1 00:00:08,152 --> 00:00:11,497 The Earth intercepts a lot of solar power: 2 00:00:11,497 --> 00:00:14,579 173 thousand terawatts. 3 00:00:14,579 --> 00:00:19,300 That's ten thousand times more power than the planet's population uses. 4 00:00:19,300 --> 00:00:20,950 So is it possible that one day 5 00:00:20,950 --> 00:00:24,447 the world could be completely reliant on solar energy? 6 00:00:24,447 --> 00:00:25,698 To answer that question, 7 00:00:25,698 --> 00:00:31,959 we first need to examine how solar panels convert solar energy to electrical energy. 8 00:00:31,959 --> 00:00:36,263 Solar panels are made up of smaller units called solar cells. 9 00:00:36,263 --> 00:00:39,183 The most common solar cells are made from silicon, 10 00:00:39,183 --> 00:00:43,297 a semiconductor that is the second most abundant element on Earth. 11 00:00:43,297 --> 00:00:44,589 In a solar cell, 12 00:00:44,589 --> 00:00:48,567 crystalline silicon is sandwiched between conductive layers. 13 00:00:48,567 --> 00:00:53,776 Each silicon atom is connected to its neighbors by four strong bonds, 14 00:00:53,776 --> 00:00:58,077 which keep the electrons in place so no current can flow. 15 00:00:58,077 --> 00:00:59,203 Here's the key: 16 00:00:59,203 --> 00:01:03,886 a silicon solar cell uses two different layers of silicon. 17 00:01:03,886 --> 00:01:07,036 An n-type silicon has extra electrons, 18 00:01:07,036 --> 00:01:12,289 and p-type silicon has extra spaces for electrons, called holes. 19 00:01:12,289 --> 00:01:14,223 Where the two types of silicon meet, 20 00:01:14,223 --> 00:01:17,922 electrons can wander across the p/n junction, 21 00:01:17,922 --> 00:01:19,979 leaving a positive charge on one side 22 00:01:19,979 --> 00:01:23,063 and creating negative charge on the other. 23 00:01:23,063 --> 00:01:26,785 You can think of light as the flow of tiny particles 24 00:01:26,785 --> 00:01:28,125 called photons, 25 00:01:28,125 --> 00:01:30,185 shooting out from the Sun. 26 00:01:30,185 --> 00:01:34,131 When one of these photons strikes the silicon cell with enough energy, 27 00:01:34,131 --> 00:01:38,529 it can knock an electron from its bond, leaving a hole. 28 00:01:38,529 --> 00:01:43,321 The negatively charged electron and location of the positively charged hole 29 00:01:43,321 --> 00:01:45,734 are now free to move around. 30 00:01:45,734 --> 00:01:48,752 But because of the electric field at the p/n junction, 31 00:01:48,752 --> 00:01:51,355 they'll only go one way. 32 00:01:51,355 --> 00:01:53,376 The electron is drawn to the n-side, 33 00:01:53,376 --> 00:01:56,362 while the hole is drawn to the p-side. 34 00:01:56,362 --> 00:02:01,995 The mobile electrons are collected by thin metal fingers at the top of the cell. 35 00:02:01,995 --> 00:02:04,750 From there, they flow through an external circuit, 36 00:02:04,750 --> 00:02:06,065 doing electrical work, 37 00:02:06,065 --> 00:02:07,606 like powering a lightbulb, 38 00:02:07,606 --> 00:02:11,974 before returning through the conductive aluminum sheet on the back. 39 00:02:11,974 --> 00:02:15,067 Each silicon cell only puts out half a volt, 40 00:02:15,067 --> 00:02:18,658 but you can string them together in modules to get more power. 41 00:02:18,658 --> 00:02:22,763 Twelve photovoltaic cells are enough to charge a cellphone, 42 00:02:22,763 --> 00:02:26,364 while it takes many modules to power an entire house. 43 00:02:26,364 --> 00:02:29,478 Electrons are the only moving parts in a solar cell, 44 00:02:29,478 --> 00:02:31,854 and they all go back where they came from. 45 00:02:31,854 --> 00:02:33,882 There's nothing to get worn out or used up, 46 00:02:33,882 --> 00:02:37,057 so solar cells can last for decades. 47 00:02:37,057 --> 00:02:42,874 So what's stopping us from being completely reliant on solar power? 48 00:02:42,874 --> 00:02:44,970 There are political factors at play, 49 00:02:44,970 --> 00:02:48,954 not to mention businesses that lobby to maintain the status quo. 50 00:02:48,954 --> 00:02:53,065 But for now, let's focus on the physical and logistical challenges, 51 00:02:53,065 --> 00:02:54,482 and the most obvious of those 52 00:02:54,482 --> 00:02:58,852 is that solar energy is unevenly distributed across the planet. 53 00:02:58,852 --> 00:03:01,219 Some areas are sunnier than others. 54 00:03:01,219 --> 00:03:02,859 It's also inconsistent. 55 00:03:02,859 --> 00:03:07,228 Less solar energy is available on cloudy days or at night. 56 00:03:07,228 --> 00:03:09,638 So a total reliance would require 57 00:03:09,638 --> 00:03:14,102 efficient ways to get electricity from sunny spots to cloudy ones, 58 00:03:14,102 --> 00:03:17,087 and effective storage of energy. 59 00:03:17,087 --> 00:03:20,393 The efficiency of the cell itself is a challenge, too. 60 00:03:20,393 --> 00:03:23,444 If sunlight is reflected instead of absorbed, 61 00:03:23,444 --> 00:03:28,130 or if dislodged electrons fall back into a hole before going through the circuit, 62 00:03:28,130 --> 00:03:30,893 that photon's energy is lost. 63 00:03:30,893 --> 00:03:33,241 The most efficient solar cell yet 64 00:03:33,241 --> 00:03:38,634 still only converts 46% of the available sunlight to electricity, 65 00:03:38,634 --> 00:03:43,642 and most commercial systems are currently 15-20% efficient. 66 00:03:43,642 --> 00:03:45,529 In spite of these limitations, 67 00:03:45,529 --> 00:03:47,204 it actually would be possible 68 00:03:47,204 --> 00:03:50,618 to power the entire world with today's solar technology. 69 00:03:50,618 --> 00:03:52,984 We'd need the funding to build the infrastructure 70 00:03:52,984 --> 00:03:54,971 and a good deal of space. 71 00:03:54,971 --> 00:03:59,440 Estimates range from tens to hundreds of thousands of square miles, 72 00:03:59,440 --> 00:04:00,976 which seems like a lot, 73 00:04:00,976 --> 00:04:06,312 but the Sahara Desert alone is over 3 million square miles in area. 74 00:04:06,312 --> 00:04:09,039 Meanwhile, solar cells are getting better, cheaper, 75 00:04:09,039 --> 00:04:11,986 and are competing with electricity from the grid. 76 00:04:11,986 --> 00:04:16,967 And innovations, like floating solar farms, may change the landscape entirely. 77 00:04:16,967 --> 00:04:18,956 Thought experiments aside, 78 00:04:18,956 --> 00:04:21,018 there's the fact that over a billion people 79 00:04:21,018 --> 00:04:24,481 don't have access to a reliable electric grid, 80 00:04:24,481 --> 00:04:26,567 especially in developing countries, 81 00:04:26,567 --> 00:04:28,842 many of which are sunny. 82 00:04:28,842 --> 00:04:30,096 So in places like that, 83 00:04:30,096 --> 00:04:34,979 solar energy is already much cheaper and safer than available alternatives, 84 00:04:34,979 --> 00:04:36,579 like kerosene. 85 00:04:36,579 --> 00:04:38,646 For say, Finland or Seattle, though, 86 00:04:38,646 --> 00:04:42,041 effective solar energy may still be a little way off.