1 00:00:00,050 --> 00:00:02,500 The following content is provided under a Creative 2 00:00:02,500 --> 00:00:04,019 Commons license. 3 00:00:04,019 --> 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 00:00:24,739 --> 00:00:26,530 PROFESSOR: All right, so let's get started. 9 00:00:26,530 --> 00:00:31,780 So today-- our last lecture we talked about different device 10 00:00:31,780 --> 00:00:35,410 parameters, mainly our series resistance 11 00:00:35,410 --> 00:00:39,037 and shunt resistance, and how that affects our efficiencies. 12 00:00:39,037 --> 00:00:41,370 Today we're going to talk a lot about different material 13 00:00:41,370 --> 00:00:46,310 properties and how they affect certain device characteristics, 14 00:00:46,310 --> 00:00:48,760 and mainly just affect our output efficiency. 15 00:00:48,760 --> 00:00:53,700 So we've been talking a lot about the fundamentals. 16 00:00:53,700 --> 00:00:56,154 I'm sure you guys are loving this right now. 17 00:00:56,154 --> 00:00:58,570 So we're going to complete this in probably the next three 18 00:00:58,570 --> 00:01:00,722 lectures and then move on to a lot 19 00:01:00,722 --> 00:01:02,180 of the kind of cross cutting themes 20 00:01:02,180 --> 00:01:05,715 in PV-- some advanced concepts, different device architectures, 21 00:01:05,715 --> 00:01:08,090 and that kind of thing. 22 00:01:08,090 --> 00:01:10,050 And so that is coming in the future, 23 00:01:10,050 --> 00:01:13,950 but we're still doing fundamentals today. 24 00:01:13,950 --> 00:01:16,330 And so I know you're probably all aware of this equation. 25 00:01:19,830 --> 00:01:22,650 And again, this is kind the progress we've made, 26 00:01:22,650 --> 00:01:27,360 so we're almost all the way through explaining basic device 27 00:01:27,360 --> 00:01:29,660 physics and basic semiconductor physics so you 28 00:01:29,660 --> 00:01:32,600 can understand simple devices. 29 00:01:32,600 --> 00:01:36,460 And it's always important to remember that your device is 30 00:01:36,460 --> 00:01:38,897 like a leaky bucket, and you're limited by the largest 31 00:01:38,897 --> 00:01:39,730 hole in that bucket. 32 00:01:39,730 --> 00:01:42,710 So the weakest aspect of your solar cell 33 00:01:42,710 --> 00:01:47,806 is really what's going to limit your device performance, 34 00:01:47,806 --> 00:01:49,180 and especially if any of you here 35 00:01:49,180 --> 00:01:52,840 are trying to make devices, it's really important 36 00:01:52,840 --> 00:01:55,510 to think about all of these things when building it. 37 00:01:55,510 --> 00:01:57,475 And this is very difficult to do. 38 00:01:57,475 --> 00:01:58,725 I can certainly tell you that. 39 00:02:02,442 --> 00:02:03,650 So I kind of like this slide. 40 00:02:03,650 --> 00:02:05,740 What this is saying what's the thing we care 41 00:02:05,740 --> 00:02:07,000 about most in our solar cells? 42 00:02:07,000 --> 00:02:10,000 Well, as scientists, other than dollars per watt, 43 00:02:10,000 --> 00:02:13,884 we want to maximize our efficiency for a certain price. 44 00:02:13,884 --> 00:02:15,800 And our efficiency, there's several parameters 45 00:02:15,800 --> 00:02:16,466 that go into it. 46 00:02:16,466 --> 00:02:19,220 Again, we talked about our GSC, our short circuit current, 47 00:02:19,220 --> 00:02:21,830 our open circuit voltage, and our fill factor. 48 00:02:21,830 --> 00:02:24,207 And that gives our output energy, or output power, 49 00:02:24,207 --> 00:02:25,790 and we divide that by the input power, 50 00:02:25,790 --> 00:02:27,470 which is the solar insulation. 51 00:02:27,470 --> 00:02:29,470 Now we can split up that again into open circuit 52 00:02:29,470 --> 00:02:33,150 voltage, short circuit current, and fill factor. 53 00:02:33,150 --> 00:02:36,140 We talked a little bit last lecture about fill factor 54 00:02:36,140 --> 00:02:39,250 and how that's influenced by different resistive 55 00:02:39,250 --> 00:02:40,909 losses in our solar cell. 56 00:02:40,909 --> 00:02:43,200 Today we're going to mainly be focused on short circuit 57 00:02:43,200 --> 00:02:46,470 current and things like internal quantum efficiency, which 58 00:02:46,470 --> 00:02:51,630 are highly affected by our diffusion length. 59 00:02:51,630 --> 00:02:54,310 And the diffusion length is often 60 00:02:54,310 --> 00:02:56,220 limited by certain defects in our materials, 61 00:02:56,220 --> 00:02:58,150 and we're going to get into why that is. 62 00:02:58,150 --> 00:03:00,400 And to a certain extent, we'll talk about open circuit 63 00:03:00,400 --> 00:03:04,630 voltage, because your GSC really has a large effect 64 00:03:04,630 --> 00:03:08,200 on your open circuit voltage. 65 00:03:08,200 --> 00:03:10,630 So what we're going to learn today 66 00:03:10,630 --> 00:03:14,002 is what is minority carrier diffusion length. 67 00:03:14,002 --> 00:03:14,960 It was in the homework. 68 00:03:14,960 --> 00:03:18,069 Hopefully you guys have some idea coming to lecture, 69 00:03:18,069 --> 00:03:19,652 but today we're going to talk about it 70 00:03:19,652 --> 00:03:22,060 a little more in depth, and why it's important, 71 00:03:22,060 --> 00:03:23,080 and how it's affected. 72 00:03:23,080 --> 00:03:24,746 What are the parameters of determinants? 73 00:03:24,746 --> 00:03:29,052 So mainly diffusivity and lifetime. 74 00:03:29,052 --> 00:03:30,760 We're going to describe how it's actually 75 00:03:30,760 --> 00:03:32,790 measured in a solar cell, which is actually 76 00:03:32,790 --> 00:03:34,010 a really cool measurement, and we actually 77 00:03:34,010 --> 00:03:35,384 have the capabilities in our lab. 78 00:03:35,384 --> 00:03:37,640 And possibly some of you, when you're making cells, 79 00:03:37,640 --> 00:03:40,235 will be able to do that measurement. 80 00:03:40,235 --> 00:03:42,360 We're also going to look at some of the things that 81 00:03:42,360 --> 00:03:45,790 limit lifetime, some of the basic recombination mechanisms. 82 00:03:45,790 --> 00:03:50,060 Also look at how your excess carrier concentration changes 83 00:03:50,060 --> 00:03:52,260 as a function of lifetime and generationally. 84 00:03:52,260 --> 00:03:54,468 And then also talk about the last material parameter, 85 00:03:54,468 --> 00:03:56,210 which is mobility, which discusses 86 00:03:56,210 --> 00:03:58,510 of how well these excited charges can move around 87 00:03:58,510 --> 00:04:00,230 in your material. 88 00:04:00,230 --> 00:04:02,600 So without further ado, here are minority curve, 89 00:04:02,600 --> 00:04:03,310 diffusion length. 90 00:04:03,310 --> 00:04:05,010 The definition is really simple. 91 00:04:05,010 --> 00:04:07,020 If you generate-- let's say, a photon 92 00:04:07,020 --> 00:04:10,540 comes in and hits a silicon atom and generates an electron pair 93 00:04:10,540 --> 00:04:11,550 over here. 94 00:04:11,550 --> 00:04:14,920 How far or how much volume can it explore? 95 00:04:14,920 --> 00:04:19,290 And that volume it can explore is 96 00:04:19,290 --> 00:04:21,170 described by some characteristic radius, 97 00:04:21,170 --> 00:04:24,550 and that radius is known as the diffusion length. 98 00:04:24,550 --> 00:04:27,230 And it's really important to solar cells, 99 00:04:27,230 --> 00:04:29,790 because when you think about these carriers 100 00:04:29,790 --> 00:04:30,990 that you're generating. 101 00:04:30,990 --> 00:04:33,132 If they can only explore a very short area, 102 00:04:33,132 --> 00:04:34,340 they're not going to make it. 103 00:04:34,340 --> 00:04:36,300 This is a very good solar cell, so the diffusion length 104 00:04:36,300 --> 00:04:38,020 is really long, and all these carriers 105 00:04:38,020 --> 00:04:39,436 that are just generated there will 106 00:04:39,436 --> 00:04:42,660 be able to make our junction. 107 00:04:42,660 --> 00:04:45,600 So again, just so we're familiar, this is our base. 108 00:04:45,600 --> 00:04:47,990 In the top, we have our emitter. 109 00:04:47,990 --> 00:04:51,100 So the junction would be at this line right here on that plane. 110 00:04:53,660 --> 00:04:55,730 If we have a really bad solar cell-- 111 00:04:55,730 --> 00:04:57,940 so let's say a lot of defects present, 112 00:04:57,940 --> 00:05:01,701 a lot of areas for these excited carriers to recombine-- they 113 00:05:01,701 --> 00:05:02,950 won't make it to the junction. 114 00:05:02,950 --> 00:05:06,140 They'll have a very short diffusion length, 115 00:05:06,140 --> 00:05:08,870 and as a result, your short circuit current and your VOC 116 00:05:08,870 --> 00:05:10,410 will suffer dramatically. 117 00:05:10,410 --> 00:05:13,450 So it's really important to get good crystal quality 118 00:05:13,450 --> 00:05:15,960 and good material quality, but up to a certain point. 119 00:05:15,960 --> 00:05:19,602 There's kind of diminishing returns 120 00:05:19,602 --> 00:05:21,310 as you go to higher and higher qualities, 121 00:05:21,310 --> 00:05:22,851 so we'll talk about that in a second. 122 00:05:25,890 --> 00:05:32,220 So if we assume-- what this is showing 123 00:05:32,220 --> 00:05:35,540 is how our short circuit current scales with our diffusion 124 00:05:35,540 --> 00:05:36,490 length. 125 00:05:36,490 --> 00:05:39,330 So we have something called the generation rate, 126 00:05:39,330 --> 00:05:41,780 and this is often proportional to the photon 127 00:05:41,780 --> 00:05:42,970 flux on your material. 128 00:05:42,970 --> 00:05:45,290 So the number of photons hitting your solar cell. 129 00:05:45,290 --> 00:05:47,547 And this generation rate is something-- 130 00:05:47,547 --> 00:05:49,880 the number of carriers produced per second in some given 131 00:05:49,880 --> 00:05:51,320 volume. 132 00:05:51,320 --> 00:05:53,130 So it's a volumetric term. 133 00:05:53,130 --> 00:05:55,420 And if we assume that everything within one diffusion 134 00:05:55,420 --> 00:05:57,820 length of our junction gets collected, 135 00:05:57,820 --> 00:06:00,820 that'll all be counted as short circuit current. 136 00:06:00,820 --> 00:06:02,820 So basically your JSC has this kind 137 00:06:02,820 --> 00:06:05,680 of linear dependence on your diffusion length, 138 00:06:05,680 --> 00:06:07,940 but that's only true up to a certain point. 139 00:06:07,940 --> 00:06:09,940 So for example, if we have a diffusion length 140 00:06:09,940 --> 00:06:11,925 that is much longer than the device thickness. 141 00:06:11,925 --> 00:06:13,800 It's really not going to be-- you get, again, 142 00:06:13,800 --> 00:06:15,940 diminishing returns as you go to longer and longer diffusion 143 00:06:15,940 --> 00:06:16,730 lengths. 144 00:06:16,730 --> 00:06:19,510 So this is a calculation I did using a 1D simulation 145 00:06:19,510 --> 00:06:22,550 program called PC1D, which if you want to play around with, 146 00:06:22,550 --> 00:06:23,590 it's free. 147 00:06:23,590 --> 00:06:25,410 It's a lot of fun to use, actually, 148 00:06:25,410 --> 00:06:29,390 and you can put in things like lifetimes-- 149 00:06:29,390 --> 00:06:31,310 and very basically, the lifetime, which 150 00:06:31,310 --> 00:06:33,080 we'll get to in a second-- how that changes the diffusion 151 00:06:33,080 --> 00:06:33,800 length. 152 00:06:33,800 --> 00:06:36,133 And you can see that there actually is a linear relation 153 00:06:36,133 --> 00:06:39,170 until the diffusion length is about on the order of 300 154 00:06:39,170 --> 00:06:41,071 microns, which is the device thickness. 155 00:06:41,071 --> 00:06:42,820 So you can see this kind of trailing often 156 00:06:42,820 --> 00:06:45,473 and become sub linear in its response. 157 00:06:45,473 --> 00:06:48,311 Yeah? 158 00:06:48,311 --> 00:06:51,839 AUDIENCE: Can you clarify why when the minority carrier 159 00:06:51,839 --> 00:06:53,630 flux at the edge of the space charge region 160 00:06:53,630 --> 00:06:55,920 matters, because I'm thinking about 161 00:06:55,920 --> 00:06:58,290 there's the back contact and the front contact, 162 00:06:58,290 --> 00:07:02,025 and there's a junction right near the front project. 163 00:07:02,025 --> 00:07:04,350 They're not [INAUDIBLE] connecting. 164 00:07:04,350 --> 00:07:07,100 PROFESSOR: So let's think about it one step back. 165 00:07:07,100 --> 00:07:09,570 Why do we care about minority carriers? 166 00:07:09,570 --> 00:07:12,450 AUDIENCE: Because those are the ones that are actually 167 00:07:12,450 --> 00:07:13,890 generating the current. 168 00:07:13,890 --> 00:07:15,514 PROFESSOR: Right, so if, let's say, you 169 00:07:15,514 --> 00:07:18,940 generate an electron hole pair and n-type material, 170 00:07:18,940 --> 00:07:21,900 the hole wants to move to the p-type side. 171 00:07:21,900 --> 00:07:25,170 And the electric field will actually repel and keep 172 00:07:25,170 --> 00:07:31,512 the electron on the n-type side. 173 00:07:31,512 --> 00:07:33,220 So it's your minority carriers the matter 174 00:07:33,220 --> 00:07:34,761 in terms of the separation, and we'll 175 00:07:34,761 --> 00:07:38,060 talk about that again if that's still fuzzy in people's heads. 176 00:07:38,060 --> 00:07:40,600 And so what matters in terms of-- you're 177 00:07:40,600 --> 00:07:43,272 talking about deriving the ideal diode equation? 178 00:07:43,272 --> 00:07:45,677 AUDIENCE: Well, no. [INAUDIBLE]. 179 00:07:45,677 --> 00:07:49,350 So it seems like the important thing is that some carrier gets 180 00:07:49,350 --> 00:07:50,792 to the metallization? 181 00:07:50,792 --> 00:07:52,250 PROFESSOR: Well, yeah, but in order 182 00:07:52,250 --> 00:07:55,810 to be separated, which is the first part that we care about, 183 00:07:55,810 --> 00:07:59,277 it matters that it's reached the junction. 184 00:07:59,277 --> 00:08:01,860 And so it's that concentration at the junction that determines 185 00:08:01,860 --> 00:08:04,265 the flux across the junction. 186 00:08:04,265 --> 00:08:05,140 Does that make sense? 187 00:08:05,140 --> 00:08:05,765 AUDIENCE: Yeah. 188 00:08:09,844 --> 00:08:12,260 PROFESSOR: And so there's also this other loose dependence 189 00:08:12,260 --> 00:08:15,290 on VOC on your diffusion length. 190 00:08:15,290 --> 00:08:17,660 And so if you recall from a few lectures ago, 191 00:08:17,660 --> 00:08:20,350 this is your equation for VOC. 192 00:08:20,350 --> 00:08:23,910 It's dependent on your short circuit current, temperature, 193 00:08:23,910 --> 00:08:27,253 and your saturation current, which you can often think also 194 00:08:27,253 --> 00:08:30,010 think of as your reverse bias current. 195 00:08:30,010 --> 00:08:35,080 And your saturation current is dependent on your diffusion 196 00:08:35,080 --> 00:08:35,750 length. 197 00:08:35,750 --> 00:08:38,770 JSC, if you recall, was linearly proportional 198 00:08:38,770 --> 00:08:40,919 to the diffusion length, so the VOC actually 199 00:08:40,919 --> 00:08:43,381 scales with the natural log of the square of the diffusion 200 00:08:43,381 --> 00:08:43,880 length. 201 00:08:43,880 --> 00:08:46,660 And if you pull out that exponent, 202 00:08:46,660 --> 00:08:50,190 it just squares with the natural log of your diffusion length. 203 00:08:52,750 --> 00:08:55,810 And again, very, very simple analogy-- 204 00:08:55,810 --> 00:08:59,100 we're assuming, again, that fill factor is not really affected 205 00:08:59,100 --> 00:09:02,830 by your diffusion length and that your efficiency is 206 00:09:02,830 --> 00:09:07,110 proportional to the product of your JSC and your VOC, 207 00:09:07,110 --> 00:09:10,390 so your short circuit current and your open circuit voltage. 208 00:09:10,390 --> 00:09:13,290 And you can see as go to longer diffusion lengths, 209 00:09:13,290 --> 00:09:15,490 there's this area of diminishing return. 210 00:09:15,490 --> 00:09:19,050 And again, there's two different regimes here. 211 00:09:19,050 --> 00:09:21,360 One is when your diffusion length is, again, much less 212 00:09:21,360 --> 00:09:22,150 than your device thickness. 213 00:09:22,150 --> 00:09:24,680 You can see that there's a huge increase in efficiency, 214 00:09:24,680 --> 00:09:26,580 but as your diffusion length gets well, 215 00:09:26,580 --> 00:09:28,405 well above your device thickness, 216 00:09:28,405 --> 00:09:29,990 it becomes less and less important. 217 00:09:40,100 --> 00:09:42,300 So how do you deal with this? 218 00:09:42,300 --> 00:09:44,030 So if you have, let's say-- suppose 219 00:09:44,030 --> 00:09:45,950 you want to make a really cheap solar cell, 220 00:09:45,950 --> 00:09:48,240 and you have a very dirty material 221 00:09:48,240 --> 00:09:50,010 with very short lifetime shown here. 222 00:09:50,010 --> 00:09:53,440 There's several ideas of what you can do. 223 00:09:53,440 --> 00:09:57,710 You can have a very, very thin device. 224 00:09:57,710 --> 00:10:00,220 Now, that's a problem if you can't absorb it very well. 225 00:10:00,220 --> 00:10:02,160 So you can have some optical tricks. 226 00:10:02,160 --> 00:10:03,580 You can do surface texturing. 227 00:10:03,580 --> 00:10:06,680 There's all sorts of other ideas for basically having 228 00:10:06,680 --> 00:10:08,940 the carriers coming in at angles or having 229 00:10:08,940 --> 00:10:11,830 a good reflector on the back. 230 00:10:11,830 --> 00:10:15,920 So that's ways you can work with very low diffusion length 231 00:10:15,920 --> 00:10:22,390 materials and still get a device efficiency that's not too bad. 232 00:10:22,390 --> 00:10:25,846 Now we're going to talk quickly about how our minority carrier 233 00:10:25,846 --> 00:10:27,720 diffusion length is measured, and again, this 234 00:10:27,720 --> 00:10:30,120 is something we're able to do in our lab. 235 00:10:30,120 --> 00:10:34,430 And one of the important things to say is defined 236 00:10:34,430 --> 00:10:35,770 is collection probability. 237 00:10:35,770 --> 00:10:38,210 So for example, if this is our junction 238 00:10:38,210 --> 00:10:41,820 right here-- so our space charge region-- 239 00:10:41,820 --> 00:10:44,300 if you generate a carrier, let's say very, very close 240 00:10:44,300 --> 00:10:47,440 to the junction, it's going to have a high or near unity 241 00:10:47,440 --> 00:10:50,930 probability of making it to the junction and being collected. 242 00:10:50,930 --> 00:10:53,090 If it's generated very, very, very far away, 243 00:10:53,090 --> 00:10:54,720 it's going to have a lower probability. 244 00:10:54,720 --> 00:10:55,660 And that's what this graph is trying 245 00:10:55,660 --> 00:10:58,201 to show-- is that right near the junction you have near unity 246 00:10:58,201 --> 00:11:01,490 collection probability, and as you go way, it comes down. 247 00:11:01,490 --> 00:11:03,290 And the different colored lines are 248 00:11:03,290 --> 00:11:08,940 showing different ways of increasing that diffusion 249 00:11:08,940 --> 00:11:09,440 length. 250 00:11:09,440 --> 00:11:10,890 Service passivation is important. 251 00:11:10,890 --> 00:11:12,387 We'll talk about what that is soon. 252 00:11:12,387 --> 00:11:13,970 And also diffusion lengths-- if you're 253 00:11:13,970 --> 00:11:15,860 limited by diffusion length, you can see 254 00:11:15,860 --> 00:11:20,105 this very, very sharp drop off. 255 00:11:20,105 --> 00:11:22,101 AUDIENCE: Just a follow up. 256 00:11:22,101 --> 00:11:27,550 So is collection meaning collected by the front contact 257 00:11:27,550 --> 00:11:31,580 to be used in your external circuit? 258 00:11:31,580 --> 00:11:33,612 PROFESSOR: Mm-hm. 259 00:11:33,612 --> 00:11:35,070 Right here it's technically defined 260 00:11:35,070 --> 00:11:37,360 as reaching the junction and being separated, 261 00:11:37,360 --> 00:11:39,858 which, in essence, will hopefully be the same thing. 262 00:11:39,858 --> 00:11:44,340 AUDIENCE: So is surface passivation [INAUDIBLE] 263 00:11:44,340 --> 00:11:46,830 sort of like diffusion? 264 00:11:46,830 --> 00:11:49,010 PROFESSOR: It can affect the diffusion length, 265 00:11:49,010 --> 00:11:51,360 and we'll-- or the affect of diffusion length. 266 00:11:51,360 --> 00:11:53,056 We'll to that in a second. 267 00:11:53,056 --> 00:11:53,930 It'll be a bit later. 268 00:11:53,930 --> 00:11:55,270 This is kind of just showing that there's 269 00:11:55,270 --> 00:11:56,790 a lot of different material parameters-- 270 00:11:56,790 --> 00:11:58,880 not just your diffusion length-- that can really 271 00:11:58,880 --> 00:12:00,510 affect your device performance and your collection 272 00:12:00,510 --> 00:12:01,010 probability. 273 00:12:04,760 --> 00:12:06,317 So if you recall a few slides back, 274 00:12:06,317 --> 00:12:07,900 we said that our short circuit current 275 00:12:07,900 --> 00:12:10,172 is directly proportional to our diffusion length. 276 00:12:10,172 --> 00:12:12,380 And the reason is that, if you're generating carriers 277 00:12:12,380 --> 00:12:14,130 within the diffusion length, you generally 278 00:12:14,130 --> 00:12:16,296 think of that as the region of which you're actually 279 00:12:16,296 --> 00:12:17,450 collecting those carriers. 280 00:12:17,450 --> 00:12:19,783 And if you go back to the next slide, that kind of makes 281 00:12:19,783 --> 00:12:21,980 sense. 282 00:12:21,980 --> 00:12:23,202 So this is highlighted. 283 00:12:23,202 --> 00:12:24,410 So this is our junction here. 284 00:12:24,410 --> 00:12:28,760 We have our n-type material on top, our p-type below. 285 00:12:28,760 --> 00:12:31,470 And within a diffusion length of your minority carrier-- 286 00:12:31,470 --> 00:12:34,095 so on your p-type type side you care about the diffusion length 287 00:12:34,095 --> 00:12:34,889 of your electrons. 288 00:12:34,889 --> 00:12:37,180 On the n-type side, you care about the diffusion length 289 00:12:37,180 --> 00:12:39,750 of your holes, and that's the region where you're really 290 00:12:39,750 --> 00:12:40,870 collecting carriers. 291 00:12:40,870 --> 00:12:43,289 Of course, there's a tail off, but the first order 292 00:12:43,289 --> 00:12:45,330 approximation-- this is actually a very good one. 293 00:12:48,400 --> 00:12:50,540 And so now putting those all together. 294 00:12:50,540 --> 00:12:54,460 If we know how our carriers are generated 295 00:12:54,460 --> 00:12:57,800 as a function of x, and we what the collection probability is 296 00:12:57,800 --> 00:13:00,300 as a function of x based on diffusion length, surface 297 00:13:00,300 --> 00:13:02,270 passivation, and other parameters, 298 00:13:02,270 --> 00:13:04,800 we can multiply them and then integrate 299 00:13:04,800 --> 00:13:07,940 to actually get what our illuminated current will be. 300 00:13:07,940 --> 00:13:08,440 Yeah? 301 00:13:08,440 --> 00:13:10,314 AUDIENCE: [INAUDIBLE] have like three regimes 302 00:13:10,314 --> 00:13:13,390 because the diffusivities are different at each [INAUDIBLE]. 303 00:13:16,382 --> 00:13:17,340 PROFESSOR: The emitter? 304 00:13:17,340 --> 00:13:19,915 AUDIENCE: [INAUDIBLE] the junction afterwards? 305 00:13:19,915 --> 00:13:21,237 PROFESSOR: Mm-hm. 306 00:13:21,237 --> 00:13:22,820 For most models you pretty much assume 307 00:13:22,820 --> 00:13:24,610 that anything absorbed-- first of all, 308 00:13:24,610 --> 00:13:27,960 the space charge region is very, very narrow. 309 00:13:27,960 --> 00:13:30,980 It's almost assumed just to be negligibly thin. 310 00:13:30,980 --> 00:13:34,900 And the emitter is generally very, very short, 311 00:13:34,900 --> 00:13:37,910 and the diffusion lengths are so poor in the emitter for reasons 312 00:13:37,910 --> 00:13:41,170 we'll get to soon that it's almost a dead layer. 313 00:13:41,170 --> 00:13:43,130 Your response, the very short wavelengths, 314 00:13:43,130 --> 00:13:45,527 where you're absorbing most of your light and emitter 315 00:13:45,527 --> 00:13:47,610 generally don't add to your short circuit current, 316 00:13:47,610 --> 00:13:49,110 and we'll talk about that soon. 317 00:13:49,110 --> 00:13:50,160 So excellent question. 318 00:13:50,160 --> 00:13:50,962 Yeah? 319 00:13:50,962 --> 00:13:52,230 AUDIENCE: Is that first region right there-- 320 00:13:52,230 --> 00:13:52,520 PROFESSOR: Wait, sorry. 321 00:13:52,520 --> 00:13:53,030 Say that again. 322 00:13:53,030 --> 00:13:53,530 I couldn't-- 323 00:13:53,530 --> 00:13:55,640 AUDIENCE: People just approximate the first region 324 00:13:55,640 --> 00:13:58,082 there and not care about [INAUDIBLE] afterwards? 325 00:13:58,082 --> 00:14:00,040 PROFESSOR: So for certain wavelengths of light, 326 00:14:00,040 --> 00:14:03,640 let's say, that are-- this curve, 327 00:14:03,640 --> 00:14:06,850 this is kind of representing Beer Lambert's law. 328 00:14:06,850 --> 00:14:10,920 If it attenuates less drastically, 329 00:14:10,920 --> 00:14:12,690 that characteristic absorption length, 330 00:14:12,690 --> 00:14:15,600 if it's a lot longer than this length here, then yes. 331 00:14:15,600 --> 00:14:18,710 You can assume that this emitter region is negligibly thin, 332 00:14:18,710 --> 00:14:20,835 and that's a little bit what the homework goes over 333 00:14:20,835 --> 00:14:21,980 as well in problem three. 334 00:14:21,980 --> 00:14:24,590 Excellent question. 335 00:14:24,590 --> 00:14:29,270 And so what we care about is the spectral response 336 00:14:29,270 --> 00:14:30,850 of our short circuit current. 337 00:14:30,850 --> 00:14:33,330 So what this is is this a quantum efficiency tool. 338 00:14:33,330 --> 00:14:35,280 This is something we have in our lab. 339 00:14:35,280 --> 00:14:38,750 It's a really fun tool to play around with. 340 00:14:38,750 --> 00:14:42,610 How it works is you basically have-- 341 00:14:42,610 --> 00:14:45,740 we have a light source that's white light, 342 00:14:45,740 --> 00:14:47,470 and it goes through a series of filters. 343 00:14:47,470 --> 00:14:51,620 There's a monochromator, which basically-- it 344 00:14:51,620 --> 00:14:53,250 diffracts the light, so it spatially 345 00:14:53,250 --> 00:14:56,050 separates the light, kind of like a rainbow. 346 00:14:56,050 --> 00:14:59,900 And then you can focus that onto your solar cell 347 00:14:59,900 --> 00:15:03,210 and measure the current output under short circuit conditions. 348 00:15:03,210 --> 00:15:07,320 And that will tell you-- because you know the carrier generation 349 00:15:07,320 --> 00:15:09,950 profile for different wavelengths of light, 350 00:15:09,950 --> 00:15:12,497 because you know what alpha is for silicon, 351 00:15:12,497 --> 00:15:14,080 you can actually pretty well calculate 352 00:15:14,080 --> 00:15:18,142 what your diffusion length is, and we'll 353 00:15:18,142 --> 00:15:19,350 talk about on the next slide. 354 00:15:19,350 --> 00:15:22,760 So this is kind of what your quantum efficiency will 355 00:15:22,760 --> 00:15:23,260 look like. 356 00:15:23,260 --> 00:15:25,284 This is, I think-- I actually don't 357 00:15:25,284 --> 00:15:26,700 know if this internal or external, 358 00:15:26,700 --> 00:15:31,280 but they're just related by a factor of 1 over r. 359 00:15:31,280 --> 00:15:34,171 So here you're blue response-- so everything 360 00:15:34,171 --> 00:15:36,170 that's absorbed right in the near surface region 361 00:15:36,170 --> 00:15:38,470 in your emitter generally doesn't get collected, 362 00:15:38,470 --> 00:15:40,260 and this is due to really bad diffusion 363 00:15:40,260 --> 00:15:43,240 lengths in the emitter region. 364 00:15:43,240 --> 00:15:47,820 As you go to longer wavelengths, the absorption length 365 00:15:47,820 --> 00:15:49,706 is much, much deeper. 366 00:15:49,706 --> 00:15:52,080 You're collecting a lot of it, and then what do you think 367 00:15:52,080 --> 00:15:53,030 is happening here? 368 00:15:57,070 --> 00:15:59,420 Generally these longer wavelengths-- your alpha 369 00:15:59,420 --> 00:16:01,340 is so low that you're not actually 370 00:16:01,340 --> 00:16:03,150 absorbing much of this light, which 371 00:16:03,150 --> 00:16:04,820 is part of the reason that you're not collecting it, 372 00:16:04,820 --> 00:16:07,195 or that you're absorbing it so far away from the junction 373 00:16:07,195 --> 00:16:09,450 that it's not being able to diffuse there. 374 00:16:09,450 --> 00:16:13,534 And so that's kind of how you can 375 00:16:13,534 --> 00:16:15,200 look at these quantum efficiency curves, 376 00:16:15,200 --> 00:16:16,800 and it's this region here that's really 377 00:16:16,800 --> 00:16:17,966 limited by diffusion length. 378 00:16:17,966 --> 00:16:19,756 And again, you have a homework problem 379 00:16:19,756 --> 00:16:20,880 discussing how that's done. 380 00:16:23,750 --> 00:16:26,840 Some of the cool other tools-- the lab can kind of do this, 381 00:16:26,840 --> 00:16:30,360 but it requires a little more-- I don't know-- 382 00:16:30,360 --> 00:16:31,920 hand work on the operator. 383 00:16:31,920 --> 00:16:35,650 But if you can take different EQE or I IQE 384 00:16:35,650 --> 00:16:39,002 curves at different points on your solar cell 385 00:16:39,002 --> 00:16:40,460 and you get those spectrums, you'll 386 00:16:40,460 --> 00:16:42,168 get a whole bunch of different spectrums. 387 00:16:42,168 --> 00:16:45,347 You'll scan with your light beam. 388 00:16:45,347 --> 00:16:46,930 You can actually get diffusion lengths 389 00:16:46,930 --> 00:16:49,260 as a function of position and get 390 00:16:49,260 --> 00:16:51,520 a spatial map of your different diffusion lengths. 391 00:16:51,520 --> 00:16:52,930 And it's really helpful if you're 392 00:16:52,930 --> 00:16:55,440 trying to fine spatial inhomogeneities in your cell. 393 00:16:55,440 --> 00:16:58,690 So I believe that this is some multi-crystalline cell, 394 00:16:58,690 --> 00:17:00,770 and see all sorts of grain boundaries. 395 00:17:00,770 --> 00:17:03,390 And those are areas of very short diffusion length, 396 00:17:03,390 --> 00:17:07,530 and we'll talk about why that's the case, actually, 397 00:17:07,530 --> 00:17:08,740 on the next couple slides. 398 00:17:08,740 --> 00:17:09,030 Question? 399 00:17:09,030 --> 00:17:09,240 Yeah? 400 00:17:09,240 --> 00:17:11,240 AUDIENCE: Could you just clarify the difference 401 00:17:11,240 --> 00:17:15,490 between diffusion length, absorption length, and band 402 00:17:15,490 --> 00:17:16,240 depth energy? 403 00:17:16,240 --> 00:17:19,240 Because I thought that the middle weight ones were more 404 00:17:19,240 --> 00:17:21,240 absorbed because they were bent? 405 00:17:21,240 --> 00:17:26,080 Their higher weight [INAUDIBLE] for bigger-- to cross 406 00:17:26,080 --> 00:17:28,530 bigger band depth energies. 407 00:17:28,530 --> 00:17:32,780 I didn't think it was because of the absorption [INAUDIBLE]. 408 00:17:32,780 --> 00:17:36,540 PROFESSOR: So alpha is what tells you is your absorption 409 00:17:36,540 --> 00:17:40,860 coefficient, and it's often in units of one over centimeters, 410 00:17:40,860 --> 00:17:42,350 so inverse centimeters. 411 00:17:42,350 --> 00:17:45,410 And so if you plot what that looks like, 412 00:17:45,410 --> 00:17:50,880 it's an exponential function with x. 413 00:17:50,880 --> 00:17:52,760 And the point to which it is attenuated 414 00:17:52,760 --> 00:17:57,410 by a factor of one over e, that point is 1 over alpha. 415 00:17:57,410 --> 00:18:03,070 And that's often called the absorption depth 416 00:18:03,070 --> 00:18:05,690 or-- what am I thinking of? 417 00:18:05,690 --> 00:18:08,070 Absorption length of that wavelength. 418 00:18:08,070 --> 00:18:10,250 And alpha will vary as a function of wavelength. 419 00:18:10,250 --> 00:18:16,695 If you recall that, if you look at lambda, for silicon, 420 00:18:16,695 --> 00:18:20,030 it's something that continues to go down at longer wavelengths. 421 00:18:20,030 --> 00:18:22,480 So the short wavelengths are absorbed very strongly, 422 00:18:22,480 --> 00:18:26,180 and so most of the light is absorbed very, very close 423 00:18:26,180 --> 00:18:31,649 to the surface, where the longer wavelengths-- most of the light 424 00:18:31,649 --> 00:18:33,690 is actually absorbed rather far from the surface. 425 00:18:33,690 --> 00:18:35,350 Does that make sense? 426 00:18:35,350 --> 00:18:38,130 And so there's a difference between your absorption length 427 00:18:38,130 --> 00:18:40,040 and your diffusion length, and that ratio 428 00:18:40,040 --> 00:18:41,260 is what's really important. 429 00:18:41,260 --> 00:18:45,620 If you're absorbing really far away from the junction, 430 00:18:45,620 --> 00:18:47,250 but you have a long diffusion length, 431 00:18:47,250 --> 00:18:49,490 there's a greater chance of it making there. 432 00:18:49,490 --> 00:18:51,830 And it's that ratio that's really, really important. 433 00:18:51,830 --> 00:18:52,440 Does that answer your question? 434 00:18:52,440 --> 00:18:52,930 AUDIENCE: Yeah. 435 00:18:52,930 --> 00:18:53,513 PROFESSOR: OK. 436 00:18:56,890 --> 00:18:59,204 So what limits this minority carrier diffusion length? 437 00:18:59,204 --> 00:19:00,620 We're going to get to the equation 438 00:19:00,620 --> 00:19:03,030 in a second for the minority carrier diffusion length, 439 00:19:03,030 --> 00:19:05,900 but basically when you excite an electron hole pair, 440 00:19:05,900 --> 00:19:09,610 you have this mobile electron, and it's in this excited state. 441 00:19:09,610 --> 00:19:11,360 You've given it this energy from a photon, 442 00:19:11,360 --> 00:19:13,152 and now it can move around, and it can only 443 00:19:13,152 --> 00:19:14,568 exist for a certain amount of time 444 00:19:14,568 --> 00:19:16,660 before it finds another whole and recombines. 445 00:19:16,660 --> 00:19:20,320 And that event, again, is called recombination. 446 00:19:20,320 --> 00:19:24,580 And a lot of this is actually determined by the size 447 00:19:24,580 --> 00:19:25,750 of grains in your material. 448 00:19:25,750 --> 00:19:28,419 If you've seen-- I think on the cell 449 00:19:28,419 --> 00:19:30,210 that [INAUDIBLE] brought in earlier-- sorry 450 00:19:30,210 --> 00:19:33,620 I don't have a good example-- it didn't just look 451 00:19:33,620 --> 00:19:34,910 like one kind of flat plane. 452 00:19:34,910 --> 00:19:37,720 You could see different grain orientations, 453 00:19:37,720 --> 00:19:40,470 and the edges of those grains are called grain boundaries, 454 00:19:40,470 --> 00:19:43,590 and those can act as recombination centers 455 00:19:43,590 --> 00:19:45,980 and actually reduce your-- it's called 456 00:19:45,980 --> 00:19:48,970 your lifetime, which we're going to get to on this slide. 457 00:19:52,920 --> 00:19:58,360 So this slide has a lot of stuff going on. 458 00:19:58,360 --> 00:20:00,900 What it's saying is that your diffusion length 459 00:20:00,900 --> 00:20:05,350 is characteristic of the diffusivity-- 460 00:20:05,350 --> 00:20:07,520 the square root of the product of your diffusivity 461 00:20:07,520 --> 00:20:10,180 in your lifetime. 462 00:20:10,180 --> 00:20:12,000 The way I like to think of diffusivity 463 00:20:12,000 --> 00:20:17,120 is that it goes up with temperature, 464 00:20:17,120 --> 00:20:19,000 and it's also affected by your mobility. 465 00:20:19,000 --> 00:20:21,300 The mobility is saying that, if you apply, 466 00:20:21,300 --> 00:20:24,090 let's say, an external field, and electric field, 467 00:20:24,090 --> 00:20:27,190 how well can those electrons move around? 468 00:20:27,190 --> 00:20:30,590 So a really high mobility means that those electrons can 469 00:20:30,590 --> 00:20:33,174 move really easily, and you'll accelerate them really quickly, 470 00:20:33,174 --> 00:20:34,715 where very low mobility means they're 471 00:20:34,715 --> 00:20:36,390 going to continue to hit into things, 472 00:20:36,390 --> 00:20:40,240 and bump around, and not move around too well. 473 00:20:40,240 --> 00:20:43,880 And your diffusion is this kind of thermal process. 474 00:20:43,880 --> 00:20:46,730 If you think of, let's say, gases in a room, 475 00:20:46,730 --> 00:20:49,860 and you have a hot gas, that's going to diffuse a lot faster. 476 00:20:49,860 --> 00:20:51,870 So it's the product of these two things. 477 00:20:51,870 --> 00:20:53,840 It's how well it can move around times 478 00:20:53,840 --> 00:20:57,530 it's thermal energy that it has to move around, 479 00:20:57,530 --> 00:20:59,220 the energy it has for moving. 480 00:20:59,220 --> 00:21:03,300 And so that's kind of what the diffusivity means to me. 481 00:21:03,300 --> 00:21:05,360 The lifetime, again, is what I mentioned 482 00:21:05,360 --> 00:21:07,570 earlier-- is that when you create this excited 483 00:21:07,570 --> 00:21:13,180 electron that's now free to move, this mobile electron, 484 00:21:13,180 --> 00:21:16,580 it can move around and explore a certain area, that area. 485 00:21:16,580 --> 00:21:19,480 Volume is defined by the diffusion length. 486 00:21:19,480 --> 00:21:23,160 And it exists in that excited state for some amount of time, 487 00:21:23,160 --> 00:21:26,889 tau, and that tau is not-- not every carrier that 488 00:21:26,889 --> 00:21:28,680 is generated necessarily has that lifetime, 489 00:21:28,680 --> 00:21:34,080 but it's a characteristic lifetime that it could have. 490 00:21:34,080 --> 00:21:36,080 And then they're pointed out here what they are. 491 00:21:40,350 --> 00:21:42,850 So that's what affects our diffusion length. 492 00:21:42,850 --> 00:21:44,580 So in the next bunch of slides, we're 493 00:21:44,580 --> 00:21:48,280 going to talk about mainly how we can affect tau. 494 00:21:48,280 --> 00:21:52,470 So tau is mainly affected by recombination centers-- so 495 00:21:52,470 --> 00:21:56,260 defects, and semiconductors, and a few other things 496 00:21:56,260 --> 00:21:57,580 that we're going to talk about. 497 00:21:57,580 --> 00:22:00,590 And then this is almost limited depending 498 00:22:00,590 --> 00:22:03,630 on what kind of materials you're using, the mobility, 499 00:22:03,630 --> 00:22:06,060 and so we'll talk about that, as well. 500 00:22:06,060 --> 00:22:08,250 So what affects lifetime? 501 00:22:08,250 --> 00:22:11,322 We're going to go over, again, basic recombination 502 00:22:11,322 --> 00:22:12,530 mechanisms in semiconductors. 503 00:22:12,530 --> 00:22:13,880 There's a lot of them. 504 00:22:13,880 --> 00:22:21,250 A lot of them have some rather complex equations behind them. 505 00:22:21,250 --> 00:22:24,207 We're not going to delve too deeply into how to derive them. 506 00:22:24,207 --> 00:22:25,290 You're welcome to do that. 507 00:22:25,290 --> 00:22:27,890 It was actually kind of fun to do on my own 508 00:22:27,890 --> 00:22:30,340 and refresh myself, so it was really useful-- 509 00:22:30,340 --> 00:22:32,340 and also be able to calculate our excess carrier 510 00:22:32,340 --> 00:22:34,387 concentration, which we're going to do 511 00:22:34,387 --> 00:22:35,470 in the next couple slides. 512 00:22:35,470 --> 00:22:43,700 So n-- let's say for n-type material, 513 00:22:43,700 --> 00:22:47,820 the number of mobile electrons you have is defined as n. 514 00:22:47,820 --> 00:22:52,984 n0 is very frequently your doping density-- 515 00:22:52,984 --> 00:22:54,150 these come up one at a time. 516 00:22:54,150 --> 00:22:54,850 Sorry. 517 00:22:54,850 --> 00:22:58,714 Wrong direction-- are generally the doping concentration. 518 00:22:58,714 --> 00:23:00,380 So if you're putting in phosphorus atoms 519 00:23:00,380 --> 00:23:02,380 into your silicon, it would be the concentration 520 00:23:02,380 --> 00:23:03,680 of phosphorus atoms. 521 00:23:03,680 --> 00:23:06,470 Your delta n is how many extra electrons 522 00:23:06,470 --> 00:23:08,420 are you adding, mobile electrons, 523 00:23:08,420 --> 00:23:10,780 due to the photo excitation of light. 524 00:23:10,780 --> 00:23:12,670 And so that's what this is saying-- 525 00:23:12,670 --> 00:23:14,810 is that you have some-- your delta n is 526 00:23:14,810 --> 00:23:16,150 equal to your generation rate. 527 00:23:16,150 --> 00:23:17,670 So your generation rate is generally 528 00:23:17,670 --> 00:23:20,950 in units of carriers per volume per second-- 529 00:23:20,950 --> 00:23:24,580 so how many carries you're generating in a certain volume. 530 00:23:24,580 --> 00:23:28,980 And because delta n is actually a density, 531 00:23:28,980 --> 00:23:31,190 you need to say, OK, how long do those carriers last 532 00:23:31,190 --> 00:23:32,200 once they're excited? 533 00:23:32,200 --> 00:23:35,056 And so it's the g tau product is what gives you your delta n. 534 00:23:38,322 --> 00:23:40,530 Now, when working with silicon, it's really important 535 00:23:40,530 --> 00:23:42,670 to understand what the different ratios are 536 00:23:42,670 --> 00:23:46,004 of n, n0, delta n, the doping concentrations. 537 00:23:46,004 --> 00:23:47,920 So getting these relative numbers in your head 538 00:23:47,920 --> 00:23:50,140 is an important step in moving forward. 539 00:23:50,140 --> 00:23:54,840 So let's say we subject a piece of silicon to AM1.5 spectra. 540 00:23:58,810 --> 00:24:03,460 So your G-- sorry. 541 00:24:03,460 --> 00:24:05,750 This is a little off. 542 00:24:05,750 --> 00:24:07,800 There we go. 543 00:24:07,800 --> 00:24:08,590 Sorry about that. 544 00:24:08,590 --> 00:24:13,270 When I added some equations-- so your generation rate is 545 00:24:13,270 --> 00:24:16,300 on the order of 10 to the 16th. 546 00:24:16,300 --> 00:24:19,080 A care lifetime for silicon-- this is not a great lifetime, 547 00:24:19,080 --> 00:24:21,340 but an OK one-- is about 10 microseconds. 548 00:24:21,340 --> 00:24:23,540 And so as a result of that, you'll get about 10 549 00:24:23,540 --> 00:24:30,300 to the 11th excess carriers per centimeter cubed. 550 00:24:32,910 --> 00:24:37,379 And if we compare that-- so for every excess electron we make, 551 00:24:37,379 --> 00:24:38,920 remember we also leave behind a hole. 552 00:24:38,920 --> 00:24:43,230 So we have delta n is generally equal to delta p. 553 00:24:43,230 --> 00:24:45,630 And that's about 10 to the 11th. 554 00:24:45,630 --> 00:24:47,760 If we look at our intrinsic carrier concentration-- 555 00:24:47,760 --> 00:24:51,830 so if we had no dopants, how many carriers 556 00:24:51,830 --> 00:24:53,637 would we have just for thermal excitation? 557 00:24:53,637 --> 00:24:54,970 And that's about 10 to the 10th. 558 00:24:54,970 --> 00:24:58,220 And so you can see that delta n is actually 559 00:24:58,220 --> 00:25:00,030 larger than your intrinsic carrier 560 00:25:00,030 --> 00:25:04,285 concentration for silicon under normal illumination conditions. 561 00:25:04,285 --> 00:25:05,410 Now, let's take an example. 562 00:25:05,410 --> 00:25:08,730 Suppose we add phosphorus at the order about 10 to the 16th, 563 00:25:08,730 --> 00:25:13,294 and so that's generally about what a base doping 564 00:25:13,294 --> 00:25:14,960 concentration should be-- in that realm. 565 00:25:14,960 --> 00:25:16,376 It might be a little high, but you 566 00:25:16,376 --> 00:25:21,220 can see that your delta p is much greater than p0. 567 00:25:21,220 --> 00:25:24,300 So p0 would be how many holes do you have, 568 00:25:24,300 --> 00:25:27,069 which is a ratio of your intrinsic carrier squared 569 00:25:27,069 --> 00:25:28,110 over your doping density. 570 00:25:28,110 --> 00:25:30,370 And that's about 10 to the fourth, so it's way, way 571 00:25:30,370 --> 00:25:35,680 less than what was there without excitation. 572 00:25:35,680 --> 00:25:39,890 So the number of holes without any light shining on it is p0. 573 00:25:39,890 --> 00:25:42,280 You generate a bunch of holes, delta p, 574 00:25:42,280 --> 00:25:43,990 by shining light on it, and you can 575 00:25:43,990 --> 00:25:47,874 see that these numbers are drastically different. 576 00:25:47,874 --> 00:25:49,290 And of course, your doping density 577 00:25:49,290 --> 00:25:54,000 is actually much, much larger than your delta n. 578 00:25:54,000 --> 00:25:56,300 Your majority carriers don't change very much, 579 00:25:56,300 --> 00:25:58,675 but your minority carriers change very, very drastically. 580 00:25:58,675 --> 00:26:00,049 That's really what this is trying 581 00:26:00,049 --> 00:26:01,315 to say here under excitation. 582 00:26:05,850 --> 00:26:07,760 What is lifetime? 583 00:26:07,760 --> 00:26:09,720 So that bubble shouldn't be up yet. 584 00:26:13,140 --> 00:26:17,460 So we measure tau by creating some excess carrier population 585 00:26:17,460 --> 00:26:20,330 and then watch them decay. 586 00:26:20,330 --> 00:26:24,060 And they decay at some rate, recombination rate, 587 00:26:24,060 --> 00:26:26,630 and under steady state conditions-- 588 00:26:26,630 --> 00:26:28,350 so under constant illumination, we're 589 00:26:28,350 --> 00:26:32,650 not looking at transients-- your recombination rate is actually 590 00:26:32,650 --> 00:26:34,005 equal to your generation rate. 591 00:26:34,005 --> 00:26:35,510 So if you compare the two equations 592 00:26:35,510 --> 00:26:38,390 on the previous slide, they're true under steady state 593 00:26:38,390 --> 00:26:38,890 conditions. 594 00:26:42,644 --> 00:26:43,810 [INAUDIBLE] going to pop up. 595 00:26:46,500 --> 00:26:49,630 And so your lifetimes add up like parallel resistors. 596 00:26:49,630 --> 00:26:52,360 So we have tau bulk, which is kind 597 00:26:52,360 --> 00:26:54,935 of the effective lifetime of these photo excited carriers. 598 00:26:58,910 --> 00:27:01,120 1 over tau bulk is equal to 1 over tau radiative, 599 00:27:01,120 --> 00:27:03,370 so this is radiative recombination. 600 00:27:03,370 --> 00:27:05,500 And this has to do with-- basically if you 601 00:27:05,500 --> 00:27:08,610 read the Shockley-Queisser efficiency limit paper, 602 00:27:08,610 --> 00:27:11,270 this is the lifetime that they assume was limiting. 603 00:27:11,270 --> 00:27:13,480 And for silicon, this is absurd. 604 00:27:13,480 --> 00:27:15,200 This is never ever the limiting factor. 605 00:27:15,200 --> 00:27:17,240 And a lot of direct band gap materials-- for those of you 606 00:27:17,240 --> 00:27:19,323 who don't know what that is, don't worry about it. 607 00:27:19,323 --> 00:27:22,140 That's often the limiting factor, 608 00:27:22,140 --> 00:27:24,440 and it has to do with the absorption is always 609 00:27:24,440 --> 00:27:27,230 equal to the emissivity in a material. 610 00:27:27,230 --> 00:27:28,930 AUDIENCE: [INAUDIBLE]? 611 00:27:28,930 --> 00:27:30,680 PROFESSOR: For a direct band gap material, 612 00:27:30,680 --> 00:27:33,190 radiative recombination can be an issue, 613 00:27:33,190 --> 00:27:36,720 and I'll talk about that in a second. 614 00:27:36,720 --> 00:27:39,160 And there's also another combination 615 00:27:39,160 --> 00:27:41,410 called Auger recombination. 616 00:27:41,410 --> 00:27:43,870 It's not "Oger" like I thought when I first came here. 617 00:27:43,870 --> 00:27:47,720 It's "O-jay," kind of like-- I don't know-- OJ Simpson, 618 00:27:47,720 --> 00:27:48,462 I guess. 619 00:27:48,462 --> 00:27:50,190 [LAUGHTER] 620 00:27:50,190 --> 00:27:53,650 And it's dominant only under very high injection conditions 621 00:27:53,650 --> 00:27:54,950 or very high doping density. 622 00:27:54,950 --> 00:27:57,397 So in your emitter layer where there's really, really high 623 00:27:57,397 --> 00:27:58,980 doping densities, you're going to have 624 00:27:58,980 --> 00:28:00,800 a lot of Auger recombination. 625 00:28:00,800 --> 00:28:03,381 And the last one is Shockley-Read-Hall 626 00:28:03,381 --> 00:28:04,380 So these are three guys. 627 00:28:04,380 --> 00:28:10,450 They came up with this kind of a model for how recombination 628 00:28:10,450 --> 00:28:14,790 happens in defective materials-- so materials 629 00:28:14,790 --> 00:28:18,740 with levels, electronic levels, in the mid-gap. 630 00:28:18,740 --> 00:28:20,690 And again, these add like parallel resistors, 631 00:28:20,690 --> 00:28:22,910 so you're always-- so if you remember back 632 00:28:22,910 --> 00:28:26,770 to the leaky bucket, these your leaky buckets for diffusion 633 00:28:26,770 --> 00:28:27,510 length. 634 00:28:27,510 --> 00:28:30,360 You're always limited by your shortest diffusion length-- 635 00:28:30,360 --> 00:28:32,740 or, sorry, your shortest lifetime. 636 00:28:32,740 --> 00:28:35,955 And this is often your limiting lifetime-- 637 00:28:35,955 --> 00:28:38,284 is your Shockley--Read--Hall recombination. 638 00:28:38,284 --> 00:28:41,210 AUDIENCE: Is it for silicon and for [INAUDIBLE]? 639 00:28:41,210 --> 00:28:42,210 PROFESSOR: For silicon-- 640 00:28:42,210 --> 00:28:43,132 AUDIENCE: [INAUDIBLE]. 641 00:28:43,132 --> 00:28:46,907 The Shockley-Read-Hall is the [INAUDIBLE]. 642 00:28:46,907 --> 00:28:48,490 PROFESSOR: So radiative recombination. 643 00:28:48,490 --> 00:28:50,560 So you can probably guess from the name 644 00:28:50,560 --> 00:28:54,110 that radiative recombination involves a photon. 645 00:28:54,110 --> 00:28:55,940 The ability to absorb photons also 646 00:28:55,940 --> 00:28:57,870 means you have the ability to emit them, 647 00:28:57,870 --> 00:29:00,820 and so silicon, or many semiconductors, 648 00:29:00,820 --> 00:29:05,010 will emit photons when you get a recombination 649 00:29:05,010 --> 00:29:06,640 event across the band. 650 00:29:06,640 --> 00:29:12,170 And when that happens, you emit a photon under equilibrium. 651 00:29:12,170 --> 00:29:14,454 So equilibrium means no outside excitation. 652 00:29:14,454 --> 00:29:16,620 It doesn't mean steady state, so this is, let's say, 653 00:29:16,620 --> 00:29:18,640 in the dark. 654 00:29:18,640 --> 00:29:22,292 You get your recombination rate is equal to your generation 655 00:29:22,292 --> 00:29:24,000 rate, because it's in thermal equilibrium 656 00:29:24,000 --> 00:29:25,070 with the area around it. 657 00:29:25,070 --> 00:29:28,900 So it's absorbing protons and emitting them at the same rate. 658 00:29:28,900 --> 00:29:33,470 And this is equal to B. So some material parameter 659 00:29:33,470 --> 00:29:38,174 times your hole in a electron concentration. 660 00:29:38,174 --> 00:29:39,840 And again, under equilibrium conditions, 661 00:29:39,840 --> 00:29:42,070 that's equal to your intrinsic carrier concentration. 662 00:29:42,070 --> 00:29:43,690 np product is equal to ni squared. 663 00:29:47,490 --> 00:29:51,210 Now, when you shine light on it, your n, 664 00:29:51,210 --> 00:29:57,410 which is to n0 plus delta n-- so this is you excited carriers, 665 00:29:57,410 --> 00:29:58,960 your excess carriers. 666 00:29:58,960 --> 00:30:01,710 So your n now increases and is greater than n sub i, 667 00:30:01,710 --> 00:30:06,541 and your net recombination rate is determined by this equation 668 00:30:06,541 --> 00:30:07,040 right here. 669 00:30:07,040 --> 00:30:10,200 So B np minus B ni squared-- so the difference 670 00:30:10,200 --> 00:30:13,670 between your equilibrium and your now excited carrier 671 00:30:13,670 --> 00:30:15,414 concentrations. 672 00:30:15,414 --> 00:30:17,342 AUDIENCE: I'm not sure if I missed this. 673 00:30:17,342 --> 00:30:19,149 Is B just a proportionality? 674 00:30:19,149 --> 00:30:20,940 PROFESSOR: It's a material parameter, yeah. 675 00:30:20,940 --> 00:30:23,070 It depends on-- for silicon, I forget. 676 00:30:23,070 --> 00:30:24,130 It was on the next slide. 677 00:30:24,130 --> 00:30:26,550 It's 10 to the minus 15th. 678 00:30:26,550 --> 00:30:28,400 I don't know for other materials, 679 00:30:28,400 --> 00:30:32,270 but I presume that that would change-- probably 680 00:30:32,270 --> 00:30:35,700 be a lot higher for other materials. 681 00:30:35,700 --> 00:30:39,320 And it turns out your radiative recombination lifetimes, 682 00:30:39,320 --> 00:30:43,029 when you plug these numbers in and you make some assumptions 683 00:30:43,029 --> 00:30:45,070 about what's really small compared to each other, 684 00:30:45,070 --> 00:30:47,740 you get these equations here. 685 00:30:47,740 --> 00:30:51,940 And again, this is tau is equal to delta n over R. 686 00:30:51,940 --> 00:30:53,360 And so you get that. 687 00:30:53,360 --> 00:30:58,510 And now if you look at for silicon, 688 00:30:58,510 --> 00:31:01,780 you get B is about 2 times 10 to the minus 15th. 689 00:31:01,780 --> 00:31:06,130 Your delta n I put-- n I determined 690 00:31:06,130 --> 00:31:09,490 just was 10 to the 16th-- some doping concentration. 691 00:31:09,490 --> 00:31:12,160 And your radiative lifetime is incredibly, incredibly long-- 692 00:31:12,160 --> 00:31:14,200 about 50 milliseconds. 693 00:31:14,200 --> 00:31:16,110 And if you remember from before when 694 00:31:16,110 --> 00:31:18,440 I was calculating a generation rate for silicon, 695 00:31:18,440 --> 00:31:20,540 we used about 10 microseconds. 696 00:31:20,540 --> 00:31:22,600 So this is really, really long. 697 00:31:22,600 --> 00:31:25,400 And so radiative recombination is very, very slow, 698 00:31:25,400 --> 00:31:27,600 and it's rarely ever the limiting lifetime 699 00:31:27,600 --> 00:31:30,680 in silicon solar cells. 700 00:31:30,680 --> 00:31:32,370 However, as you mentioned earlier, 701 00:31:32,370 --> 00:31:35,870 it's actually a big problem in direct band gap materials. 702 00:31:35,870 --> 00:31:38,010 And if you think of there's some materials 703 00:31:38,010 --> 00:31:41,760 we actually want a very short radiative recombination time. 704 00:31:41,760 --> 00:31:44,010 So for example, if you're trying to make an LED, 705 00:31:44,010 --> 00:31:46,010 you inject carriers using a voltage 706 00:31:46,010 --> 00:31:48,162 that recombination emits photons, 707 00:31:48,162 --> 00:31:49,120 and then you get light. 708 00:31:49,120 --> 00:31:51,105 And that's basically how an LED works. 709 00:31:57,385 --> 00:31:59,510 So now we'll talk a little about Shockley-Read-Hall 710 00:31:59,510 --> 00:32:00,180 recombinations. 711 00:32:00,180 --> 00:32:02,840 So this is something that our lab works, 712 00:32:02,840 --> 00:32:05,060 I think, very, very well in. 713 00:32:05,060 --> 00:32:09,940 We do a lot of defects in semiconductors, specifically 714 00:32:09,940 --> 00:32:10,730 iron. 715 00:32:10,730 --> 00:32:12,740 And so iron is one of these really, really awful 716 00:32:12,740 --> 00:32:14,180 contaminants in solar cells. 717 00:32:14,180 --> 00:32:16,230 Just a little bit of iron, I think-- [INAUDIBLE], 718 00:32:16,230 --> 00:32:17,230 correct me if I'm wrong. 719 00:32:17,230 --> 00:32:19,188 I don't remember what year production this was. 720 00:32:19,188 --> 00:32:22,334 Maybe it was 2009, but two grams of iron 721 00:32:22,334 --> 00:32:24,000 could contaminate the entire year supply 722 00:32:24,000 --> 00:32:26,090 of silicon detrimentally. 723 00:32:26,090 --> 00:32:27,016 So that's a lot. 724 00:32:27,016 --> 00:32:28,682 AUDIENCE: I think you actually calculate 725 00:32:28,682 --> 00:32:29,723 this in your [INAUDIBLE]. 726 00:32:29,723 --> 00:32:31,740 PROFESSOR: Yes, you do for a single panel, 727 00:32:31,740 --> 00:32:35,430 and it shocked me. 728 00:32:35,430 --> 00:32:37,180 So basically what we're trying to say here 729 00:32:37,180 --> 00:32:39,420 is that you have iron atoms and it 730 00:32:39,420 --> 00:32:41,380 can sit in different areas of your lattice, 731 00:32:41,380 --> 00:32:43,900 but you have these defects that exist, 732 00:32:43,900 --> 00:32:46,390 and they introduce different energy levels 733 00:32:46,390 --> 00:32:49,150 within the band gap. 734 00:32:49,150 --> 00:32:52,860 So the outer electrons of iron can either sit at these sites-- 735 00:32:52,860 --> 00:32:55,582 so these blue sites where they're donors, 736 00:32:55,582 --> 00:32:58,040 or they can create acceptor states kind of like boron does, 737 00:32:58,040 --> 00:33:00,430 but they're much higher up into the gap. 738 00:33:00,430 --> 00:33:02,080 And these act as recombination centers, 739 00:33:02,080 --> 00:33:04,060 and we'll talk about why that is in a second. 740 00:33:07,400 --> 00:33:09,880 So these trap levels can interact 741 00:33:09,880 --> 00:33:14,630 with mobile carriers in a whole bunch of different ways. 742 00:33:14,630 --> 00:33:16,380 They can capture an electron. 743 00:33:16,380 --> 00:33:19,280 That electron can then sit there. 744 00:33:19,280 --> 00:33:20,894 If there's enough heat energy, it 745 00:33:20,894 --> 00:33:23,310 might actually get promoted and jump out of that, and then 746 00:33:23,310 --> 00:33:26,800 which case it wouldn't have actually decreased 747 00:33:26,800 --> 00:33:29,630 your excess carrier population. 748 00:33:29,630 --> 00:33:34,000 It can also capture holes, and it can also emit holes. 749 00:33:34,000 --> 00:33:38,220 And there's a bunch of things that go into these equations 750 00:33:38,220 --> 00:33:40,600 here. 751 00:33:40,600 --> 00:33:44,000 It depends on a lot of the energy of this trap state. 752 00:33:44,000 --> 00:33:46,027 It depends on the carrier excitation. 753 00:33:46,027 --> 00:33:47,860 We'll talk about that in another few slides. 754 00:33:47,860 --> 00:33:52,000 And it also depends on these-- what 755 00:33:52,000 --> 00:33:54,320 are effective-- I forget the exact word, 756 00:33:54,320 --> 00:33:58,410 but the effective hole in electron lifetimes. 757 00:33:58,410 --> 00:34:00,670 And those are limited by your trap density. 758 00:34:00,670 --> 00:34:02,870 So these can be thought of-- suppose 759 00:34:02,870 --> 00:34:05,300 they're each-- let's say each iron atom is introducing 760 00:34:05,300 --> 00:34:06,424 one trap level. 761 00:34:06,424 --> 00:34:08,840 It would be the number of trap levels, the density of trap 762 00:34:08,840 --> 00:34:13,969 levels within your system, times some thermal energy, 763 00:34:13,969 --> 00:34:15,639 and then a capture cross section, 764 00:34:15,639 --> 00:34:18,940 which is saying, OK, that trap state exists in one location. 765 00:34:18,940 --> 00:34:23,040 How much area can it see in terms of what effective area is 766 00:34:23,040 --> 00:34:25,940 it capturing electrons? 767 00:34:25,940 --> 00:34:29,449 And oftentimes under the right conditions-- so 768 00:34:29,449 --> 00:34:32,510 with very, very deep traps, so traps mid-gap 769 00:34:32,510 --> 00:34:34,741 under low injections, your Shockley-Read-Hall 770 00:34:34,741 --> 00:34:36,949 recombination is actually one of those two lifetimes, 771 00:34:36,949 --> 00:34:38,870 and it's a very simple equation. 772 00:34:38,870 --> 00:34:41,142 And under very, very high injection conditions, 773 00:34:41,142 --> 00:34:42,850 it's actually summing them up, and if you 774 00:34:42,850 --> 00:34:44,266 look in the previous slide, if you 775 00:34:44,266 --> 00:34:45,989 go to delta n goes to infinity, you 776 00:34:45,989 --> 00:34:48,150 can see that this becomes true. 777 00:34:48,150 --> 00:34:48,674 Joel? 778 00:34:48,674 --> 00:34:51,605 AUDIENCE: The energy, the thermal energy type 779 00:34:51,605 --> 00:34:53,234 [INAUDIBLE]? 780 00:34:53,234 --> 00:34:54,650 PROFESSOR: That's a good question. 781 00:34:54,650 --> 00:34:55,608 That would be my guess. 782 00:34:59,961 --> 00:35:01,752 Sorry, there's another question back there? 783 00:35:01,752 --> 00:35:05,640 AUDIENCE: Yeah, so is iron worse or is gold worse? 784 00:35:05,640 --> 00:35:06,825 PROFESSOR: I can't hear you. 785 00:35:06,825 --> 00:35:09,387 AUDIENCE: Is iron a worse dopant, or is gold 786 00:35:09,387 --> 00:35:11,566 your worst dopant in terms of [INAUDIBLE]? 787 00:35:11,566 --> 00:35:13,640 PROFESSOR: Oh, in terms of capture cross section? 788 00:35:13,640 --> 00:35:14,790 AUDIENCE: Yeah. 789 00:35:14,790 --> 00:35:19,780 PROFESSOR: I know they're both bad, really bad. 790 00:35:19,780 --> 00:35:23,340 [INAUDIBLE], do you know that off the top of your head? 791 00:35:23,340 --> 00:35:26,990 AUDIENCE: Sure, so gold has a larger lifetime 792 00:35:26,990 --> 00:35:30,294 impact at lower concentrations than iron, 793 00:35:30,294 --> 00:35:32,390 but it's perhaps one of worst, and that's 794 00:35:32,390 --> 00:35:36,110 why you're not allowed to wear gold jewelry at the cleaners. 795 00:35:36,110 --> 00:35:39,460 They ask you to take off your wedding bands and other jewelry 796 00:35:39,460 --> 00:35:42,863 before entering the [INAUDIBLE] cleaners. 797 00:35:42,863 --> 00:35:44,446 PROFESSOR: So no bling in the cleaner. 798 00:35:44,446 --> 00:35:46,930 There you go. 799 00:35:46,930 --> 00:35:50,180 And so for the material scientists and physicists 800 00:35:50,180 --> 00:35:53,060 in the room, if that does not apply to you, don't worry. 801 00:35:53,060 --> 00:35:56,250 This is just to explain what is going on. 802 00:35:56,250 --> 00:35:57,870 Often when you want recombination 803 00:35:57,870 --> 00:36:01,540 to happen-- so this is a momentum, or k, versus energy-- 804 00:36:01,540 --> 00:36:04,150 it requires not only the emission of a photon, 805 00:36:04,150 --> 00:36:10,400 but also a phonon to change its momentum. 806 00:36:10,400 --> 00:36:15,100 When you introduce a trap level, or these localized impurities, 807 00:36:15,100 --> 00:36:16,670 because it's localized in real space, 808 00:36:16,670 --> 00:36:18,590 it's delocalized in k space, so you 809 00:36:18,590 --> 00:36:20,540 have this kind of flat level in k, 810 00:36:20,540 --> 00:36:23,375 and you have these very, very efficient pathways 811 00:36:23,375 --> 00:36:24,980 for recombination. 812 00:36:24,980 --> 00:36:26,620 If that doesn't resonate with you, 813 00:36:26,620 --> 00:36:27,911 don't worry about it right now. 814 00:36:36,720 --> 00:36:38,850 So here we see that really the impurities can 815 00:36:38,850 --> 00:36:41,640 have a very, very large effect. 816 00:36:41,640 --> 00:36:43,960 If you think of the doping densities that we put in, 817 00:36:43,960 --> 00:36:45,560 we've been using about 10 to the 15th, 818 00:36:45,560 --> 00:36:47,570 10 to the 16th for our doping density. 819 00:36:47,570 --> 00:36:49,990 This is on the order of like a million less, 820 00:36:49,990 --> 00:36:53,290 and it can have a huge impact on lifetime. 821 00:36:53,290 --> 00:36:56,080 So one of the worst, again, as we said, was iron, 822 00:36:56,080 --> 00:36:58,320 and these interstitial irons are especially bad. 823 00:36:58,320 --> 00:37:01,870 And at 10 to the-- I don't know-- looks like 10 824 00:37:01,870 --> 00:37:03,122 to the 11th. 825 00:37:03,122 --> 00:37:04,330 Very, very low concentration. 826 00:37:04,330 --> 00:37:06,460 That's one in 10 to the 12th. 827 00:37:06,460 --> 00:37:08,420 So that's one in a trillion atoms 828 00:37:08,420 --> 00:37:12,140 are iron-- cane detrimentally impact your solar cell. 829 00:37:12,140 --> 00:37:13,590 So that's really, really bad. 830 00:37:13,590 --> 00:37:17,290 So keeping fabs clean-- so again, 831 00:37:17,290 --> 00:37:19,520 no jewelry and other things can really-- 832 00:37:19,520 --> 00:37:23,020 that can actually have a very large effect on your device 833 00:37:23,020 --> 00:37:24,300 performance. 834 00:37:24,300 --> 00:37:28,690 And if you plot that versus your dislocation density, 835 00:37:28,690 --> 00:37:31,100 you can see that if you have-- it's 836 00:37:31,100 --> 00:37:35,115 especially bad for very, very high lifetime silicon. 837 00:37:35,115 --> 00:37:37,240 Just a few dislocations can actually really, really 838 00:37:37,240 --> 00:37:39,124 hurt it, but the effect is mitigated 839 00:37:39,124 --> 00:37:41,540 if you're already starting with very low lifetime silicon. 840 00:37:46,260 --> 00:37:51,170 And again, this is something our lab works on quite extensively. 841 00:37:51,170 --> 00:37:52,795 It's not just the number of iron atoms. 842 00:37:52,795 --> 00:37:54,211 So if you take a piece of silicon, 843 00:37:54,211 --> 00:37:55,646 and you want to know its lifetime 844 00:37:55,646 --> 00:37:57,020 or how iron impacts its lifetime, 845 00:37:57,020 --> 00:37:59,320 it's not just the total number of iron atoms in it. 846 00:37:59,320 --> 00:38:01,110 It's also how they're distributed. 847 00:38:01,110 --> 00:38:04,090 So if you have, let's say, clusters of iron atoms, that 848 00:38:04,090 --> 00:38:07,040 would count as one defect, or effectively less 849 00:38:07,040 --> 00:38:08,430 than the number of atoms in it. 850 00:38:08,430 --> 00:38:12,820 And so clustering these things can actually be really, really 851 00:38:12,820 --> 00:38:16,380 a good way of cleaning up your solar cell material, 852 00:38:16,380 --> 00:38:18,350 and this is an effect called gettering. 853 00:38:18,350 --> 00:38:20,370 And if you can getter these impurity atoms 854 00:38:20,370 --> 00:38:22,790 into one location, they'll have less of a detrimental 855 00:38:22,790 --> 00:38:24,120 impact on your material. 856 00:38:28,659 --> 00:38:30,450 So this is kind of a tricky one to explain, 857 00:38:30,450 --> 00:38:32,760 but this is-- so Shockley-Read-Hall 858 00:38:32,760 --> 00:38:35,930 recombination can also show up in something 859 00:38:35,930 --> 00:38:37,680 called service recombination. 860 00:38:37,680 --> 00:38:40,550 So if you look at your silicon lattice, 861 00:38:40,550 --> 00:38:43,650 each silicon atom has four valence electrons, 862 00:38:43,650 --> 00:38:47,520 and it bonds to four silicon atoms around it, 863 00:38:47,520 --> 00:38:49,510 and it has satisfied covalent bonds. 864 00:38:49,510 --> 00:38:53,000 So this silicon atom has all its satisfied, all its satisfied, 865 00:38:53,000 --> 00:38:54,410 until you get to the surface. 866 00:38:54,410 --> 00:38:57,260 And at the surface, you have what are called dangling bonds. 867 00:38:57,260 --> 00:38:59,530 And these dealing bonds can actually 868 00:38:59,530 --> 00:39:01,590 introduce traps states, and so you 869 00:39:01,590 --> 00:39:05,370 can see that actually introduces a whole ton of levels 870 00:39:05,370 --> 00:39:07,766 within the band gap that can provide 871 00:39:07,766 --> 00:39:09,390 Shockley-Read-Hall recall recombination 872 00:39:09,390 --> 00:39:11,280 pathways for your carriers. 873 00:39:11,280 --> 00:39:17,090 And so surfaces are incredibly important, and the way 874 00:39:17,090 --> 00:39:19,350 we tend to think of it-- and this 875 00:39:19,350 --> 00:39:22,040 is a concept that might be difficult to grasp at first, 876 00:39:22,040 --> 00:39:23,570 but it scales with two things. 877 00:39:23,570 --> 00:39:26,140 There's two things going on. 878 00:39:26,140 --> 00:39:29,570 You can think of that this is the width of your cell, 879 00:39:29,570 --> 00:39:31,970 and you have some service recombination velocity, 880 00:39:31,970 --> 00:39:35,100 which is some kind of characteristic of how well they 881 00:39:35,100 --> 00:39:37,800 can recombine at the surface. 882 00:39:37,800 --> 00:39:40,955 And at let's say infinite surface recombination 883 00:39:40,955 --> 00:39:43,330 velocities, it means that any carrier that comes and hits 884 00:39:43,330 --> 00:39:45,690 that surface will most surely recombine. 885 00:39:45,690 --> 00:39:46,925 So this drops to zero. 886 00:39:46,925 --> 00:39:49,300 So then you're limited by, OK, how well can they actually 887 00:39:49,300 --> 00:39:51,310 diffuse to your surface? 888 00:39:51,310 --> 00:39:55,720 So it's again some kind of ratio of your self thickness 889 00:39:55,720 --> 00:39:58,450 squared over the diffusivity, your carrier diffusivity, 890 00:39:58,450 --> 00:40:00,080 and that that gives you an idea of what 891 00:40:00,080 --> 00:40:01,163 your limiting factors are. 892 00:40:01,163 --> 00:40:05,790 So under very low surface recombination velocities, 893 00:40:05,790 --> 00:40:07,349 you're limited by this term here, 894 00:40:07,349 --> 00:40:09,140 the first one, and then the very high ones, 895 00:40:09,140 --> 00:40:11,146 you're limited by this term. 896 00:40:11,146 --> 00:40:15,736 And do there's two effects going on there. 897 00:40:15,736 --> 00:40:17,110 And it's summarized as well here. 898 00:40:19,740 --> 00:40:22,360 At very, very low surface recombination velocities, 899 00:40:22,360 --> 00:40:27,610 your tau surface almost goes to infinity-- very high. 900 00:40:27,610 --> 00:40:33,520 And you can passivate these bonds using hydrogen. 901 00:40:33,520 --> 00:40:37,204 So for example, if you use hydrofluoric acid, what it does 902 00:40:37,204 --> 00:40:39,620 is it etches away the silicon oxide layer that sits there, 903 00:40:39,620 --> 00:40:42,590 and you have these hydrogen atoms that now sit and satisfy 904 00:40:42,590 --> 00:40:43,832 these bonds. 905 00:40:43,832 --> 00:40:45,290 And if they're perfectly satisfied, 906 00:40:45,290 --> 00:40:46,498 you'll have a mobile carrier. 907 00:40:46,498 --> 00:40:49,190 It'll actually elastically scatter off, not 908 00:40:49,190 --> 00:40:52,220 lose any energy, and not recombine through these trap 909 00:40:52,220 --> 00:40:52,946 states. 910 00:40:52,946 --> 00:40:54,314 AUDIENCE: I have a question. 911 00:40:54,314 --> 00:40:56,460 I thought [INAUDIBLE] is a very good passivation 912 00:40:56,460 --> 00:40:57,440 barrier for silicon? 913 00:40:57,440 --> 00:40:58,620 PROFESSOR: What is? 914 00:40:58,620 --> 00:41:00,167 AUDIENCE: I thought silicon dioxide 915 00:41:00,167 --> 00:41:03,127 is a really good passivation barrier for silicon. 916 00:41:03,127 --> 00:41:05,210 PROFESSOR: I've seen some diagrams of what silicon 917 00:41:05,210 --> 00:41:06,270 oxide looks like on silicon. 918 00:41:06,270 --> 00:41:07,650 It passivates many of the bonds. 919 00:41:07,650 --> 00:41:09,000 You're absolutely right. 920 00:41:09,000 --> 00:41:10,460 HF is actually probably the best. 921 00:41:10,460 --> 00:41:12,610 The problem is that it etches glass and other things that 922 00:41:12,610 --> 00:41:15,068 are in your source material, and it's incredibly dangerous. 923 00:41:15,068 --> 00:41:18,480 It can kill you rather dramatically. 924 00:41:18,480 --> 00:41:20,350 So it's only used in laboratory settings. 925 00:41:20,350 --> 00:41:22,641 If you're trying to actually take lifetime measurements 926 00:41:22,641 --> 00:41:28,250 and negate the effect of surface recombination, 927 00:41:28,250 --> 00:41:29,770 silicon oxide can be a good one. 928 00:41:29,770 --> 00:41:30,920 If you actually look at the structure, 929 00:41:30,920 --> 00:41:32,503 there's a few dangling bonds in there, 930 00:41:32,503 --> 00:41:35,060 but it can passivate most of them-- just not all of them. 931 00:41:35,060 --> 00:41:37,270 Another good passivation technique 932 00:41:37,270 --> 00:41:39,550 is actually the silicon nitride ARC coating. 933 00:41:39,550 --> 00:41:41,340 That passivates the surface very well. 934 00:41:43,850 --> 00:41:45,507 So yeah, good question. 935 00:41:45,507 --> 00:41:48,090 There's other ways to mitigate surface recombination, as well, 936 00:41:48,090 --> 00:41:50,390 and we'll talk about that, I think, in either next lecture 937 00:41:50,390 --> 00:41:51,306 or the one after that. 938 00:41:57,187 --> 00:41:58,770 So yeah, this slide is just telling us 939 00:41:58,770 --> 00:42:04,230 that, if we vary our thickness of our silicon, 940 00:42:04,230 --> 00:42:08,770 we can actually measure our surface recombination velocity, 941 00:42:08,770 --> 00:42:11,700 and we can fit it so we can figure out 942 00:42:11,700 --> 00:42:14,290 our tau surface, which is a really important material 943 00:42:14,290 --> 00:42:15,040 parameter. 944 00:42:15,040 --> 00:42:18,750 Generally, I think good surface recombination velocities are 945 00:42:18,750 --> 00:42:23,150 anywhere from like 10 to maybe in the 100ths for centimeters 946 00:42:23,150 --> 00:42:27,410 per second, and really bad ones are much, much higher. 947 00:42:31,160 --> 00:42:34,660 And the last type of recombination mechanism 948 00:42:34,660 --> 00:42:38,410 we're going to talk about today is Auger recombination, 949 00:42:38,410 --> 00:42:40,680 and this looks like-- when I first saw this, 950 00:42:40,680 --> 00:42:43,670 I'm like, why on earth would this ever happen? 951 00:42:43,670 --> 00:42:46,420 And the fact is it does until you get to very, very 952 00:42:46,420 --> 00:42:48,880 high carrier concentration. 953 00:42:48,880 --> 00:42:51,620 So you can see that it involves three particles. 954 00:42:51,620 --> 00:42:53,260 Let's say an n-type silicon. 955 00:42:53,260 --> 00:42:55,330 It needs two electrons in the hole. 956 00:42:55,330 --> 00:42:59,855 What happens is that you get the simultaneous relaxation 957 00:42:59,855 --> 00:43:00,820 and excitation. 958 00:43:00,820 --> 00:43:06,790 So you get this relaxation of this excited electron 959 00:43:06,790 --> 00:43:11,130 into a hole, and then you get this excitation 960 00:43:11,130 --> 00:43:13,860 of this other electron into a higher energy state, 961 00:43:13,860 --> 00:43:17,120 and then it thermalizes down and releases a phonon, 962 00:43:17,120 --> 00:43:17,867 releases heat. 963 00:43:17,867 --> 00:43:18,450 Yeah, Jessica? 964 00:43:18,450 --> 00:43:21,780 AUDIENCE: [INAUDIBLE] terms of p-type here? 965 00:43:21,780 --> 00:43:24,970 PROFESSOR: So this is going to be our n-type material. 966 00:43:24,970 --> 00:43:29,110 And again, because this type of recombination event 967 00:43:29,110 --> 00:43:32,030 requires two particles, it requires two electrons, 968 00:43:32,030 --> 00:43:33,570 so it's n squared in one hole. 969 00:43:33,570 --> 00:43:35,760 So the recombination rate goes up 970 00:43:35,760 --> 00:43:39,200 with pn squared at high enough concentrations. 971 00:43:39,200 --> 00:43:43,700 And so your tau goes out with the 1 over n squared. 972 00:43:43,700 --> 00:43:47,185 And this is particularly bad, again, 973 00:43:47,185 --> 00:43:48,560 only at very-- because it goes up 974 00:43:48,560 --> 00:43:50,950 with the square of the carrier concentration, 975 00:43:50,950 --> 00:43:53,550 it's really bad at very high carrier concentrations. 976 00:43:53,550 --> 00:43:56,240 So if we look at this plot, we can see that our minority care 977 00:43:56,240 --> 00:43:58,820 lifetime drops well below a microsecond around 10 978 00:43:58,820 --> 00:44:01,020 to the 18th, so you generally want 979 00:44:01,020 --> 00:44:03,830 to stay out of that range of doping concentrations 980 00:44:03,830 --> 00:44:07,542 in your base, because you'll have very, very bad lifetimes. 981 00:44:07,542 --> 00:44:11,826 AUDIENCE: [INAUDIBLE] are both sides-- 982 00:44:11,826 --> 00:44:15,569 is that the top blue part and the bottom blue part n-type? 983 00:44:15,569 --> 00:44:16,860 PROFESSOR: I didn't label this. 984 00:44:16,860 --> 00:44:17,401 You're right. 985 00:44:17,401 --> 00:44:18,680 This is the valence band. 986 00:44:18,680 --> 00:44:19,805 That's the conduction band. 987 00:44:26,330 --> 00:44:28,470 And so this is kind of driving home, again, 988 00:44:28,470 --> 00:44:29,990 that leaky bucket idea-- that is, 989 00:44:29,990 --> 00:44:32,730 you're really limited by your worst lifetime. 990 00:44:32,730 --> 00:44:34,720 And so if you remember, we're thinking 991 00:44:34,720 --> 00:44:36,520 about parallel circuits here. 992 00:44:36,520 --> 00:44:39,470 Your bulk, or your effective lifetime of each carrier, 993 00:44:39,470 --> 00:44:42,580 is determined by these three here-- your radiative. 994 00:44:42,580 --> 00:44:45,000 Sorry, that should be tau band, which 995 00:44:45,000 --> 00:44:47,190 is the same as your radiative recombination-- 996 00:44:47,190 --> 00:44:49,200 Auger and Shockley-Read-Hall. 997 00:44:49,200 --> 00:44:51,460 And so at different excess carrier densities-- so 998 00:44:51,460 --> 00:44:57,640 we're varying delta n by shining various intensities of light. 999 00:44:57,640 --> 00:45:03,950 And we can kind of activate different limiting lifetimes. 1000 00:45:03,950 --> 00:45:08,022 So at very low, you're limited by Shockley-Read-Hall. 1001 00:45:08,022 --> 00:45:09,480 And Shockley-Read-Hall can actually 1002 00:45:09,480 --> 00:45:14,136 go down with higher illumination conditions. 1003 00:45:14,136 --> 00:45:16,260 And your Auger, remember it gets really, really bad 1004 00:45:16,260 --> 00:45:18,930 around 10 to the 18th-- becomes your limiting. 1005 00:45:18,930 --> 00:45:22,770 So your tau bulk is never doing better 1006 00:45:22,770 --> 00:45:23,858 than your worst lifetime. 1007 00:45:27,762 --> 00:45:30,446 AUDIENCE: So on that graph is tau 1008 00:45:30,446 --> 00:45:32,160 and emitter also the same thing as-- 1009 00:45:32,160 --> 00:45:33,218 PROFESSOR: Tau Auger? 1010 00:45:33,218 --> 00:45:35,170 AUDIENCE: [INAUDIBLE] tau [INAUDIBLE]. 1011 00:45:35,170 --> 00:45:37,620 PROFESSOR: This came out of Daniel McDonald's thesis. 1012 00:45:37,620 --> 00:45:40,420 Tau emitter-- it's complicated because it 1013 00:45:40,420 --> 00:45:41,870 has other influences in it. 1014 00:45:41,870 --> 00:45:43,910 Auger, I always think of recombination 1015 00:45:43,910 --> 00:45:45,900 in the emitter as Auger, but you also 1016 00:45:45,900 --> 00:45:49,870 have other carriers coming in due to injection currents. 1017 00:45:49,870 --> 00:45:51,670 And so your excess carrier population 1018 00:45:51,670 --> 00:45:54,390 is also a function of that, and so the equation 1019 00:45:54,390 --> 00:45:56,110 for it gets a little more complicated, 1020 00:45:56,110 --> 00:45:59,940 but it would make sense that, as you increase illumination, 1021 00:45:59,940 --> 00:46:02,980 you're increasing your current into the emitter. 1022 00:46:02,980 --> 00:46:05,580 And you would get more carriers, and it would decrease. 1023 00:46:05,580 --> 00:46:08,409 And it looks almost exactly like Auger in his regime over here. 1024 00:46:08,409 --> 00:46:10,450 I'm not sure of the other things that go into it, 1025 00:46:10,450 --> 00:46:11,980 but if you look up his thesis, I think 1026 00:46:11,980 --> 00:46:13,438 it gives a pretty good description. 1027 00:46:18,281 --> 00:46:20,280 So you're probably bored of hearing me say this, 1028 00:46:20,280 --> 00:46:24,650 but again, we're always limited by our weakest. 1029 00:46:24,650 --> 00:46:28,110 So in defect mitigated recombination materials-- so 1030 00:46:28,110 --> 00:46:31,810 where your shortest lifetime is due to some kind 1031 00:46:31,810 --> 00:46:33,310 of Shockley-Read-Hall recombination. 1032 00:46:36,660 --> 00:46:38,160 Your lifetime for Shockley-Read-Hall 1033 00:46:38,160 --> 00:46:40,970 is always going to be much, much shorter 1034 00:46:40,970 --> 00:46:43,020 than your radiative lifetimes, which 1035 00:46:43,020 --> 00:46:46,930 is a characteristic we can exploit for measuring 1036 00:46:46,930 --> 00:46:48,630 the lifetimes of our materials. 1037 00:46:48,630 --> 00:46:51,180 So because very, very few carriers will actually 1038 00:46:51,180 --> 00:46:54,590 radiatively recombine and emit a photon, that, if more of them 1039 00:46:54,590 --> 00:46:56,160 are radiatively recombining, then we 1040 00:46:56,160 --> 00:46:58,620 know that it's a very high lifetime material. 1041 00:46:58,620 --> 00:47:00,349 If there's a lot of defects and we 1042 00:47:00,349 --> 00:47:02,390 have very, very short lifetimes, very few of them 1043 00:47:02,390 --> 00:47:04,150 will radiatively recombine. 1044 00:47:04,150 --> 00:47:10,050 And so this emission of photons with energy at the band gap 1045 00:47:10,050 --> 00:47:12,590 can give us an idea of the lifetime within our material, 1046 00:47:12,590 --> 00:47:13,900 and that's how we measure. 1047 00:47:13,900 --> 00:47:16,360 It's a technique called photoluminescence, 1048 00:47:16,360 --> 00:47:19,160 and what you do is you shine light on it, 1049 00:47:19,160 --> 00:47:20,304 generally with a laser. 1050 00:47:20,304 --> 00:47:21,970 We put a diffuser in front of the lasers 1051 00:47:21,970 --> 00:47:26,142 so the laser beam spreads its photons over a large area. 1052 00:47:26,142 --> 00:47:27,350 We excite all these carriers. 1053 00:47:27,350 --> 00:47:29,530 So this laser has very, very short wavelengths, 1054 00:47:29,530 --> 00:47:31,380 and I think in our-- well, very short. 1055 00:47:31,380 --> 00:47:32,920 It's 900 nanometers. 1056 00:47:32,920 --> 00:47:36,170 Silicon's band gap corresponds to about 1,108 nanometers. 1057 00:47:36,170 --> 00:47:38,830 And so 900 is easily absorbed, not just right 1058 00:47:38,830 --> 00:47:42,850 near the emitter, but also somewhat well deep 1059 00:47:42,850 --> 00:47:45,370 below the junction as well. 1060 00:47:45,370 --> 00:47:48,010 And then as you begin to see recombination, 1061 00:47:48,010 --> 00:47:50,857 when radiative recombination happens, we emit a photon. 1062 00:47:50,857 --> 00:47:53,190 And that can happen in certain areas better than others, 1063 00:47:53,190 --> 00:47:55,395 and a lot of it depends on, like I 1064 00:47:55,395 --> 00:48:01,830 said, defect density and other lifetime eliminating defects. 1065 00:48:01,830 --> 00:48:05,410 And it's a good way to spatially locate where problems 1066 00:48:05,410 --> 00:48:07,690 are in your solar cell. 1067 00:48:07,690 --> 00:48:09,114 Any other questions? 1068 00:48:09,114 --> 00:48:09,614 Ben? 1069 00:48:09,614 --> 00:48:12,100 AUDIENCE: How good is spatial resolution on [INAUDIBLE]? 1070 00:48:12,100 --> 00:48:13,641 PROFESSOR: It depends on your camera. 1071 00:48:13,641 --> 00:48:17,680 So we use, I think, a germanium camera to detect those photons, 1072 00:48:17,680 --> 00:48:20,110 because Silicon won't have a very good response. 1073 00:48:20,110 --> 00:48:23,520 And it depends on the CCD array within your camera. 1074 00:48:23,520 --> 00:48:25,260 It can be really good. 1075 00:48:25,260 --> 00:48:29,050 I do a similar technique to measure shunts, 1076 00:48:29,050 --> 00:48:30,670 and we have microscope objectively. 1077 00:48:30,670 --> 00:48:32,690 We just have to zoom in really, really far, 1078 00:48:32,690 --> 00:48:34,340 and then we just scan over an area. 1079 00:48:36,900 --> 00:48:42,230 And last little thing is that, if you recall-- hold on. 1080 00:48:42,230 --> 00:48:46,840 Let me-- this slide. 1081 00:48:46,840 --> 00:48:48,765 Traps cannot only trap an electron, 1082 00:48:48,765 --> 00:48:50,600 but you can also emit an electron, 1083 00:48:50,600 --> 00:48:52,460 assuming it has enough thermal energy, 1084 00:48:52,460 --> 00:48:56,510 and you can see that on this plot. 1085 00:48:56,510 --> 00:48:57,960 And so this is an Arrhenius plot. 1086 00:48:57,960 --> 00:49:00,590 So again, high temperatures are in this direction. 1087 00:49:00,590 --> 00:49:02,230 Low temperatures are over here. 1088 00:49:02,230 --> 00:49:04,250 And you can see that your lifetime actually 1089 00:49:04,250 --> 00:49:07,070 increases at higher temperatures because electrons 1090 00:49:07,070 --> 00:49:09,640 that see that trap fall into it, then can easily come back 1091 00:49:09,640 --> 00:49:11,681 out of it because they have enough thermal energy 1092 00:49:11,681 --> 00:49:12,210 to escape. 1093 00:49:12,210 --> 00:49:14,180 And that's really what this is depicting. 1094 00:49:14,180 --> 00:49:17,400 So one of the things I think for researchers in the room who 1095 00:49:17,400 --> 00:49:19,840 are studying these types of materials, varying temperature 1096 00:49:19,840 --> 00:49:21,590 is often a really, really good way 1097 00:49:21,590 --> 00:49:24,920 of looking at electronic structure materials. 1098 00:49:24,920 --> 00:49:27,280 And it can be very, very powerful, 1099 00:49:27,280 --> 00:49:29,840 and this is one example of a tool 1100 00:49:29,840 --> 00:49:36,350 to look at these types of traps. 1101 00:49:36,350 --> 00:49:36,850 Oh, good. 1102 00:49:36,850 --> 00:49:38,630 We have plenty of time. 1103 00:49:38,630 --> 00:49:41,240 We actually might end early. 1104 00:49:41,240 --> 00:49:43,090 So now we're going to talk about mobility. 1105 00:49:43,090 --> 00:49:44,530 We've given a lot of-- sorry? 1106 00:49:44,530 --> 00:49:46,071 AUDIENCE: I was just wondering, is it 1107 00:49:46,071 --> 00:49:49,440 possible to somehow introduce defects that are at the energy 1108 00:49:49,440 --> 00:49:50,422 levels [INAUDIBLE]? 1109 00:49:53,614 --> 00:49:55,030 PROFESSOR: That's a good question. 1110 00:49:55,030 --> 00:49:59,830 So phosphorus actually has, if you draw it on an e versus x 1111 00:49:59,830 --> 00:50:09,242 diagram-- so if we have our conduction band here, 1112 00:50:09,242 --> 00:50:12,790 our valence band here, we said iron puts states 1113 00:50:12,790 --> 00:50:14,320 in the middle of the gap. 1114 00:50:14,320 --> 00:50:17,110 Phosphorus and boron actually put states very, very, very 1115 00:50:17,110 --> 00:50:19,550 close to the valence band and conduction band. 1116 00:50:19,550 --> 00:50:22,010 If you go to low enough temperature-- so let's 1117 00:50:22,010 --> 00:50:25,010 say a below 100 Kelvin-- you can actually 1118 00:50:25,010 --> 00:50:28,320 freeze out those donor electrons onto the phosphorus atoms. 1119 00:50:28,320 --> 00:50:31,750 And below certain concentrations of phosphorus atoms, 1120 00:50:31,750 --> 00:50:36,530 for example-- so below like 10 to the 18th-- at 0 Kelvin, 1121 00:50:36,530 --> 00:50:38,720 you cannot conduct electricity. 1122 00:50:38,720 --> 00:50:40,355 It actually becomes a total insulator. 1123 00:50:40,355 --> 00:50:41,563 That's an excellent question. 1124 00:50:41,563 --> 00:50:44,300 But at room temperature, when kt is on the order-- 1125 00:50:44,300 --> 00:50:47,530 so kt is your thermal energy, and at room temperature, 1126 00:50:47,530 --> 00:50:49,630 if you put that for electrons, it's 1127 00:50:49,630 --> 00:50:55,160 0.026 electron volts or 26 millielectron volts. 1128 00:50:55,160 --> 00:50:57,895 This is a good number to have in mind, by the way. 1129 00:50:57,895 --> 00:50:59,960 When that number is on the order of this binding 1130 00:50:59,960 --> 00:51:01,870 energy for phosphorus, they're almost always 1131 00:51:01,870 --> 00:51:07,680 fully ionized and free, but that's a very good question. 1132 00:51:07,680 --> 00:51:08,180 Anyone else? 1133 00:51:14,520 --> 00:51:17,280 So if we remember our definition mobility 1134 00:51:17,280 --> 00:51:20,410 is related to or diffusivity, and again, our mobility 1135 00:51:20,410 --> 00:51:24,209 is saying how well these excited charges can move around. 1136 00:51:24,209 --> 00:51:26,000 And it's related to how much thermal energy 1137 00:51:26,000 --> 00:51:30,660 these charges have, so that's why we have this kbt factor. 1138 00:51:30,660 --> 00:51:33,480 And what's plotted on the right is 1139 00:51:33,480 --> 00:51:37,940 the Shockley-Queisser efficiency limit, which are the stars. 1140 00:51:37,940 --> 00:51:42,560 And then how if you-- let's say you reduce your mobility by, 1141 00:51:42,560 --> 00:51:46,180 let's say, a factor of 10 or 100. 1142 00:51:46,180 --> 00:51:48,280 What's the impact on the overall efficiency? 1143 00:51:48,280 --> 00:51:51,010 And you can see that, if you detrimentally 1144 00:51:51,010 --> 00:51:52,510 impact your mobility, you can really 1145 00:51:52,510 --> 00:51:55,100 have a large effect on your diffusion length, 1146 00:51:55,100 --> 00:51:57,710 and it can really hurt your device performance. 1147 00:51:57,710 --> 00:51:59,870 So it's a really important material parameter 1148 00:51:59,870 --> 00:52:00,560 to think about. 1149 00:52:04,070 --> 00:52:07,770 So there's lots of ways that these mobile electrons can 1150 00:52:07,770 --> 00:52:08,980 do what's called scattering. 1151 00:52:08,980 --> 00:52:11,790 So if I'm a mobile electron, I'm moving down 1152 00:52:11,790 --> 00:52:13,560 through the silicon lattice. 1153 00:52:13,560 --> 00:52:16,649 And let's say I see a defect, and this defect, 1154 00:52:16,649 --> 00:52:18,190 because it has these extra electrons, 1155 00:52:18,190 --> 00:52:21,420 it creates this kind of area of charge. 1156 00:52:21,420 --> 00:52:24,290 It can see that it can scatter off of it and lose its energy, 1157 00:52:24,290 --> 00:52:27,555 and so that's called a scattering event. 1158 00:52:27,555 --> 00:52:28,710 Not really lose its energy. 1159 00:52:28,710 --> 00:52:29,210 Sorry. 1160 00:52:29,210 --> 00:52:30,680 It'll change direction. 1161 00:52:30,680 --> 00:52:34,420 It kind of impacts the movement of that carrier. 1162 00:52:34,420 --> 00:52:40,280 And there's all sorts of other defects scattering mechanisms. 1163 00:52:40,280 --> 00:52:45,170 You can also scatter with an oscillating atom or a phonon. 1164 00:52:45,170 --> 00:52:48,410 There's another type of scattering mechanism, 1165 00:52:48,410 --> 00:52:51,825 and it's heavily dependent on what 1166 00:52:51,825 --> 00:52:53,790 you put into your material, and we'll 1167 00:52:53,790 --> 00:52:55,350 talk about that in a second. 1168 00:52:55,350 --> 00:52:56,850 And for a lot of materials that are, 1169 00:52:56,850 --> 00:53:02,020 let's say, porous or amorphous in some way, or even a lot of, 1170 00:53:02,020 --> 00:53:04,470 let's say, organic semiconductors, 1171 00:53:04,470 --> 00:53:07,530 having a good percolation network is really important 1172 00:53:07,530 --> 00:53:08,660 to transport these charges. 1173 00:53:08,660 --> 00:53:10,670 And often it's a very limiting factor in, 1174 00:53:10,670 --> 00:53:12,253 let's say, like organic photovoltaics. 1175 00:53:15,004 --> 00:53:18,270 And so this is a relatively simple scattering mechanism. 1176 00:53:18,270 --> 00:53:21,132 What time-- oh, we have plenty time. 1177 00:53:21,132 --> 00:53:22,590 What's going on here is that we can 1178 00:53:22,590 --> 00:53:26,660 see that, as we add carriers-- so this is n is 10 to 14th. 1179 00:53:26,660 --> 00:53:28,550 Very, very low concentration of dopants-- 1180 00:53:28,550 --> 00:53:30,530 as we increase the number carriers, 1181 00:53:30,530 --> 00:53:32,860 are scattering off of those ionized impurities. 1182 00:53:32,860 --> 00:53:34,610 So every time you add a phosphorus atom, 1183 00:53:34,610 --> 00:53:38,160 lets say, you introduce a static positive charge 1184 00:53:38,160 --> 00:53:41,060 and a mobile negative charge when that electron leaves. 1185 00:53:41,060 --> 00:53:42,860 And so you now have all of these scattering 1186 00:53:42,860 --> 00:53:44,834 centers of positive charge. 1187 00:53:44,834 --> 00:53:46,750 And so as you increase the number of dopants-- 1188 00:53:46,750 --> 00:53:54,340 this for silicon-- you decrease the mobility of your material, 1189 00:53:54,340 --> 00:53:57,010 and it's also greatly a function of temperature. 1190 00:53:57,010 --> 00:54:02,995 I think that's mostly due to either phonon scattering-- 1191 00:54:02,995 --> 00:54:03,930 is that right? 1192 00:54:03,930 --> 00:54:07,006 Is there any other mechanism I'm missing, [INAUDIBLE], 1193 00:54:07,006 --> 00:54:09,690 if you're still there? 1194 00:54:09,690 --> 00:54:11,520 AUDIENCE: Sorry, I was on mute. 1195 00:54:11,520 --> 00:54:13,200 Yes, I think you're good so far. 1196 00:54:13,200 --> 00:54:16,050 We'll keep it simple, and use the simplest case first. 1197 00:54:16,050 --> 00:54:18,860 I think that makes [INAUDIBLE]. 1198 00:54:18,860 --> 00:54:21,630 PROFESSOR: But importantly is that higher temperatures, you 1199 00:54:21,630 --> 00:54:26,140 generally get a much lower, lower mobility. 1200 00:54:26,140 --> 00:54:27,580 And again, hitting home for-- this 1201 00:54:27,580 --> 00:54:29,690 is not true necessarily for silicon, 1202 00:54:29,690 --> 00:54:38,171 but for a lot of these heterojunction devices-- 1203 00:54:38,171 --> 00:54:40,420 so for example, organics have very, very low diffusion 1204 00:54:40,420 --> 00:54:42,600 lengths, and a lot of it's limited by mobility. 1205 00:54:42,600 --> 00:54:48,695 And so what you do is you make these Interdigitated-- what 1206 00:54:48,695 --> 00:54:49,570 I would call p and n. 1207 00:54:49,570 --> 00:54:53,139 I forget the organic analogy, but p and n layers 1208 00:54:53,139 --> 00:54:54,680 that interdigitated so that they only 1209 00:54:54,680 --> 00:54:57,190 have to diffuse not the width of the device, 1210 00:54:57,190 --> 00:54:58,980 but the length of those fingers. 1211 00:54:58,980 --> 00:55:01,335 So you effectively need a much shorter diffusion length. 1212 00:55:01,335 --> 00:55:02,710 And so this is talking about some 1213 00:55:02,710 --> 00:55:05,248 of those other different ideas, and-- 1214 00:55:05,248 --> 00:55:08,039 AUDIENCE: I'm sorry, that was a heterojunction? [INAUDIBLE]. 1215 00:55:08,039 --> 00:55:10,330 PROFESSOR: A heterojunction is two different materials. 1216 00:55:10,330 --> 00:55:12,274 AUDIENCE: OK, what was the thing you were just 1217 00:55:12,274 --> 00:55:13,250 describing with the-- 1218 00:55:13,250 --> 00:55:17,586 PROFESSOR: That's an interdigitated pn structure. 1219 00:55:26,156 --> 00:55:28,030 Yeah, so what we're going to be talking about 1220 00:55:28,030 --> 00:55:33,320 is the product of n and mu. 1221 00:55:33,320 --> 00:55:37,280 And if you recall that your conductivity-- so hold on. 1222 00:55:37,280 --> 00:55:40,010 Let's go back. 1223 00:55:40,010 --> 00:55:41,940 What we have here is that we have 1224 00:55:41,940 --> 00:55:47,680 a highly doped semiconductor. 1225 00:55:47,680 --> 00:55:50,050 So this is about 10 to the 16th, and then we 1226 00:55:50,050 --> 00:55:51,260 have our intrinsic silicon. 1227 00:55:51,260 --> 00:55:54,720 So this has no dopants in it whatsoever. 1228 00:55:54,720 --> 00:55:57,170 And now, you remember from last lecture 1229 00:55:57,170 --> 00:55:59,560 when we applied a voltage across the terminals, 1230 00:55:59,560 --> 00:56:01,900 a current started to flow, and when we heated it up, 1231 00:56:01,900 --> 00:56:02,955 what had happened? 1232 00:56:02,955 --> 00:56:04,964 Who remembers? 1233 00:56:04,964 --> 00:56:06,130 AUDIENCE: Current increased. 1234 00:56:06,130 --> 00:56:07,796 PROFESSOR: Current increased, and that's 1235 00:56:07,796 --> 00:56:10,990 due to more thermally excited carriers. 1236 00:56:10,990 --> 00:56:14,800 And so your intrinsic carrier concentration goes up. 1237 00:56:14,800 --> 00:56:18,800 And so what was-- for room temperature, what's 1238 00:56:18,800 --> 00:56:20,300 the intrinsic carrier concentration? 1239 00:56:20,300 --> 00:56:24,570 It's about 10 to the 10th-- in that range. 1240 00:56:24,570 --> 00:56:30,450 And so in increase-- so a small increase in temperature 1241 00:56:30,450 --> 00:56:32,200 can greatly increase the intrinsic carrier 1242 00:56:32,200 --> 00:56:34,410 concentration-- maybe something like 10 to the 12th. 1243 00:56:34,410 --> 00:56:36,910 Now in a doped semiconductor, is that 1244 00:56:36,910 --> 00:56:38,492 going to affect it as much? 1245 00:56:38,492 --> 00:56:40,700 How about you guys think about that for a little bit. 1246 00:56:40,700 --> 00:56:42,080 Mute and talk to your neighbor. 1247 00:56:42,080 --> 00:56:43,830 And so I'm going to heat both of these up, 1248 00:56:43,830 --> 00:56:45,540 one with a high dopant concentration, 1249 00:56:45,540 --> 00:56:46,425 and one with a low. 1250 00:56:46,425 --> 00:56:47,800 And which one you think will have 1251 00:56:47,800 --> 00:56:50,133 the highest relative change in connectivity and in which 1252 00:56:50,133 --> 00:56:52,439 direction? 1253 00:56:52,439 --> 00:56:53,730 So I'll give you three minutes. 1254 00:57:01,810 --> 00:57:04,552 So we're now going to subject. 1255 00:57:04,552 --> 00:57:05,760 You've seen this demo before. 1256 00:57:05,760 --> 00:57:09,250 We're now going to subject our intrinsic carrier to my hair 1257 00:57:09,250 --> 00:57:11,920 dryer. 1258 00:57:11,920 --> 00:57:14,460 And right now we're getting-- let's see. 1259 00:57:14,460 --> 00:57:16,560 It's about 10 microamps. 1260 00:57:16,560 --> 00:57:25,990 And if we heat this guy up-- did I mix these two up? 1261 00:57:25,990 --> 00:57:27,790 Ah, there we go. 1262 00:57:27,790 --> 00:57:31,870 So you can see we get a rather large increase in current. 1263 00:57:31,870 --> 00:57:35,227 That was up to 100 microamps, so a factor of 10. 1264 00:57:35,227 --> 00:57:36,310 So quite a large increase. 1265 00:57:38,840 --> 00:57:43,170 So let's see a show of hands. 1266 00:57:43,170 --> 00:57:46,146 So right now we're getting-- maybe 1267 00:57:46,146 --> 00:57:49,240 we need to put this on milliamps. 1268 00:57:49,240 --> 00:57:51,530 So we're getting about 58 milliamps of current 1269 00:57:51,530 --> 00:57:52,952 through the semiconductor. 1270 00:57:52,952 --> 00:57:55,160 Who thinks that the current is going to increase when 1271 00:57:55,160 --> 00:57:56,480 we add more thermal carriers? 1272 00:57:59,224 --> 00:58:00,390 This is where the doped one. 1273 00:58:00,390 --> 00:58:01,473 We just saw the intrinsic. 1274 00:58:05,660 --> 00:58:08,262 Do you think it'll go up, the connectivity? 1275 00:58:08,262 --> 00:58:09,720 So this is the doped semiconductor. 1276 00:58:09,720 --> 00:58:13,300 Now who think it's going to stay the same? 1277 00:58:13,300 --> 00:58:15,684 Who thinks it's going to go down? 1278 00:58:15,684 --> 00:58:16,850 All right, so this is split. 1279 00:58:16,850 --> 00:58:18,160 Wow. 1280 00:58:18,160 --> 00:58:24,380 So right now we're getting about 57 milliamps, and let's heat 1281 00:58:24,380 --> 00:58:27,026 this guy up and see what happens. 1282 00:58:27,026 --> 00:58:28,900 And so you can see, it's actually going down. 1283 00:58:28,900 --> 00:58:31,165 It's now 52, 50, 49. 1284 00:58:34,360 --> 00:58:37,770 So what's important is that we're measuring conductivity. 1285 00:58:37,770 --> 00:58:39,460 It's not only how many carriers we have, 1286 00:58:39,460 --> 00:58:41,330 but also how well they can move around. 1287 00:58:41,330 --> 00:58:43,650 And it's, again, that product of number 1288 00:58:43,650 --> 00:58:45,156 of carriers times the mobility. 1289 00:58:45,156 --> 00:58:46,530 And again, each of those carriers 1290 00:58:46,530 --> 00:58:47,530 carries an electric charge. 1291 00:58:47,530 --> 00:58:50,071 So you put the electric charge of an electron in front of it. 1292 00:58:52,037 --> 00:58:54,370 This is what I was supposed to have up in the background 1293 00:58:54,370 --> 00:58:55,430 while that was happening. 1294 00:58:55,430 --> 00:58:57,580 AUDIENCE: The intrinsic still had to go change, right? 1295 00:58:57,580 --> 00:58:58,080 [INAUDIBLE]. 1296 00:58:58,080 --> 00:59:00,110 PROFESSOR: Yeah, so again, remember 1297 00:59:00,110 --> 00:59:02,220 there was huge changes. 1298 00:59:02,220 --> 00:59:03,500 One was measuring milliamps. 1299 00:59:03,500 --> 00:59:05,296 One was measuring microamps. 1300 00:59:05,296 --> 00:59:07,420 So if we look at room temperature, we have about 10 1301 00:59:07,420 --> 00:59:09,440 to the 10th intrinsic carriers. 1302 00:59:09,440 --> 00:59:12,000 So this is for intrinsic silicon with no dopants whatsoever. 1303 00:59:12,000 --> 00:59:14,910 As we increase the heat, I don't think 1304 00:59:14,910 --> 00:59:17,450 we're going to 500 degrees, but let's say we get the 400. 1305 00:59:17,450 --> 00:59:22,900 We're only going up by a factor of 100, which is substantial, 1306 00:59:22,900 --> 00:59:25,850 but if we had 10 to the 16th carriers 1307 00:59:25,850 --> 00:59:28,274 originally from our dopants, these added number 1308 00:59:28,274 --> 00:59:29,690 of intrinsic carriers aren't going 1309 00:59:29,690 --> 00:59:31,630 to have really much of an effect at all 1310 00:59:31,630 --> 00:59:33,060 in terms of the connectivity. 1311 00:59:33,060 --> 00:59:34,870 So what's really affecting the dope case 1312 00:59:34,870 --> 00:59:36,540 is that our mobility actually goes down 1313 00:59:36,540 --> 00:59:38,123 with temperature due to the scattering 1314 00:59:38,123 --> 00:59:40,050 events with temperature. 1315 00:59:40,050 --> 00:59:42,590 And for intrinsic silicon, you get a little bit better 1316 00:59:42,590 --> 00:59:44,510 mobility, so it's a little bit higher, 1317 00:59:44,510 --> 00:59:46,218 but they both have the same general trend 1318 00:59:46,218 --> 00:59:49,150 of lower mobility, but only by, let's say, 1319 00:59:49,150 --> 00:59:51,260 this is about a factor of 10, where 1320 00:59:51,260 --> 00:59:57,260 it was about a factor of 100 for the intrinsic carrier. 1321 00:59:57,260 --> 00:59:59,770 So again, our carriers in the intrinsic case 1322 00:59:59,770 --> 01:00:00,890 go up by a factor of 100. 1323 01:00:00,890 --> 01:00:02,640 Our mobility goes up by a factor of 10, 1324 01:00:02,640 --> 01:00:06,220 so the conductivity then has to increase by a factor of 10. 1325 01:00:06,220 --> 01:00:08,810 And for our doped semiconductor, really the heat 1326 01:00:08,810 --> 01:00:11,062 is just hurting our conductivity because 1327 01:00:11,062 --> 01:00:13,270 of the decrease in mobility, and the thermal carriers 1328 01:00:13,270 --> 01:00:16,410 don't really add-- they're washed out 1329 01:00:16,410 --> 01:00:18,370 by the sea of dopant atoms that are really 1330 01:00:18,370 --> 01:00:19,556 adding all the carriers. 1331 01:00:19,556 --> 01:00:20,056 Yeah? 1332 01:00:20,056 --> 01:00:23,840 AUDIENCE: So if you were to obviously heat up 1333 01:00:23,840 --> 01:00:26,230 [INAUDIBLE] more-- [INAUDIBLE] the doped more, 1334 01:00:26,230 --> 01:00:29,098 it would probably eventually get to the intrinsic case 1335 01:00:29,098 --> 01:00:31,120 where there are constant increases, 1336 01:00:31,120 --> 01:00:35,259 but would you ever want your solar cell that hot? 1337 01:00:35,259 --> 01:00:37,550 PROFESSOR: Would you ever you your solar cell that hot? 1338 01:00:37,550 --> 01:00:38,902 That's a good question. 1339 01:00:38,902 --> 01:00:40,485 AUDIENCE: Yeah, I don't know how [INAUDIBLE] would it 1340 01:00:40,485 --> 01:00:40,790 melt [INAUDIBLE]. 1341 01:00:40,790 --> 01:00:43,320 PROFESSOR: So let's go-- there's an equation for that, 1342 01:00:43,320 --> 01:00:45,255 and we'll talk about that later, too. 1343 01:00:49,170 --> 01:00:51,930 So if you look at our VOC, if we have a large saturation 1344 01:00:51,930 --> 01:00:59,010 current, that means that we're going to have a very low VOC. 1345 01:00:59,010 --> 01:01:00,520 We have this reverse current that's 1346 01:01:00,520 --> 01:01:02,050 going in the opposite direction of our illumination 1347 01:01:02,050 --> 01:01:04,210 current that's opposing that illumination current. 1348 01:01:04,210 --> 01:01:08,960 And so if it's large, then it'll hurt our VOC. 1349 01:01:08,960 --> 01:01:13,530 And you can see that it scales with d, which scales with kt, 1350 01:01:13,530 --> 01:01:16,170 and so we get this increase in temperature 1351 01:01:16,170 --> 01:01:19,270 is increasing this J0. 1352 01:01:19,270 --> 01:01:23,581 And so for most types of cells, heat 1353 01:01:23,581 --> 01:01:25,830 is very, very bad, especially for crystalline silicon. 1354 01:01:25,830 --> 01:01:27,150 For amorphous silicon, it's different. 1355 01:01:27,150 --> 01:01:28,941 Well, I'm not going to get into that today, 1356 01:01:28,941 --> 01:01:32,570 but for crystalline silicon, heat is generally 1357 01:01:32,570 --> 01:01:35,770 very bad for the performance. 1358 01:01:35,770 --> 01:01:38,950 And when you do testingg-- so for example, 1359 01:01:38,950 --> 01:01:44,390 when NREL does testing, they'll rate all your cells at AM1.5G, 1360 01:01:44,390 --> 01:01:49,090 some calibrated solar simulator that's illuminating 1361 01:01:49,090 --> 01:01:49,592 your sample. 1362 01:01:49,592 --> 01:01:51,300 And they're kept at constant temperature, 1363 01:01:51,300 --> 01:01:52,883 so the temperature is always reported, 1364 01:01:52,883 --> 01:01:54,440 and it's generally kept at the 25 C. 1365 01:01:54,440 --> 01:01:56,690 So the temperature is a very important characteristic. 1366 01:01:59,050 --> 01:02:03,430 But to answer your question, if, again, we 1367 01:02:03,430 --> 01:02:06,590 looked at an Arrhenius plot-- so this is 1/kt. 1368 01:02:06,590 --> 01:02:08,580 So this is high temperatures over here, 1369 01:02:08,580 --> 01:02:09,720 low temperatures over here. 1370 01:02:12,708 --> 01:02:15,520 And this is carrier concentration. 1371 01:02:15,520 --> 01:02:22,419 At very, very high temperatures, when your thermal carrier-- 1372 01:02:22,419 --> 01:02:24,460 so if you extend this out to higher temperatures, 1373 01:02:24,460 --> 01:02:25,918 you can see that this will actually 1374 01:02:25,918 --> 01:02:29,702 surpassed the number of dopant atoms, 1375 01:02:29,702 --> 01:02:30,910 and you'll actually increase. 1376 01:02:30,910 --> 01:02:32,493 So this is high temperature over here. 1377 01:02:37,184 --> 01:02:38,850 Your carrier concentration will actually 1378 01:02:38,850 --> 01:02:42,940 increase at much, much higher temperatures, 1379 01:02:42,940 --> 01:02:46,260 and this is what's the extrinsic region. 1380 01:02:46,260 --> 01:02:49,070 So your donor concentration is pretty much only determined 1381 01:02:49,070 --> 01:02:52,009 by your dopant density, so this is ND. 1382 01:02:52,009 --> 01:02:53,550 And then at low enough temperatures-- 1383 01:02:53,550 --> 01:02:55,508 so this is very low temperatures-- you actually 1384 01:02:55,508 --> 01:02:58,120 start freezing out you're donor electrons 1385 01:02:58,120 --> 01:02:59,940 into these donor states. 1386 01:03:02,910 --> 01:03:05,330 So that actually sums it up. 1387 01:03:05,330 --> 01:03:07,220 If you guys have other questions, 1388 01:03:07,220 --> 01:03:08,980 feel free to ask them, but we actually 1389 01:03:08,980 --> 01:03:10,670 can end a little bit early. 1390 01:03:10,670 --> 01:03:14,200 I do have your homework, so if you want those, come up here. 1391 01:03:14,200 --> 01:03:18,410 And I think [INAUDIBLE] posted the projects online 1392 01:03:18,410 --> 01:03:22,800 so you can finish homework number three. 1393 01:03:22,800 --> 01:03:24,580 That's it.