Perovskite: Revolutionizing the Solar Industry

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Most solar cells are currently made of silicon. But recent research has proved that perovskite might soon replace silicon. This would both decrease the cost for consumers, and increase the efficiency of the panels. Here’s some of the reasons why.

Some science behind solar panels

Solar panels consist of many individual solar cells, which sandwich glass, a semiconductive material, and wires together. The semiconductor converts the photons in sunlight into electrons, which run through the wires to provide energy to your home. 

A diagram showing each individual section of a solar panel.

The semiconductor within solar cells has historically been composed of silicon. Silicon-based semiconductors are, unfortunately, difficult and expensive to manufacture, and are a driving force behind high solar panel costs. They also have a maximum possible efficiency of only 33%, because they can only absorb relatively low wavelengths. 

Recently, scientists have begun researching a group of materials called perovskites. Perovskites would be much less expensive to manufacture and could increase the solar panels’ maximum possible efficiency. The atoms within perovskite bond to one another in a unique pattern (aka a “crystal structure”) much different from that of silicon. The properties of materials are determined by their structures, so perovskites display many material properties different from silicon. (More on crystal structures at the very bottom of this article.)

Benefits of perovskite over silicon

The properties improved by using perovskite over silicon include easier manufacturing, the ability to generate more energy, increased transparency and flexibility, and decreased weight. Each of these benefits leads to less expensive and more useful applications for solar panels. 

  1. Easier manufacturing. While silicon cells require several rounds of manufacturing, perovskite cells can simply be printed into sheets, which decreases manufacturing costs enormously. Little research has been done on the magnitude of this decrease, but an estimate is made below.
  2. Greater efficiency. Perovskite cells could surpass the maximum potential efficiency of silicon; they can be manufactured such that they absorb photons of a much higher wavelength than is possible with silicon. 

In 2006, the maximum efficiency of perovskite solar cells was about 3%. After years of research, its efficiency has increased to 25.2%, while the record for pure silicon solar cells is holding steady at 27%. Tandem silicon-perovskite solar cells have increased further to 29.1%. A commercialized tandem silicon-perovskite cell might have an efficiency closer to 24%, which is still 5-10% higher than the efficiency of traditional silicon solar cells.

Additionally, Dr. Daniel Gamelin (a chemistry professor from the University of Washington) has developed “perovskite quantum dots,” which go on the surface of solar cells. These dots emit two low-energy photons per high-energy photon absorbed. Solar cells can typically produce one electron per photon, so doubling the number of photons doubles the potential efficiency. Where silicon solar cells have a maximum theoretical efficiency of 33%, perovskite cells could attain closer to 66%. Efficiencies above 45% are unheard of, so this would be revolutionary.

A diagram showing the glass, silicon, and backing parts of a solar panel.

Additional benefits of perovskite

  1. Increased transparency. Adding different combinations of elements into the perovskite crystal structure alters its transparency. While the solar cells couldn’t be crystal-clear, they could reach the transparency of a stained glass window. These semi-transparent solar panels might replace windows in addition to roof installations, which would further increase their energy potential.
  2. Increased flexibility and decreased weight. While silicon cells need to be at least 100 μm (that’s a micrometer) thick, perovskite cells can be as thin as 1 μm. This decreased thickness allows for the cells to be more flexible and lightweight. Flexibility is important because it means that the cells are harder to break, and both flexibility and low weight contribute to easier transportation.

The increased efficiency and decreased manufacturing costs of perovskite solar cells decrease the price of solar panels by an estimated $0.65/kWh (assuming a cost of $4.22/kWh per silicon solar panel). In an average home solar installation costing $14,000, this would save a homeowner $2,800–and as perovskite cells continue to improve, these savings will continue to increase. 

Additionally, the market value of perovskite solar cells is estimated to increase by $1.5 billion from 2017 to 2022. This increased market value will undoubtedly come with more advances in the industry, and more decreases in cost to homeowners.

Drawbacks to perovskite

Unfortunately, in addition to introducing several benefits, perovskite also presents several issues. These issues mean that perovskite panels aren’t quite on the market yet. Scientists are working on overcoming these problems, which include toxicity due to lead, deterioration in water exposure, and defects in the crystal structure.

A perovskite crystal structure floating above solar panels.

  1. Toxicity. Some perovskite cells are manufactured with both lead iodide and a lead halide, both of which pose health and environmental concerns. Researchers have proposed alternative compounds to replace lead in the crystal structure, including tin iodides and germanium halides. These ideas show early successes and are promising, but are still in development.
  2. Deterioration. The cells also deteriorate with water exposure, which is impractical for solar panels destined for the outdoors. Researchers have resolved this by adding graphene (or other protective layers) into the perovskite; this protects it from water. However, this solution is not yet mainstream. 
  3. Defects in the crystal structure. Perovskite cells are limited by defects throughout the material, which are uncommon, but lead to decreased efficiency. Researchers have discovered that the larger the crystals within the material–or the more times the crystal structure can repeat itself before a new crystal structure begins–the fewer defects appear in the material. 

Changing how the perovskite is manufactured–adding one heating (annealing) step into the printing process, for example–can increase the crystal size and decrease the number of defects. Adding this one step into the process keeps manufacturing costs below those of silicon. This process is also not yet mainstream.

As these issues are being overcome, there is reason to believe that soon, the benefits of perovskite will soon outweigh the drawbacks. Perovskite cells might therefore soon become more popular than silicon. 

The cost of a solar panel installation for your home would continue to decrease as perovskite seeps into the market.

References: 

https://www.cei.washington.edu/education/science-of-solar/perovskite-solar-cell/

https://www.nrel.gov/pv/perovskite-solar-cells.html

https://www.perovskite-info.com/perovskite-solar

https://www.energy.gov/eere/solar/perovskite-solar-cells

https://cleantechnica.com/2020/02/21/how-low-can-solar-cells-go-perovskite-researchers-say-down-down-down/

https://docs.google.com/document/d/18GphwM7TjdtNLCjB2L0e2UoNiGwnvlN967Htt9bigi4/edit

https://www.perovskite-info.com/perovskite-solar-panel-efficiency-current-market-status

https://www.nature.com/articles/d41586-019-01985-y

https://www.tandfonline.com/doi/full/10.1080/14686996.2018.1460176

https://cleantechnica.com/2017/10/03/coal-killing-perovskite-solar-cell-problem-solved-almost-graphene/

https://www.nature.com/articles/s41528-018-0035-z

More materials science behind perovskite

Every molecule has a very specific structure its atoms typically fall into; for example, NaCl forms a simple cube of alternating Na+ cations and Cl- anions. 

The silicon structure is slightly more complex, as shown below.

Perovskites are a group of materials that form a simpler crystal structure than silicon, known as the CaTiO3 (or ABX3) structure. The A, B, and X can each be replaced with any number of elements, as long as the charges balance out. In CaTiO3, for example, the Ca has a 2+ charge, the Ti has a 4+ charge, and the O has a 2- charge. The formula that gives us is 2+4-2*3=0, which shows us that the charges balance out. So almost any combination of two positive ions and one negative ions that cancel out their charges would fall into this crystal structure. 

Mineral Perovskite. Chemical formula. Vector illustration. Color can change quickly

This unique crystal structure is what gives perovskite so many benefits over silicon, especially its abilities to absorb more wavelengths. The crystal structure also increases its conductivity (perovskite can be a superconductor), which allows it to convert higher amounts of energy. Perovskite’s crystal structure is why it’s such a vast improvement from silicon in solar cells.

https://www.chegg.com/homework-help/questions-and-answers/catio3-perovskite-structure-figure-1–ionic-radius-ca-2-0106-nm-ti-4-0064-nm-o-2-0132-nm-a-q20067715

The different structure of perovskite gives it many advantages over silicon, as discussed above.

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