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If you told the average person only thirty years ago that black panels left in the sun would generate copious amounts of electricity for homes and businesses, the likeliest reaction would have been a condescending grin. Luckily the technology to capture energy from the sun — which shines enough light on Earth’s surface in an hour to power the whole world’s energy for an entire year — has improved immensely, to the point that for many homeowners it’s cheaper to install solar panels on their rooftop than to use the grid.

The first solar cell was constructed by Charles Fritts in the 1880s and had a conversion efficiency of just 1% — hardly enough to be useful. Today, however, the most efficient commercially available solar panels on the market have efficiency ratings as high as 22.5%, while the majority of panels range from 12% to 16% efficiency rating. However, solar efficiency can climb to rated efficiencies as high as 46%, in the case of multi-junction photovoltaic (PV) cells that pick up energy from multiple different spectra.

If all this sounds somewhat familiar, it’s because plants have been harnessing energy from the sun for hundreds of millions of years — there’s nothing new about how solar energy works, we are just using it in a different way. Plants convert the sun’s energy into chemical energy, whereas solar cells produce electricity. This leads us to an important question: how do solar panels work?

Solar panels ABC

Solar panels generate electricity when photons knock electrons off from the material. In fact, a solar panel is comprised of an array of smaller units called photovoltaic cells, which are the things that actually convert solar energy into electricity. The typical solar panel is additionally comprised of a metal frame, a glass casing, and various wiring to allow current to flow from the silicon cells. Because solar panels generate direct current, an inverter is also required to allow you to use the electricity in your home.

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Physics-wise, solar power is predicated on the photovoltaic effect (photo meaning “light” and voltaic meaning “electricity”), in which two dissimilar materials in close contact produce an electrical voltage when struck by light or other radiant energy. In solar energy, the materials belong to a class called semiconductors — neither conductors nor electrical insulators that allow electrons to flow under certain conditions. The most common semiconductor used in the solar industry is silicon.

Semiconductors can be one of two types: P and N. Every solar cell sandwiches two of these semiconductors, one layer of P-type and one layer of N-type (which looks a lot like a battery).

P-type semiconductors tend to pick up a small positive charge while N-type ones have a negative charge. Typically, the semiconducting material is riddled with impurities that make them more susceptible to donating or accepting electrons because crystals such as silicon or germanium do not usually allow electrons to move freely from atom to atom. It’s all very similar to how one of the battery’s electrodes has a negative voltage with respect to the other, but applied in a different context.

It’s the P-N junction where electrons are free to cross from one side to the other, but not in the opposite direction. Imagine a hill — electrons can easily go down the hill (to the N side), but can’t climb it (to the P side).

Each photon with enough energy will normally free exactly one electron, causing a ‘hole’ to form. The electric field will then cause the electron to migrate to the N side and the hole to the P side.

This happens when an electron is lifted up to an excited state by consuming energy received from the incoming light. Were it not for a junction-forming material, the free electrons would have eventually fallen back to the ground state.  And because the electrons are only allowed to flow in a single direction — from N-type to P-type — the photovoltaic effect produces a direct current.  This current, together with the cell’s voltage, defines the power (or wattage) that the solar cell can produce.

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