDIENCE: [INAUDIBLE]. 483 00:19:41,810 --> 00:19:45,010 PROFESSOR: The curve will shift, the red curve will shift up 484 00:19:45,010 --> 00:19:47,660 by about 1/2, right, because the illumination current is now 485 00:19:47,660 --> 00:19:49,610 cut in half. 486 00:19:49,610 --> 00:19:54,000 What will happen to the voltage intersect right here? 487 00:19:54,000 --> 00:19:57,480 What is the relation between voltage and current? 488 00:19:57,480 --> 00:19:59,260 It's the logarithmic relation, right? 489 00:19:59,260 --> 00:20:03,590 So it won't necessarily be cut in half, right? 490 00:20:03,590 --> 00:20:08,450 But it'll be cut by whatever this would be here, a log of 2. 491 00:20:08,450 --> 00:20:10,230 So OK. 492 00:20:10,230 --> 00:20:14,340 So we're beginning to develop an intuitive understanding 493 00:20:14,340 --> 00:20:15,950 of where electrons are flowing inside 494 00:20:15,950 --> 00:20:19,420 of our solar cells in the dark and under illumination. 495 00:20:19,420 --> 00:20:20,950 In the dark is important because we 496 00:20:20,950 --> 00:20:22,740 can test our devices in the dark, 497 00:20:22,740 --> 00:20:25,200 and we can still learn a lot about our solar cell device 498 00:20:25,200 --> 00:20:27,070 characteristics in the dark. 499 00:20:27,070 --> 00:20:31,000 As well, we can, under forward bias conditions in the dark, 500 00:20:31,000 --> 00:20:34,460 we can force carriers from one side of the junction 501 00:20:34,460 --> 00:20:37,416 to the other the wrong way and probe for weaknesses 502 00:20:37,416 --> 00:20:38,540 in the pn-junction regions. 503 00:20:38,540 --> 00:20:40,660 That's helpful. 504 00:20:40,660 --> 00:20:42,480 And in the illumination condition, 505 00:20:42,480 --> 00:20:44,820 obviously we're testing the total amount of power that's 506 00:20:44,820 --> 00:20:46,570 coming out of our device. 507 00:20:46,570 --> 00:20:48,354 So again, this is very useful because It's 508 00:20:48,354 --> 00:20:49,770 off of this red curve here that we 509 00:20:49,770 --> 00:20:53,222 defined the efficiency or the performance of the solar cell. 510 00:20:53,222 --> 00:20:55,170 So what I'll ask folks to do now is 511 00:20:55,170 --> 00:21:00,860 to-- we'll begin passing around these little tools. 512 00:21:00,860 --> 00:21:02,440 And I'll ask David Berney Needleman 513 00:21:02,440 --> 00:21:03,630 to come up to the front. 514 00:21:03,630 --> 00:21:05,230 David is our lab guru. 515 00:21:05,230 --> 00:21:07,180 He's the one who helped build these, 516 00:21:07,180 --> 00:21:09,650 really was the driving force behind getting them built. 517 00:21:09,650 --> 00:21:11,777 These are IV testers that will allow 518 00:21:11,777 --> 00:21:13,860 you to measure the current voltage characteristics 519 00:21:13,860 --> 00:21:16,600 of solar cells right here in class. 520 00:21:16,600 --> 00:21:18,937 And he's going to-- well, we'll pass them out 521 00:21:18,937 --> 00:21:20,520 while maybe he comes to the front here 522 00:21:20,520 --> 00:21:21,645 and explains how they work. 523 00:21:27,650 --> 00:21:31,000 So now that we have the basic IV curves rolling in, 524 00:21:31,000 --> 00:21:34,050 what I'd like you to do is modify the height 525 00:21:34,050 --> 00:21:35,330 or the intensity of the light. 526 00:21:35,330 --> 00:21:37,496 And the easiest way to modify the intensity of light 527 00:21:37,496 --> 00:21:40,600 is to move the light position up and down. 528 00:21:40,600 --> 00:21:43,120 So modify the intensity of the light 529 00:21:43,120 --> 00:21:45,730 and see how this IV curve changes. 530 00:21:45,730 --> 00:21:49,650 Note the y-axis scale, which might change as well. 531 00:21:49,650 --> 00:21:52,110 It might rescale depending on the condition. 532 00:21:52,110 --> 00:21:53,730 But note the y-axis scale and see 533 00:21:53,730 --> 00:21:59,000 how the intercept of the y-axis is changing 534 00:21:59,000 --> 00:22:00,682 with illumination intensity. 535 00:22:00,682 --> 00:22:01,390 Give that a shot. 536 00:22:08,640 --> 00:22:11,380 All right, folks. 537 00:22:11,380 --> 00:22:13,680 Why don't we circle back real quick. 538 00:22:13,680 --> 00:22:15,180 This has been a good experiment. 539 00:22:15,180 --> 00:22:19,230 I am very much in favor of multitasking and browsing. 540 00:22:19,230 --> 00:22:21,459 So if you want to keep your experiment running over 541 00:22:21,459 --> 00:22:23,250 the course of the remainder of the lecture, 542 00:22:23,250 --> 00:22:24,791 I will certainly have nothing opposed 543 00:22:24,791 --> 00:22:27,101 to testing a few different illumination conditions. 544 00:22:27,101 --> 00:22:29,100 And if there's anything really, really important 545 00:22:29,100 --> 00:22:31,558 I'm going to emphasize, this is a really important wake-up, 546 00:22:31,558 --> 00:22:32,740 folks. 547 00:22:32,740 --> 00:22:34,870 The I sub L, just to really recap here, 548 00:22:34,870 --> 00:22:36,560 we have this ideal diode equation, 549 00:22:36,560 --> 00:22:39,450 the illumination current coming in from our light source. 550 00:22:39,450 --> 00:22:41,850 And in our little set-up, how many batteries 551 00:22:41,850 --> 00:22:42,995 did you see there? 552 00:22:42,995 --> 00:22:43,892 AUDIENCE: One. 553 00:22:43,892 --> 00:22:44,850 PROFESSOR: Look closer. 554 00:22:44,850 --> 00:22:47,239 How many batteries do you see total in our set-up? 555 00:22:47,239 --> 00:22:48,780 Look especially at that light source. 556 00:22:48,780 --> 00:22:49,571 Two of them, right? 557 00:22:49,571 --> 00:22:51,930 There's a 9-volt and a 1.5-volt. All right. 558 00:22:51,930 --> 00:22:54,290 So one of them is powering the light source. 559 00:22:54,290 --> 00:22:58,860 And we have, as well, bias to the solar cell device, right? 560 00:22:58,860 --> 00:23:02,380 So we have a bit of a combination of the last two 561 00:23:02,380 --> 00:23:03,060 slides, right? 562 00:23:03,060 --> 00:23:06,830 In this case, in the dark, we were biasing our solar cell 563 00:23:06,830 --> 00:23:07,920 using the battery. 564 00:23:07,920 --> 00:23:10,220 And in the illumination conditions, the light 565 00:23:10,220 --> 00:23:12,860 itself was causing the solar cell to become forward biased. 566 00:23:12,860 --> 00:23:16,629 But we can add a battery to sweep the bias 567 00:23:16,629 --> 00:23:17,920 condition of the device, right? 568 00:23:17,920 --> 00:23:20,530 So even though we have a natural biasing of the solar cell 569 00:23:20,530 --> 00:23:23,080 by the light, we can force the solar cell 570 00:23:23,080 --> 00:23:25,462 under different operating conditions with the battery. 571 00:23:25,462 --> 00:23:27,670 And so that's effectively what's happening right here 572 00:23:27,670 --> 00:23:31,175 is you have a combination of both simple scenarios 573 00:23:31,175 --> 00:23:33,720 that we just looked at, and we're 574 00:23:33,720 --> 00:23:36,400 building on those components to really understand 575 00:23:36,400 --> 00:23:38,520 the larger system. 576 00:23:38,520 --> 00:23:41,550 Why might that be important, or why might that be realistic? 577 00:23:41,550 --> 00:23:44,450 Well, the light itself is biasing 578 00:23:44,450 --> 00:23:46,180 that particular solar cell device. 579 00:23:46,180 --> 00:23:47,940 But that solar cell might be connected 580 00:23:47,940 --> 00:23:51,755 in series with a bunch of other solar cells in a module, right? 581 00:23:51,755 --> 00:23:53,130 And those other solar cells might 582 00:23:53,130 --> 00:23:55,370 be biasing that one solar cell. 583 00:23:55,370 --> 00:23:59,530 So that's why we have to think about the solar cell device 584 00:23:59,530 --> 00:24:02,700 both from the perspective of what bias condition is it 585 00:24:02,700 --> 00:24:05,220 under, what illumination is it under, 586 00:24:05,220 --> 00:24:06,970 and of course, what's happening around it. 587 00:24:06,970 --> 00:24:08,990 Is it just powering an external load? 588 00:24:08,990 --> 00:24:10,970 Is there a battery connected in series to it? 589 00:24:10,970 --> 00:24:13,550 Are there other solar cells connected in series with it? 590 00:24:13,550 --> 00:24:14,270 OK. 591 00:24:14,270 --> 00:24:14,780 Yes, Ashley? 592 00:24:14,780 --> 00:24:19,920 AUDIENCE: So I don't understand still why having a load 593 00:24:19,920 --> 00:24:23,730 would bias the device. 594 00:24:23,730 --> 00:24:26,450 PROFESSOR: So let's imagine under illumination conditions 595 00:24:26,450 --> 00:24:28,280 right here, what I'm going to do very, 596 00:24:28,280 --> 00:24:33,700 very quickly is replace this battery manually in my slides, 597 00:24:33,700 --> 00:24:37,460 if PowerPoint auto save will allow me, with a resistor. 598 00:24:37,460 --> 00:24:41,680 So if you'll excuse my quick introduction here 599 00:24:41,680 --> 00:24:43,550 of the resistor. 600 00:24:43,550 --> 00:24:48,380 Now, sorry about the little artistic license. 601 00:24:48,380 --> 00:24:48,880 OK. 602 00:24:48,880 --> 00:24:50,400 So now I have my resistor here. 603 00:24:50,400 --> 00:24:53,780 And my illumination is coming into the device 604 00:24:53,780 --> 00:24:56,880 from-- say one of the sides is generating electron-hole pairs. 605 00:24:56,880 --> 00:24:59,260 I have a multiplicity of electrons that have now 606 00:24:59,260 --> 00:25:01,282 gone down the hill, right? 607 00:25:01,282 --> 00:25:03,490 It's more energetically favorable for these electrons 608 00:25:03,490 --> 00:25:04,630 to be on the other side. 609 00:25:04,630 --> 00:25:05,588 And what has that done? 610 00:25:05,588 --> 00:25:07,610 It's raised the chemical potential of this side. 611 00:25:07,610 --> 00:25:10,616 It's difficult for them to get back the other way. 612 00:25:10,616 --> 00:25:11,990 It's not impossible, but it could 613 00:25:11,990 --> 00:25:14,620 be more easy for them to flow through an external circuit 614 00:25:14,620 --> 00:25:16,032 to get back to the other side. 615 00:25:16,032 --> 00:25:17,990 And as they flow through that external circuit, 616 00:25:17,990 --> 00:25:20,620 they're depositing their energy across that external circuit. 617 00:25:20,620 --> 00:25:21,670 What energy? 618 00:25:21,670 --> 00:25:24,100 Well, it's the potential difference 619 00:25:24,100 --> 00:25:27,460 from this side to that side. 620 00:25:27,460 --> 00:25:30,470 So that's why the solar cell can be thought of, as 621 00:25:30,470 --> 00:25:32,650 in forward bias conditions, under illumination 622 00:25:32,650 --> 00:25:34,500 with an external load attached to it. 623 00:25:34,500 --> 00:25:38,110 Of course, the load has to be well-matched to the output 624 00:25:38,110 --> 00:25:39,176 of the solar cell device. 625 00:25:39,176 --> 00:25:41,675 AUDIENCE: And is the biasing because there is a voltage drop 626 00:25:41,675 --> 00:25:42,805 across the resistor? 627 00:25:42,805 --> 00:25:43,430 PROFESSOR: Yes. 628 00:25:43,430 --> 00:25:45,550 The biasing is because you have a shift 629 00:25:45,550 --> 00:25:48,970 in the chemical potential of this side up relative to-- you 630 00:25:48,970 --> 00:25:51,797 have a shift of the n-type side higher than the p-type side. 631 00:25:51,797 --> 00:25:52,380 That's a bias. 632 00:25:52,380 --> 00:25:55,170 Anytime you have a difference in the chemical potential 633 00:25:55,170 --> 00:25:57,930 in one terminal versus the other terminal of your solar cell, 634 00:25:57,930 --> 00:25:58,774 you have a bias. 635 00:25:58,774 --> 00:26:00,190 Whether that's generated by light, 636 00:26:00,190 --> 00:26:02,260 whether it's generated by a battery, right, 637 00:26:02,260 --> 00:26:05,030 whether it's the energy input to create that bias is coming 638 00:26:05,030 --> 00:26:08,050 from the sun or if it's coming from an external battery, 639 00:26:08,050 --> 00:26:09,410 that's a matter of detail. 640 00:26:09,410 --> 00:26:11,665 AUDIENCE: So is the sun forward biasing the cell? 641 00:26:11,665 --> 00:26:12,290 PROFESSOR: Yes. 642 00:26:12,290 --> 00:26:13,664 One can think about this as-- 643 00:26:13,664 --> 00:26:16,039 AUDIENCE: I thought you were talking about the difference 644 00:26:16,039 --> 00:26:17,460 between light and the LE-- OK. 645 00:26:17,460 --> 00:26:17,540 PROFESSOR: Oh. 646 00:26:17,540 --> 00:26:20,000 So the LED, in this case, could forward bias your device, too. 647 00:26:20,000 --> 00:26:21,083 I mean, it's just photons. 648 00:26:21,083 --> 00:26:22,870 Photons are forward biasing the device. 649 00:26:22,870 --> 00:26:25,127 AUDIENCE: So then can some ever reverse bias? 650 00:26:25,127 --> 00:26:25,710 PROFESSOR: No. 651 00:26:25,710 --> 00:26:28,320 That would be very difficult. What you could do, 652 00:26:28,320 --> 00:26:30,320 though, is have a bunch of solar cells connected 653 00:26:30,320 --> 00:26:32,210 in series with this one, right, that 654 00:26:32,210 --> 00:26:33,449 are producing forward power. 655 00:26:33,449 --> 00:26:35,240 You could shade this device, and then power 656 00:26:35,240 --> 00:26:37,190 could be flowing backward through it, right? 657 00:26:37,190 --> 00:26:39,150 In other words, it could be in the dark right 658 00:26:39,150 --> 00:26:42,007 here, in a dark condition. 659 00:26:42,007 --> 00:26:43,840 And you could be in a reverse bias condition 660 00:26:43,840 --> 00:26:47,005 just because of the way the other solar cells around it 661 00:26:47,005 --> 00:26:49,533 are behaving, if you have a shaded solar cell, for example, 662 00:26:49,533 --> 00:26:50,105 in a module. 663 00:26:50,105 --> 00:26:52,540 So imagine a seagull lands and kind of covers up 664 00:26:52,540 --> 00:26:54,280 one of the cells. 665 00:26:54,280 --> 00:26:58,460 That will be under reverse bias, and that could present problems 666 00:26:58,460 --> 00:27:02,580 if the solar cell can't withstand the reverse bias. 667 00:27:02,580 --> 00:27:04,240 No, this is a very ideal condition. 668 00:27:04,240 --> 00:27:06,859 What happens in the real world is that at some reverse bias 669 00:27:06,859 --> 00:27:08,400 condition, you'll just have biased it 670 00:27:08,400 --> 00:27:10,390 so much that electrons will be able to tunnel through 671 00:27:10,390 --> 00:27:12,390 from the p-type into the n-type right here. 672 00:27:12,390 --> 00:27:14,796 The electrons in the valence band will be able to tunnel 673 00:27:14,796 --> 00:27:16,170 through into the conduction band. 674 00:27:16,170 --> 00:27:18,710 And what happens to this IV curve is it goes zoom, 675 00:27:18,710 --> 00:27:19,960 begins dropping. 676 00:27:19,960 --> 00:27:24,280 So if the solar cell reverse bias-- 677 00:27:24,280 --> 00:27:27,190 let's see, the reverse bias current, 678 00:27:27,190 --> 00:27:30,262 or the current at reverse bias voltage, is not low enough, 679 00:27:30,262 --> 00:27:31,970 in other words, if the pn-junction is not 680 00:27:31,970 --> 00:27:34,630 strong enough, you could have a catastrophic failure 681 00:27:34,630 --> 00:27:37,487 of your module by just shading one of your cells. 682 00:27:37,487 --> 00:27:39,320 Thankfully, this is one of the testings that 683 00:27:39,320 --> 00:27:41,800 are done with the solar simulator 684 00:27:41,800 --> 00:27:43,250 to prevent that failure mode. 685 00:27:43,250 --> 00:27:43,990 AUDIENCE: OK. 686 00:27:43,990 --> 00:27:44,864 PROFESSOR: All right. 687 00:27:44,864 --> 00:27:47,091 I'll entertain deeper dives with questions. 688 00:27:47,091 --> 00:27:48,590 I'll try to keep the lecture focused 689 00:27:48,590 --> 00:27:50,220 on the broader general topics. 690 00:27:50,220 --> 00:27:53,950 But if somebody is interested in learning more, 691 00:27:53,950 --> 00:27:55,901 I'm happy to kind of dive into there. 692 00:27:55,901 --> 00:27:56,400 All right. 693 00:27:56,400 --> 00:27:59,220 So readings are strongly encouraged. 694 00:27:59,220 --> 00:28:01,500 I have interacted with several of you. 695 00:28:01,500 --> 00:28:03,930 Joe has interacted with probably 3n, 696 00:28:03,930 --> 00:28:06,680 n being the number of people I've interacted with so far, 697 00:28:06,680 --> 00:28:10,430 and really tried to impart the wisdom of pn-junctions. 698 00:28:10,430 --> 00:28:12,917 So please, please, please come to us if still 699 00:28:12,917 --> 00:28:14,250 things are going over your head. 700 00:28:14,250 --> 00:28:17,940 You should be able to explain to your roommates exactly what is 701 00:28:17,940 --> 00:28:19,430 going on in a pn-junction. 702 00:28:19,430 --> 00:28:22,144 Define parameters that determine solar cell efficiency. 703 00:28:22,144 --> 00:28:23,560 So now we have a qualitative sense 704 00:28:23,560 --> 00:28:26,250 about where current is flowing, where electrons are moving 705 00:28:26,250 --> 00:28:29,585 around, what defines the power output, how 706 00:28:29,585 --> 00:28:31,960 the power output is changing with illumination condition. 707 00:28:31,960 --> 00:28:33,834 We're getting an intuitive sense of all this. 708 00:28:33,834 --> 00:28:35,960 Let's start putting some discrete variables 709 00:28:35,960 --> 00:28:37,370 to all of that. 710 00:28:37,370 --> 00:28:40,880 And there are a bunch of two-letter or three-letter 711 00:28:40,880 --> 00:28:43,732 acronyms with some subscripts here that we'll get to know 712 00:28:43,732 --> 00:28:45,190 and we'll become very familiar with 713 00:28:45,190 --> 00:28:47,120 over the next few lectures. 714 00:28:47,120 --> 00:28:51,640 So how is solar cell conversion efficiency determined 715 00:28:51,640 --> 00:28:53,280 from that illuminated IV curve? 716 00:28:53,280 --> 00:28:54,770 That's our first question. 717 00:28:54,770 --> 00:28:59,380 And what I'm going to do is start with our source 718 00:28:59,380 --> 00:29:00,590 IV curve right here. 719 00:29:00,590 --> 00:29:02,330 This is just the IV quadrant. 720 00:29:02,330 --> 00:29:02,830 OK? 721 00:29:02,830 --> 00:29:05,950 So notice the current starts at 0 722 00:29:05,950 --> 00:29:07,520 and goes to some negative value. 723 00:29:07,520 --> 00:29:09,170 So we're looking in the IV quadrant. 724 00:29:09,170 --> 00:29:11,570 Voltage is going from 0 to a positive value. 725 00:29:11,570 --> 00:29:13,130 So again, IV quadrant. 726 00:29:13,130 --> 00:29:16,870 We have our ideal diode equation here. 727 00:29:16,870 --> 00:29:18,450 And oh, notice one thing. 728 00:29:18,450 --> 00:29:22,230 I just changed I to J. What just happened? 729 00:29:22,230 --> 00:29:24,650 Well, I and J look very similar, but they're, in fact, 730 00:29:24,650 --> 00:29:26,460 two different variables. 731 00:29:26,460 --> 00:29:30,090 Most often, PV researchers will report a current density, 732 00:29:30,090 --> 00:29:32,990 in other words, a current per unit area instead 733 00:29:32,990 --> 00:29:35,780 of the actual current coming out of a solar cell device. 734 00:29:35,780 --> 00:29:38,707 So what you've been measuring here off of the DAC 735 00:29:38,707 --> 00:29:41,040 has been current, total current output from that device. 736 00:29:41,040 --> 00:29:42,670 And it might be a really tiny number, 737 00:29:42,670 --> 00:29:44,170 and it might be difficult to compare 738 00:29:44,170 --> 00:29:45,644 against other-sized devices. 739 00:29:45,644 --> 00:29:47,310 And so what solar cell researchers often 740 00:29:47,310 --> 00:29:49,268 do is they say, OK, let's normalize the current 741 00:29:49,268 --> 00:29:51,150 by the area to get a current density. 742 00:29:51,150 --> 00:29:53,190 And we'll call current density J, 743 00:29:53,190 --> 00:29:56,210 and we'll call current I, right? 744 00:29:56,210 --> 00:29:57,710 So for calculating power, we'll have 745 00:29:57,710 --> 00:30:00,830 to use I. We'll have to multiply I times V. 746 00:30:00,830 --> 00:30:04,170 But if we're just looking at one solar cell versus another, 747 00:30:04,170 --> 00:30:06,870 we can use J as a very convenient way of comparing 748 00:30:06,870 --> 00:30:09,270 one solar cell versus another. 749 00:30:09,270 --> 00:30:10,020 Cool. 750 00:30:10,020 --> 00:30:10,520 OK. 751 00:30:10,520 --> 00:30:13,380 So the illuminated IV curve looks something like this, 752 00:30:13,380 --> 00:30:13,880 right? 753 00:30:13,880 --> 00:30:15,040 It's in the IV quadrant. 754 00:30:15,040 --> 00:30:17,206 It goes out a certain amount, then it the curves up. 755 00:30:17,206 --> 00:30:20,020 We just determined that here in class. 756 00:30:20,020 --> 00:30:22,420 And that's essentially the ideal diode equation 757 00:30:22,420 --> 00:30:26,240 with a superposition term, this J sub L right there. 758 00:30:26,240 --> 00:30:28,650 So let's parse through this. 759 00:30:28,650 --> 00:30:31,040 We have the y-intercept over here. 760 00:30:31,040 --> 00:30:34,060 At the y-intercept, there is maximum current 761 00:30:34,060 --> 00:30:36,510 flowing through the circuit but no power 762 00:30:36,510 --> 00:30:38,765 because voltage is equal to 0. 763 00:30:38,765 --> 00:30:41,140 So remember, the Fermi energy is the same on either side. 764 00:30:41,140 --> 00:30:42,639 The chemical potentials are the same 765 00:30:42,639 --> 00:30:43,860 on either side of the device. 766 00:30:43,860 --> 00:30:46,670 So there's no energy gain of the electron traveling 767 00:30:46,670 --> 00:30:50,757 through the external circuit, but there's a maximum current. 768 00:30:50,757 --> 00:30:52,840 And no power flowing through that external circuit 769 00:30:52,840 --> 00:30:54,590 because there's no potential to be dropped 770 00:30:54,590 --> 00:30:56,870 across the external resistor. 771 00:30:56,870 --> 00:30:58,860 The opposite happens over here at this point 772 00:30:58,860 --> 00:31:01,660 called Voc, which we'll call open-circuit voltage. 773 00:31:01,660 --> 00:31:04,670 The oc stands for open circuit, V, voltage. 774 00:31:04,670 --> 00:31:07,130 Open-circuit voltage is just as you would think it is. 775 00:31:07,130 --> 00:31:09,900 When your solar cell is in an open circuit, when you-- 776 00:31:09,900 --> 00:31:11,290 say you took a pair of scissors-- 777 00:31:11,290 --> 00:31:13,380 please don't this-- and cut the leads so 778 00:31:13,380 --> 00:31:16,110 that your solar cell wasn't outputting 779 00:31:16,110 --> 00:31:17,770 the current through an external load, 780 00:31:17,770 --> 00:31:21,540 there would be a bias voltage built up across the p and the n 781 00:31:21,540 --> 00:31:22,810 side of the solar cell. 782 00:31:22,810 --> 00:31:25,249 And it would be the maximum voltage 783 00:31:25,249 --> 00:31:27,290 that could be supported by that solar cell device 784 00:31:27,290 --> 00:31:28,539 under illumination conditions. 785 00:31:28,539 --> 00:31:30,690 That's the open-circuit voltage, open circuit 786 00:31:30,690 --> 00:31:33,010 because there's no current, again, 787 00:31:33,010 --> 00:31:34,810 traveling through the external circuit. 788 00:31:34,810 --> 00:31:38,460 That's why current is 0, open circuit. 789 00:31:38,460 --> 00:31:40,507 And voltage because this is-- well, 790 00:31:40,507 --> 00:31:42,090 it's an interesting point because it's 791 00:31:42,090 --> 00:31:45,420 the maximum voltage here represented in the IV quadrant. 792 00:31:45,420 --> 00:31:49,140 And somewhere in between the point of open-circuit voltage 793 00:31:49,140 --> 00:31:51,714 and short-circuit current-- short-circuit current, 794 00:31:51,714 --> 00:31:53,880 again, because you're short circuiting your device-- 795 00:31:53,880 --> 00:31:55,395 current is flowing through, but there's no resistor. 796 00:31:55,395 --> 00:31:56,436 There's no external load. 797 00:31:56,436 --> 00:31:58,810 There's no power being deposited on external load. 798 00:31:58,810 --> 00:32:00,380 Somewhere between these two extreme conditions 799 00:32:00,380 --> 00:32:02,879 where there's no power flowing through the external circuit, 800 00:32:02,879 --> 00:32:04,440 you have a maximum power point where 801 00:32:04,440 --> 00:32:06,981 there is a power being deposited across your external circuit 802 00:32:06,981 --> 00:32:08,510 and a lot of it, right? 803 00:32:08,510 --> 00:32:10,160 That's the maximum power point. 804 00:32:10,160 --> 00:32:12,135 This is the point at which the solar cell 805 00:32:12,135 --> 00:32:15,170 is producing the maximum amount of power output. 806 00:32:15,170 --> 00:32:18,590 And to represent that slightly differently, what 807 00:32:18,590 --> 00:32:21,900 I've done-- so if I were to take current times 808 00:32:21,900 --> 00:32:24,870 voltage right here using IV quadrant data, 809 00:32:24,870 --> 00:32:26,921 my power would be a negative number. 810 00:32:26,921 --> 00:32:27,420 Why? 811 00:32:27,420 --> 00:32:29,220 Because voltage is positive, but current 812 00:32:29,220 --> 00:32:30,387 is a negative number, right? 813 00:32:30,387 --> 00:32:32,720 So I'd multiply a positive and negative number together, 814 00:32:32,720 --> 00:32:35,210 you get a negative number, and that just sounds weird. 815 00:32:35,210 --> 00:32:37,210 Who talks about power output from solar cells 816 00:32:37,210 --> 00:32:38,270 being negative? 817 00:32:38,270 --> 00:32:41,160 It almost sounds like power's going into the device. 818 00:32:41,160 --> 00:32:43,330 So this is another convention that you're 819 00:32:43,330 --> 00:32:45,830 going to have to get used to is looking at the IV curve 820 00:32:45,830 --> 00:32:47,750 in the I quadrant. 821 00:32:47,750 --> 00:32:50,229 So all we've done is taken the y-axis 822 00:32:50,229 --> 00:32:51,520 and multiplied by a negative 1. 823 00:32:51,520 --> 00:32:55,030 So we flipped it up, right? 824 00:32:55,030 --> 00:32:56,235 So bear with me here. 825 00:32:56,235 --> 00:32:58,300 It's a bit tricky to keep all this in your RAM. 826 00:32:58,300 --> 00:33:01,040 But here's our short-circuit current point now. 827 00:33:01,040 --> 00:33:02,910 Here's our open-circuit voltage point. 828 00:33:02,910 --> 00:33:05,180 Our IV curve now is pointed down. 829 00:33:05,180 --> 00:33:07,640 Before it was going up because we were in the IV quadrant. 830 00:33:07,640 --> 00:33:09,370 Now, we flipped, essentially just 831 00:33:09,370 --> 00:33:11,980 done a-- we've done a flip vertical, if you will, 832 00:33:11,980 --> 00:33:16,100 on our IV curve, and we have our current increasing here 833 00:33:16,100 --> 00:33:17,944 going to higher bias voltages. 834 00:33:17,944 --> 00:33:20,360 Now we can take the product of the voltage and the current 835 00:33:20,360 --> 00:33:22,309 to determine the power, and we obtain 836 00:33:22,309 --> 00:33:24,350 a curve that looks very much like this blue curve 837 00:33:24,350 --> 00:33:26,200 right here that you can see. 838 00:33:26,200 --> 00:33:29,280 And the maximum power point is truth in advertising. 839 00:33:29,280 --> 00:33:30,960 It's at the maximum power. 840 00:33:30,960 --> 00:33:33,390 It's where this blue curve reaches a maximum. 841 00:33:33,390 --> 00:33:35,910 That is the maximum power point of the solar cell device. 842 00:33:35,910 --> 00:33:38,070 That is where the solar cell is outputting 843 00:33:38,070 --> 00:33:40,720 the maximum amount of power. 844 00:33:40,720 --> 00:33:42,230 And so at this maximum power point, 845 00:33:42,230 --> 00:33:45,070 there is a voltage and a current associated with it that you can 846 00:33:45,070 --> 00:33:46,890 read right off the IV curve. 847 00:33:46,890 --> 00:33:51,310 And this we call Jmp, or current density at the maximum power 848 00:33:51,310 --> 00:33:55,500 point, and Vmp, which is the voltage at the maximum power 849 00:33:55,500 --> 00:33:57,310 point. 850 00:33:57,310 --> 00:33:59,490 So, so far, we've learned essentially four variables 851 00:33:59,490 --> 00:33:59,990 here. 852 00:33:59,990 --> 00:34:04,130 We have our Jsc, our Voc, and our Jmp, 853 00:34:04,130 --> 00:34:07,830 and our Vmp at that data point right there. 854 00:34:07,830 --> 00:34:11,286 Questions, since I know you have them. 855 00:34:11,286 --> 00:34:13,436 AUDIENCE: To ensure that the device is working 856 00:34:13,436 --> 00:34:17,808 in the maximum power point, does an external voltage have 857 00:34:17,808 --> 00:34:19,659 to be applied to it? 858 00:34:19,659 --> 00:34:21,469 PROFESSOR: So to ensure that the solar cell 859 00:34:21,469 --> 00:34:24,550 device is operating right here, a couple of things 860 00:34:24,550 --> 00:34:25,489 need to happen. 861 00:34:25,489 --> 00:34:27,659 You need to have the right illumination conditions, 862 00:34:27,659 --> 00:34:29,639 and you need to have the right load. 863 00:34:29,639 --> 00:34:31,650 So the two need to be matched to each other. 864 00:34:31,650 --> 00:34:32,303 Absolutely. 865 00:34:32,303 --> 00:34:34,219 And that's where some of the power electronics 866 00:34:34,219 --> 00:34:36,715 come into play. 867 00:34:36,715 --> 00:34:37,215 Yeah? 868 00:34:37,215 --> 00:34:39,171 AUDIENCE: So in the last problem set, 869 00:34:39,171 --> 00:34:44,305 where [INAUDIBLE], we assumed that output voltage would 870 00:34:44,305 --> 00:34:46,329 be [INAUDIBLE] volts. 871 00:34:46,329 --> 00:34:46,995 PROFESSOR: Yeah. 872 00:34:46,995 --> 00:34:49,790 AUDIENCE: Is that, in general, a safe assumption 873 00:34:49,790 --> 00:34:51,464 for [INAUDIBLE] solar cell? 874 00:34:51,464 --> 00:34:52,380 PROFESSOR: Yeah, yeah. 875 00:34:52,380 --> 00:34:55,320 So it's a very interesting question regarding the homework 876 00:34:55,320 --> 00:34:55,820 question. 877 00:34:55,820 --> 00:34:58,540 Let me repeat it so that the microphone can hear it. 878 00:34:58,540 --> 00:35:01,670 The homework question in the last homework, 879 00:35:01,670 --> 00:35:05,040 there was one question that inquired, 880 00:35:05,040 --> 00:35:07,160 assume that the voltage at the maximum power point 881 00:35:07,160 --> 00:35:12,130 is the band gap voltage equivalent minus 0.5 volts. 882 00:35:12,130 --> 00:35:15,240 And the rationale for that assumption is as follows. 883 00:35:15,240 --> 00:35:17,680 The open-circuit voltage, this point, 884 00:35:17,680 --> 00:35:23,290 is generally between 0.35 and 0.4 volts minus the band gap, 885 00:35:23,290 --> 00:35:24,750 or lower than the band gap. 886 00:35:24,750 --> 00:35:27,150 So you have the band gap energy minus 0.4 volts. 887 00:35:27,150 --> 00:35:29,820 And I can show you a very nice little paper 888 00:35:29,820 --> 00:35:30,995 that describes why that is. 889 00:35:30,995 --> 00:35:32,640 It essentially has to do, in part, 890 00:35:32,640 --> 00:35:35,830 with losses inside of the solar cell at thermodynamic limits 891 00:35:35,830 --> 00:35:37,880 of conversion inside of the solar cell device. 892 00:35:37,880 --> 00:35:39,560 Then what we've done is we've done 893 00:35:39,560 --> 00:35:42,090 another additional discounting from the Voc to the maximum 894 00:35:42,090 --> 00:35:47,310 power point, which we've assumed is around 0.1, maybe 0.2 volts. 895 00:35:47,310 --> 00:35:49,507 Notice the shape of the IV curve right here. 896 00:35:49,507 --> 00:35:51,090 The maximum power point is interesting 897 00:35:51,090 --> 00:35:53,006 because the voltage at the maximum power point 898 00:35:53,006 --> 00:35:55,990 is almost the Voc, in a good device. 899 00:35:55,990 --> 00:35:57,940 And the current at the maximum power point 900 00:35:57,940 --> 00:36:00,560 is almost Jsc, but not quite. 901 00:36:00,560 --> 00:36:01,380 All right? 902 00:36:01,380 --> 00:36:04,335 So the discounting from the Voc to the maximum power 903 00:36:04,335 --> 00:36:08,040 point voltage is not that much, as is the discounting 904 00:36:08,040 --> 00:36:10,480 from the short-circuit current to the maximum power 905 00:36:10,480 --> 00:36:12,640 point in a good device. 906 00:36:12,640 --> 00:36:15,850 In a bad device, this maximum power point 907 00:36:15,850 --> 00:36:17,710 here could be dragged all way down here. 908 00:36:17,710 --> 00:36:20,335 You could have an IV curve that looked something more like this 909 00:36:20,335 --> 00:36:23,310 instead, almost like a resistor, at which point 910 00:36:23,310 --> 00:36:26,699 the maximum power output would be a lot less, a lot less 911 00:36:26,699 --> 00:36:28,240 than what's shown here in blue curve. 912 00:36:31,660 --> 00:36:32,350 Cool. 913 00:36:32,350 --> 00:36:32,850 All right. 914 00:36:32,850 --> 00:36:35,010 So let's continue moving on. 915 00:36:35,010 --> 00:36:37,160 The efficiency of the solar cell. 916 00:36:37,160 --> 00:36:42,290 Eta, this Greek letter eta, is our power out versus power in. 917 00:36:42,290 --> 00:36:45,390 Our power in is the illumination intensity 918 00:36:45,390 --> 00:36:48,100 given in units of watts per meter squared. 919 00:36:48,100 --> 00:36:51,140 So we calculated this in our very first homework assignment 920 00:36:51,140 --> 00:36:54,100 and realized that the AM 1.5 spectrum is around 921 00:36:54,100 --> 00:36:56,560 1,000 watts per meter squared. 922 00:36:56,560 --> 00:36:58,980 So that's our input power right here. 923 00:37:02,090 --> 00:37:05,840 Our output power is the voltage at the maximum power 924 00:37:05,840 --> 00:37:07,522 point times-- whoopsy-- times the 925 00:37:07,522 --> 00:37:08,980 current at the maximum power point, 926 00:37:08,980 --> 00:37:10,960 not the current density, the current 927 00:37:10,960 --> 00:37:12,232 at the maximum power point. 928 00:37:12,232 --> 00:37:13,940 So take this current density and multiply 929 00:37:13,940 --> 00:37:16,460 by area, and that's effectively-- the units 930 00:37:16,460 --> 00:37:19,040 work out better that way. 931 00:37:19,040 --> 00:37:21,960 So it would be either V times I at the maximum power point 932 00:37:21,960 --> 00:37:25,259 or V times J times the area, the area of the device, 933 00:37:25,259 --> 00:37:27,550 the area of the solar cell, at the maximum power point. 934 00:37:27,550 --> 00:37:30,870 And that's the total power out. 935 00:37:30,870 --> 00:37:32,130 Actually, yeah, yeah. 936 00:37:32,130 --> 00:37:35,412 So as long as the units are in units of watts per meter 937 00:37:35,412 --> 00:37:37,870 squared-- yeah, down here-- if this is not total watts but, 938 00:37:37,870 --> 00:37:39,536 watts per meter squared, you could still 939 00:37:39,536 --> 00:37:41,200 use current density. 940 00:37:41,200 --> 00:37:42,670 Those units would still work out. 941 00:37:42,670 --> 00:37:45,890 So be very careful whether you use total power in 942 00:37:45,890 --> 00:37:48,650 or normalized by unit area power, right? 943 00:37:48,650 --> 00:37:50,440 Just keep track of your units. 944 00:37:50,440 --> 00:37:52,850 Don't do like the professor. 945 00:37:52,850 --> 00:37:53,410 OK. 946 00:37:53,410 --> 00:37:56,530 So we have efficiency here as power out versus power in, 947 00:37:56,530 --> 00:38:00,030 the power out being the maximum power point power and the power 948 00:38:00,030 --> 00:38:02,199 in being the illumination from the sun. 949 00:38:02,199 --> 00:38:03,240 Now we're really talking. 950 00:38:03,240 --> 00:38:05,379 This is starting to get interesting because it's 951 00:38:05,379 --> 00:38:06,170 beginning to click. 952 00:38:06,170 --> 00:38:08,050 Pieces from lecture number 2 come together 953 00:38:08,050 --> 00:38:09,314 with what we're seeing now. 954 00:38:09,314 --> 00:38:11,605 So this is solar cell output power at the maximum power 955 00:38:11,605 --> 00:38:13,230 point and sunlight coming in. 956 00:38:13,230 --> 00:38:14,380 OK. 957 00:38:14,380 --> 00:38:16,850 So what I'm going to do next is I'm 958 00:38:16,850 --> 00:38:18,470 going to take this maximum power point 959 00:38:18,470 --> 00:38:23,050 and I'm going to draw a box that starts at the origin here, 960 00:38:23,050 --> 00:38:28,650 and the kitty-corner corner of my box 961 00:38:28,650 --> 00:38:31,160 is going to end at the maximum power point. 962 00:38:31,160 --> 00:38:33,640 So it'll have some rectilinear shape that 963 00:38:33,640 --> 00:38:35,650 will comprise the maximum power point 964 00:38:35,650 --> 00:38:39,550 and 0, 0, the origin, as two of its corners. 965 00:38:39,550 --> 00:38:42,030 And that box looks like this blue one right here. 966 00:38:42,030 --> 00:38:45,120 The area of that box is Jmp times Vmp. 967 00:38:47,670 --> 00:38:48,300 OK? 968 00:38:48,300 --> 00:38:50,550 And notice I have another box around here. 969 00:38:50,550 --> 00:38:54,780 I have this clear box that starts at the Voc 970 00:38:54,780 --> 00:38:57,120 point and the Jsc point. 971 00:38:57,120 --> 00:39:00,770 And now I have two rectilinear shapes, this blue one 972 00:39:00,770 --> 00:39:03,470 and the clear one right here, the bigger one. 973 00:39:03,470 --> 00:39:08,820 The bigger one has an area of Jsc times Voc. 974 00:39:08,820 --> 00:39:10,570 And I'm going to define a parameter called 975 00:39:10,570 --> 00:39:14,180 fill factor, which will be the ratio of these two areas, 976 00:39:14,180 --> 00:39:17,510 the ratio of those two boxes, the Vmp times Jmp divided 977 00:39:17,510 --> 00:39:20,470 by the Voc and Jsc. 978 00:39:20,470 --> 00:39:23,840 If this is 1, which is virtually impossible to do, 979 00:39:23,840 --> 00:39:25,840 but if this were 1, it would mean that these two 980 00:39:25,840 --> 00:39:27,510 boxes were the same size. 981 00:39:27,510 --> 00:39:29,840 And the current and voltage at the maximum power points 982 00:39:29,840 --> 00:39:32,530 would be the current and voltage under 983 00:39:32,530 --> 00:39:35,850 short-circuit and open-circuit conditions respectively. 984 00:39:35,850 --> 00:39:41,840 In real life, this blue box is smaller than the square box 985 00:39:41,840 --> 00:39:42,860 right over here. 986 00:39:42,860 --> 00:39:48,120 And so the Jmp Vmp product is less than the Jsc Voc product. 987 00:39:48,120 --> 00:39:50,310 And by consequence as well, the Jmp 988 00:39:50,310 --> 00:39:54,610 is less than the Jsc, Vmp is less than Voc. 989 00:39:54,610 --> 00:39:58,470 So the ratio of the two boxes is defined as the fill factor. 990 00:39:58,470 --> 00:40:02,550 The fill factor indicates the quality of your diode. 991 00:40:02,550 --> 00:40:04,830 If your fill factor is very poor, 992 00:40:04,830 --> 00:40:07,565 that means that that sun right over there at its maximum power 993 00:40:07,565 --> 00:40:10,060 point is being dragged toward the origin. 994 00:40:10,060 --> 00:40:11,980 That means that the area of this blue box 995 00:40:11,980 --> 00:40:16,160 is growing smaller relative to the area of this clear box. 996 00:40:16,160 --> 00:40:18,730 The fill factor is going down. 997 00:40:18,730 --> 00:40:22,900 That means you're filling less of this maximum square box 998 00:40:22,900 --> 00:40:27,340 function defined by the Voc Jsc. 999 00:40:27,340 --> 00:40:28,280 OK. 1000 00:40:28,280 --> 00:40:32,950 So we have defined efficiency as power out divided 1001 00:40:32,950 --> 00:40:36,120 by power in, power out being the current voltage 1002 00:40:36,120 --> 00:40:38,180 product of the maximum power point divided 1003 00:40:38,180 --> 00:40:40,820 by the solar insulation, fill factor 1004 00:40:40,820 --> 00:40:46,320 being defined as the ratio of Vmp Imp product divided 1005 00:40:46,320 --> 00:40:49,360 by Voc Ioc product. 1006 00:40:49,360 --> 00:40:52,450 Notice that here I've written this in terms of total current, 1007 00:40:52,450 --> 00:40:54,260 here in terms of current density. 1008 00:40:54,260 --> 00:40:56,064 The areas essentially just cancel out 1009 00:40:56,064 --> 00:40:58,480 because you have an area in the numerator and denominator. 1010 00:40:58,480 --> 00:40:59,000 They cancel. 1011 00:40:59,000 --> 00:41:01,650 These ratios should be identical. 1012 00:41:01,650 --> 00:41:05,210 Thus we obtain an expression for the efficiency in terms 1013 00:41:05,210 --> 00:41:09,280 of fill factor, Voc, and Ioc. 1014 00:41:09,280 --> 00:41:12,430 Simply by using this fill factor definition right here, 1015 00:41:12,430 --> 00:41:14,450 what I've done is I've multiplied 1016 00:41:14,450 --> 00:41:16,650 this side of the equation-- let's just 1017 00:41:16,650 --> 00:41:18,620 focus right here-- where we have fill 1018 00:41:18,620 --> 00:41:22,470 factor equals Vmp times Imp divided by Voc times Ioc. 1019 00:41:22,470 --> 00:41:25,070 I moved the denominator up to the side 1020 00:41:25,070 --> 00:41:28,140 over here, multiplied it by fill factor, and that's my Vmp Imp. 1021 00:41:28,140 --> 00:41:30,100 Now, I go back to that top equation 1022 00:41:30,100 --> 00:41:32,480 and say my Vmp Imp is now going to be substituted 1023 00:41:32,480 --> 00:41:35,260 by fill factor times Voc times Ioc, 1024 00:41:35,260 --> 00:41:37,853 and that's how I get to this equation right here. 1025 00:41:37,853 --> 00:41:38,719 Why? 1026 00:41:38,719 --> 00:41:41,010 Why do I go through the effort of this little numerical 1027 00:41:41,010 --> 00:41:42,050 manipulation? 1028 00:41:42,050 --> 00:41:44,900 I do it because these parameters right here 1029 00:41:44,900 --> 00:41:48,790 are fairly easy to measure using the solar simulator 1030 00:41:48,790 --> 00:41:50,580 that you just put together. 1031 00:41:50,580 --> 00:41:54,440 So I can measure the point at which my voltage is 1032 00:41:54,440 --> 00:41:55,530 at open-circuit condition. 1033 00:41:55,530 --> 00:41:59,000 I can measure the current at short-circuit condition. 1034 00:41:59,000 --> 00:42:01,670 And simply by taking the ratio of those boxes, 1035 00:42:01,670 --> 00:42:04,160 I can determine what my fill factor is as well. 1036 00:42:04,160 --> 00:42:10,660 And these break down roughly into the current is going 1037 00:42:10,660 --> 00:42:13,372 to be a function roughly-- again, I'm really painting 1038 00:42:13,372 --> 00:42:15,330 broad brush strokes here-- the current is going 1039 00:42:15,330 --> 00:42:18,480 to be roughly a function of illumination condition and bulk 1040 00:42:18,480 --> 00:42:20,380 material quality. 1041 00:42:20,380 --> 00:42:23,690 The Voc will be roughly a function of the interface 1042 00:42:23,690 --> 00:42:25,050 and the diode characteristics. 1043 00:42:25,050 --> 00:42:26,809 And the fill factor is going to be 1044 00:42:26,809 --> 00:42:28,850 a function of the interface diode characteristics 1045 00:42:28,850 --> 00:42:31,647 but also of the resistances within the device. 1046 00:42:31,647 --> 00:42:33,355 And so from an engineering point of view, 1047 00:42:33,355 --> 00:42:37,420 when we break the solar cell output down into these three 1048 00:42:37,420 --> 00:42:40,280 parameters so that we can better understand what's 1049 00:42:40,280 --> 00:42:43,040 going wrong with our solar cell. 1050 00:42:43,040 --> 00:42:45,457 If we have everything lumped in terms of Vmp Imp, 1051 00:42:45,457 --> 00:42:47,540 it becomes a little bit more obscure to figure out 1052 00:42:47,540 --> 00:42:50,290 what exactly is going wrong with our solar cell device. 1053 00:42:50,290 --> 00:42:51,607 Ashley? 1054 00:42:51,607 --> 00:42:53,232 AUDIENCE: You said the fill factor also 1055 00:42:53,232 --> 00:42:55,162 an easily measurable parameter? 1056 00:42:55,162 --> 00:42:57,620 PROFESSOR: So the fill factor you would measure essentially 1057 00:42:57,620 --> 00:43:00,830 by doing the little analysis we just did right here. 1058 00:43:00,830 --> 00:43:01,880 Yeah, exactly. 1059 00:43:01,880 --> 00:43:04,560 So you'd have to do a voltage current sweep. 1060 00:43:04,560 --> 00:43:05,060 Mm-hmm. 1061 00:43:08,630 --> 00:43:09,260 Coolness. 1062 00:43:09,260 --> 00:43:09,890 OK. 1063 00:43:09,890 --> 00:43:12,840 So we have an expression for efficiency 1064 00:43:12,840 --> 00:43:17,640 in terms of fill factor, Voc, Ioc and our incoming power. 1065 00:43:17,640 --> 00:43:20,000 So power out, this right here again 1066 00:43:20,000 --> 00:43:23,910 is power out, divided by power in. 1067 00:43:23,910 --> 00:43:26,110 Why does efficiency matter? 1068 00:43:26,110 --> 00:43:28,140 Why do we care so much about efficiency? 1069 00:43:28,140 --> 00:43:31,920 Well, the conversion efficiency determines 1070 00:43:31,920 --> 00:43:34,910 the area of solar cells needed to produce a certain peak 1071 00:43:34,910 --> 00:43:37,100 power, or to think of it differently, 1072 00:43:37,100 --> 00:43:39,540 the area of solar panels that is necessary to produce 1073 00:43:39,540 --> 00:43:42,010 a certain energy per unit time. 1074 00:43:42,010 --> 00:43:44,815 And many costs scale with area. 1075 00:43:44,815 --> 00:43:47,612 You have glass, encapsulants, the absorbent materials 1076 00:43:47,612 --> 00:43:49,320 within the solar cell devices themselves, 1077 00:43:49,320 --> 00:43:51,300 the metals that are used to make contacts, 1078 00:43:51,300 --> 00:43:53,365 the labor that's used to install the panels. 1079 00:43:53,365 --> 00:43:55,101 If you have a larger panel area, you 1080 00:43:55,101 --> 00:43:56,350 need more labor to install it. 1081 00:43:56,350 --> 00:43:58,475 The aluminum and racking and framing materials that 1082 00:43:58,475 --> 00:44:02,380 go into holding the panels up in the field either on a roof 1083 00:44:02,380 --> 00:44:03,620 or out in the field. 1084 00:44:03,620 --> 00:44:06,710 So efficiency affects pretty much everything 1085 00:44:06,710 --> 00:44:08,960 but the inverter and possibly some of the soft costs 1086 00:44:08,960 --> 00:44:09,585 of the project. 1087 00:44:09,585 --> 00:44:11,390 That includes the architect and the people 1088 00:44:11,390 --> 00:44:16,030 who you pay to handle the money, financing, and the lawyers 1089 00:44:16,030 --> 00:44:16,610 perhaps. 1090 00:44:16,610 --> 00:44:20,050 So pretty much all of the real material and labor costs 1091 00:44:20,050 --> 00:44:22,210 are scaling with area. 1092 00:44:22,210 --> 00:44:24,970 And so efficiency determines that to a large degree, 1093 00:44:24,970 --> 00:44:26,830 and hence it's a highly-leveraged way 1094 00:44:26,830 --> 00:44:28,560 to reduce the costs of solar energy. 1095 00:44:28,560 --> 00:44:30,120 If you do a sensitivity analysis, 1096 00:44:30,120 --> 00:44:33,000 which you will do in the second and third parts of the class, 1097 00:44:33,000 --> 00:44:34,610 and look at the costs of solar and how 1098 00:44:34,610 --> 00:44:35,984 it scales with efficiency, you'll 1099 00:44:35,984 --> 00:44:38,890 see that efficiency is one of the determining factors 1100 00:44:38,890 --> 00:44:41,090 for cost in a solar cell device. 1101 00:44:41,090 --> 00:44:42,770 And that's why we focus on it a lot. 1102 00:44:42,770 --> 00:44:45,940 To put it into perspective, if the efficiency up there is 1103 00:44:45,940 --> 00:44:48,500 determined by the output power versus the input power, 1104 00:44:48,500 --> 00:44:51,770 if we had 100% conversion efficiency, which is impossible 1105 00:44:51,770 --> 00:44:54,420 to achieve, thermodynamically impossible to achieve, 1106 00:44:54,420 --> 00:44:57,117 we would produce a certain amount of energy per unit time, 1107 00:44:57,117 --> 00:44:59,200 or a certain amount of peak power, with this panel 1108 00:44:59,200 --> 00:44:59,970 right there. 1109 00:44:59,970 --> 00:45:02,580 Say that's the size of our field installation. 1110 00:45:02,580 --> 00:45:04,830 If we had a 33% efficiency cell, which 1111 00:45:04,830 --> 00:45:07,030 is closer to the space-grade solar cells, 1112 00:45:07,030 --> 00:45:09,810 we'd need three times that area, so three 1113 00:45:09,810 --> 00:45:12,380 times the encapsulants, three times the glass, three times 1114 00:45:12,380 --> 00:45:14,260 the labor to install it. 1115 00:45:14,260 --> 00:45:20,230 And if we had a 20% efficiency, say, high end 1116 00:45:20,230 --> 00:45:22,311 but still commercial solar module, 1117 00:45:22,311 --> 00:45:24,060 not something you'd need to get from NASA, 1118 00:45:24,060 --> 00:45:27,840 but something that you could buy from a supplier, 1119 00:45:27,840 --> 00:45:30,050 you'd need five times that area. 1120 00:45:30,050 --> 00:45:33,490 Whereas if you had a 10% efficiency module, which 1121 00:45:33,490 --> 00:45:36,130 is more approaching the area of some relatively 1122 00:45:36,130 --> 00:45:40,102 inexpensive solar cells, you would need 10 times that area. 1123 00:45:40,102 --> 00:45:41,560 So if you're doing a cost analysis, 1124 00:45:41,560 --> 00:45:43,130 this is why efficiency matters. 1125 00:45:43,130 --> 00:45:45,110 It might still be cheaper to use this 1126 00:45:45,110 --> 00:45:47,230 instead of to use this over here. 1127 00:45:47,230 --> 00:45:50,070 That might very well be more expensive when you do the math 1128 00:45:50,070 --> 00:45:52,130 and figure out how much it costs to deposit those materials 1129 00:45:52,130 --> 00:45:53,680 with a very low throughput deposition 1130 00:45:53,680 --> 00:45:55,510 process and very high cost. 1131 00:45:55,510 --> 00:45:57,190 It might still be, but it might not. 1132 00:45:57,190 --> 00:45:59,590 The material costs might end up whopping you. 1133 00:45:59,590 --> 00:46:02,980 And so a simple equation that calculates all these parameters 1134 00:46:02,980 --> 00:46:05,830 in, the material costs, the module efficiency, 1135 00:46:05,830 --> 00:46:07,830 essentially the material [? and labor ?] costs, 1136 00:46:07,830 --> 00:46:10,457 are being calculated in dollars per meter squared, just saying, 1137 00:46:10,457 --> 00:46:12,540 how many dollars go into producing a meter squared 1138 00:46:12,540 --> 00:46:13,760 of this material? 1139 00:46:13,760 --> 00:46:15,490 And the efficiency is over here. 1140 00:46:15,490 --> 00:46:18,370 And this is just a very simple back-of-the-envelope 1141 00:46:18,370 --> 00:46:22,020 calculation type of way of estimating the cost of a solar 1142 00:46:22,020 --> 00:46:22,930 system. 1143 00:46:22,930 --> 00:46:26,410 So if you say, OK, I'm willing to pay more 1144 00:46:26,410 --> 00:46:29,910 for a high-efficiency cell because I'm using less area, 1145 00:46:29,910 --> 00:46:32,580 you can use this type of calculation 1146 00:46:32,580 --> 00:46:34,397 to get to the answer quickly. 1147 00:46:34,397 --> 00:46:36,480 It's not a levelized cost of electricity analysis. 1148 00:46:36,480 --> 00:46:38,560 It's not using discounted capital flows 1149 00:46:38,560 --> 00:46:40,686 and so forth, which we'll get to later on in class. 1150 00:46:40,686 --> 00:46:42,601 This is a really back-of-the-envelope envelope 1151 00:46:42,601 --> 00:46:44,790 engineering approach to estimating costs of a solar 1152 00:46:44,790 --> 00:46:47,060 system. 1153 00:46:47,060 --> 00:46:50,220 So I think this is a great place to stop. 1154 00:46:50,220 --> 00:46:53,240 And if anybody has a pitch concerning their project 1155 00:46:53,240 --> 00:46:55,550 ideas, class project ideas, I'd like to invite them 1156 00:46:55,550 --> 00:46:57,980 to the front now. 1157 00:46:57,980 --> 00:47:00,220 The class project, mind you, is really the capstone 1158 00:47:00,220 --> 00:47:03,670 of this class, 2.626, 2.627. 1159 00:47:03,670 --> 00:47:07,189 So if you have an idea, a fun idea, for a class project, 1160 00:47:07,189 --> 00:47:09,730 I'd invite you to give a pitch up here at the front of class, 1161 00:47:09,730 --> 00:47:14,000 or you're welcome to send it on an email to the class listserv.