The Mystery Flaw of Solar Panels

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This episode of Real Engineering is brought to you by Brilliant, the problem solving website

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that teaches you to think like an engineer.

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Installed global capacity of solar cells has increased year on year for the past decade,

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fueled by the plummeting prices and rising efficiency of solar cells. [1] Forcing fossil

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fuel producers out of the market through technological advance.

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At the end of 2019, the total installed capacity of photovoltaic cells exceeded 630 thousand

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Megawatts, an astounding figure that is going to continue to rise in the coming decades.

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However, in the 40 years we have been using solar cells, there has been a mysterious flaw

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that has been sapping away potential electric current from the photovoltaic cells.

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Upon testing in the laboratory, newly manufactured solar cells display an efficiency of about

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20%. Meaning they could convert 20% of the incoming energy from sunlight into electric

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current. However, within hours of operation, that efficiency would drop to 18%. [2] A 10%

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drop in total electric generation. Losing 10% of 630,000 Megawatts of power is no small

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problem. That’s equivalent to about 30 nuclear power plants worth of power capacity, if the

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solar panels could operate all day, which they can’t, but you get the point. There's

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a lot of potential electricity being lost.

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It’s no wonder that scientists and engineers have been hunting down the cause of this problem,

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termed light induced degradation, for 40 years. And last year, we may have finally cracked

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the problem and found the cause behind this mysterious loss in power. To understand it

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we first have to understand how photovoltaic cells work.

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Photovoltaic cells use the photovoltaic effect to generate a current. An effect where photons

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of a particular threshold frequency striking a material can cause electrons to gain enough

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energy to free them from their atomic orbits and move freely in the material. [3]

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This is best achieved with semiconductors, whose unique properties lying between conductors

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and insulators allows them to most easily elevate electrons from atomic orbit to moving

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freely among their atoms.

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Some of the first solar cells were created using selenium, like this one, created by

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Charles Fritts, sitting atop a New York in 1884 [4] A revolutionary device that produced

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a consistent current of electricity, but it was achieving an efficiency of just 1%. Converting

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1% of the energy striking it in the form of light, into electricity. This, in combination

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with the high cost of selenium, made it a unviable source of electricity.

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To succeed these devices needed to compete with fossil fuel power sources.

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Before the photovoltaic effect could power the world, scientists and engineers would

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need to figure out how to increase that efficiency percentage and do it with cheaper materials.

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Enter Silicon. A common semiconductor material that has formed the bedrock of the electronic

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age. This is going to be our starting material for our solar cell. Let’s build a solar

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cell from scratch and see how efficiencies were gradually increased over time.

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Let’s first look at what happens when light interacts with a pure silicon crystal like

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this.

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Incoming light can do one of three things. It can be reflected, absorbed, or simply pass

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right through it. If the light is reflected or passes through, it cannot produce the photovoltaic

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effect.

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Step one to improving our efficiency is to minimize the amount of light that gets reflected

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off the material. This is wasted energy that affects our efficiency level. In fact, 30%

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of light that strikes untreated silicon is reflected. So before we even start, our maximum

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efficiency drops to 70%. [5]

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For this reason, Silicon is often treated with a layer of silicon monoxide which can

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reduce the light reflected to just 10%, while a second layer with a secondary material,

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like Titanium Dioxide can reduce it as low as 3% [6]

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Texturing the surface of the material can further increase the probability of the light

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being absorbed. If it is textured like this, light that is initially reflected has another

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chance to strike the material and be absorbed.

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Only light that is absorbed can potentially cause the photovoltaic effect, but not all

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light will. We need photons above a threshold energy to increase an electron’s energy

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enough to allow it to move freely in the material.

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A photon’s energy is defined by multiplying planck’s constant by its frequency. Silicon

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requires photons with 1.1 electron volts to produce the photovoltaic effect, which corresponds

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to a wavelength of 1,110 nanometres [7]

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This lies around here in the light spectrum and any lower energy light from here down

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cannot cause the photovoltaic effect. This light will simply cause the atom to vibrate

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and create heat.

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This graph shows the total solar energy being emitted by the sun, however a good deal of

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this does not reach the Earth’s surface as it is absorbed in the atmosphere. This

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is a more realistic graph. About 4% of the energy reach earth’s surface is in ultraviolet,

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as the sun emits relatively little ultraviolet photons. 44% is in the visible spectrum, and

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52% is in the infrared spectrum. This may sound surprising, as infrared light is lower

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energy, but it covers a wider range of the spectrum and thus accounts for more energy.

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Because silicon cannot make use of light with a wavelength greater than 1,110 nanometres,

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everything from here up is energy we cannot convert to electricity. This represents about

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19% of the total energy reaching earth.

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Another thing to note is that light with higher energy does not release more electrons, it

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simply produces higher energy electrons. For example, blue light has roughly twice the

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energy of red light, but the electrons that blue light release simply lose their extra

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energy in the form of heat. Producing no extra electricity. This energy loss results in about

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33% of sunlights energy being lost.[8]

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So these spectrum losses alone cause a 52% loss in efficiency. This is a lot of energy

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to lose, but silicon sits near the ideal threshold frequency that balances these two energy losses.

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Capturing enough of the lower energy wavelengths, while not losing too much efficiency as a

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result of the material heating up. [9]

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The reason’s solar panels lose efficiency as they get hotter is quite complicated and

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outside the scope of this video, but for now all you need to know is that silicon balances

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these factors best for terrestrial purposes.

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This is such a large loss in power that in some climates active cooling, which takes

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some of the electricity the panels create to cool the panels, actually results in more

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electricity being generated.

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Onto the next problem.

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Knocking an electron free by itself does not create an electrical current in our circuit.

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It just frees an electron to float freely about the material. To create a useful current

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we have to force this electron around an external circuit where it can do work. Freeing an electron

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also creates a positively charged “hole” in its place, that is also free to move about

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the material. If an electron meets a hole, it simply fills it and our energy is wasted.

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The next trick to maximise efficiency is to limit the chances electrons have to fill these

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holes and to force them into our circuit as quickly as possible. To do this we use the

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unique properties of silicon.

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Silicon has 4 electrons in its outer shell, and thus readily forms a crystal structure

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with 4 neighbouring atoms using covalent bonds, a bond where neighbouring atoms share an electron

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pair.

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We can manipulate this behaviour and tailor the crystals material properties by adding

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impurities, called dopants.

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Say we add boron atoms to the silicon crystal wafer. These boron atoms have 3 electrons

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available for bonding with the silicon crystal, but silicon wants 4. So this creates a “hole”

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in the crystal that wants to be filled with an electron. We call this a p-type as it has

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positive charge carriers

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Now, let’s say we create another wafer of silicon, but this time we add atoms with 5

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electrons available for bonding, like phosphorus. Again the phosphorus bonds with the silicon,

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but this time we have an excess electron that can float freely about the material. We call

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this an n-type, because it has negative charge carriers.

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Now, let’s sandwich these two materials together and see what happens.

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The positive holes and negative electrons migrate towards each other. The electrons

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will jump into the p-type and the holes jump into the n-type. This causes an imbalance

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of charge, because now the p-type side has more negative charges, and the n-type has

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more positive charges.

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We have just formed an electromagnetic valve that allows electrons to pass in one direction.

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Let’s see how this works.

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Suppose a photon with sufficient energy enters the p-type side of the solar cell and knocks

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an electron free. The electron starts bouncing around the material and one of two things

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can happen. It can recombine with a hole, resulting in no current, or it can come into

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the electromagnetic field at the junction of the material. Here the electromagnetic

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field actually accelerates the electron across the junction into the n-type side [10], where

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there are very few holes for it to fill, and to boot, the junction’s electromagnetic

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field actually prevents the electron from passing back to the other side. A similar

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thing happens on the n-type side, where holes are selectively transported across the junction

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before they can recombine. This means one side of the junction becomes negatively charged,

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while the other side becomes positively charged, we have created a potential difference or

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in other words a voltage. If we add some metal contacts and an external load circuit, these

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electrons will pass along the circuit to recombine with the holes on the other side. We have

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just created a solar cell.

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You may notice a problem here though, by adding metal contacts to the upper surface of the

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solar cell, we have just blocked light from entering the cell, and thus reduced it’s

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efficiency.

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This is yet another problem engineers have had to think carefully about in their quest

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to optimize solar cell efficiency.

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Over the years engineers have optimized both the shape and manufacturing techniques to

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minimize the area covered by the metal electrodes, while also minimizing the resistance the electrons

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will face in entering the external circuit.

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One research paper used topology optimization to design these electric contacts. [11] Topology

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optimization uses algorithms to optimize the design of objects using constraints the engineer

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inputs. Using this method for the electric contacts produced something remarkably like

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the vasculature of a leaf, and that shouldn’t really surprise you.

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Footage: Vasculature tissue on a leaf does not perform

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photosynthesis. It instead brings the water that is essential for photosynthesis to the

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leaf and extracts the useful products,, serving a similar purpose as our electric contacts,

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so of course plants have developed the perfect shape to optimize the energy they can absorb

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from the sun. Plants have had millions of years to evolve this shape[10] However, most

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solar cells use a simple grid shape, as it is cheap to manufacture. This typically results

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in an efficiency loss of about 8%.

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All told, these effects result in typical modern silicon solar cells having a laboratory

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tested efficiency of 20%.

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So, what was happening to cause that drop to 18% after a couple of hours of operation?

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This problem was the focus of hundreds of scientific papers and many found clues to

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the problem. [12] Many noted that the efficiency drop was correlated to the concentration of

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boron and oxygen in the silicon and noted that the drop did not occur when boron was

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substituted for gallium. Thus, it was known a boron oxygen defect was causing the issue.

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Others found that the defects could be reversed by heating the silicon in the dark at 200

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degrees for 30 minutes, but it would return once again upon exposure to the light. Efforts

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in reducing the problem have primarily focused on reducing the concentration of oxygen impurities

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in the silicon wafers, which occur as a result of the czochralski silicon wafer manufacturing

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technique that is the source of the 95% of silicon solar cells. These manufacturing techniques

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are still a point of research [14] and the engineers and scientists were working blindly.

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Little was known about the actual defect creation process and how exactly it was causing such

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a large drop in efficiencies, leaving engineers with less information to solve the problem

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with.

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This paper used a special imaging technique and observed these boron oxygen molecules

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converting into something the paper refers to as “shallow acceptors” when exposed

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to light. [13] In essence, they observed the defects transforming into little electron

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traps that acted as recombination sites, and thus reduced the time and probability of electrons

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entering the circuit to do work.

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With this knowledge, engineers can now develop better techniques for preventing this phenomenon

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and hopefully help increase our renewable energy capacity in the coming years.

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It’s easy to think that technology has reached a point of being so advanced that knowing

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where things can be improved is practically impossible for the average person, but that

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simply isn't true. A little bit of research into any area will reveal countless problems

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humans are still grappling with fixing.

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When I started researching this video, I knew little about solar panels beyond the basics.

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In order to make this video, I took a week to deep dive into some college textbooks using

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my knowledge of material science and electronics to guide my research, but I had some gaps

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in understanding that the college textbooks just assumed I had preexisting knowledge of.

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Terms like “band gap” and “fermi levels” kept appearing, and without understanding

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these terms, I couldn’t make complete sense of the explanations.

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These were like canyons in my journey for knowledge. I couldn’t advance until I filled

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them in. So, half way through the research and writing process, I decided to stop what

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I was doing. I changed my tactics. I decided to take the Brilliant course on solar energy,

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because I knew Brilliant would guide me through the very basics of the subject right through

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to the more complicated concepts. It worked a treat. All the little gaps in my understanding

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were filled in and I could now read scientific papers and college textbooks without feeling

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like I was reading a foreign language.

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