Perovskite solar panels: an expert guide

Solar-technology
Last updated on 4 September 20245 min read

Find out about the main benefits and drawbacks of perovskite solar panels, and why they're not available yet.

Photo of author Melody Abeni
Written byMelody Abeni
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A hand holding up a small perovskite solar cell, with a cartoon yellow information booklet to the right of the hand

At a glance

šŸ“ˆ Perovskite is more efficient than silicon

Perovskite is better at absorbing a part of the light spectrum that silicon can't handle well, while silicon is more stable. The efficiency of this combination has recently reached a staggering 34.6%.

Unfortunately, this superior performance has only been achieved with small solar cells in laboratories.

Cells are less efficient when they're combined into a panel. The current efficiency record for a perovskite-silicon panel is 26.9%, held by UK-based company Oxford PV.

šŸ› ļø But solar panels made from perovskite have significant stability issues

Currently, perovskite solar cells are unstable and have a significantly shorter life than silicon cells.

Perovskite cells are more sensitive to things like oxygen, moisture and heat, which can significantly degrade their performance in a matter of months.

Naturally, this is a vital area of research for perovskite solar panel manufacturers.

šŸ“… Perovskite solar panels won't be available to purchase for a while

Despite the exciting developments in the lab, perovskite solar panels are still a long way from being commercially available.

Manufacturers have been aiming to bring the panels to market for years, but repeated delays have raised doubts about their realistic timeline.

Achievements in laboratory settings with small-scale solar cells donā€™t always translate directly to commercial-scale production.

šŸŒ Their production process may have a slightly lower carbon footprint

Perovskite solar panels use raw materials that are cheap, abundant and easy to find all over the world.

The manufacturing process for perovskite solar panels is also relatively simple and can be conducted at lower temperatures than that of traditional silicon panels.Ā 

āš–ļø Perovskite solar panels are light and flexible, so they could have more uses

Perovskite solar panels only need a very thin layer of perovskite material, which allows for lightweight and flexible panel designs.

They could work well in a variety of innovative settings, including curved surfaces, building-integrated photovoltaics, and portable electronics.

Due to their high efficiency, perovskite solar panels have captured the attention of both the scientific community and the renewable energy industry. However, this material still has a number of fundamental problems, and itā€™s not clear when it will enter the mainstream residential solar market.Ā 

In this article, weā€™ll run through exactly how perovskite solar panels differ from their silicon cousins, and explore their key benefits and drawbacks.Ā 

If you'd like to find out how much a solar & battery system could save you on your energy bills, answer a few quick questions below and we'll provide you with an estimate.

What are perovskite solar panels?

Perovskite solar panels are a type of solar panel that uses perovskite materials as the active layer to generate electricity from sunlight.Ā 

Itā€™s a bit complicated, but the term ā€˜perovskiteā€™ can actually refer to two things - either a natural crystalline material first discovered in Russiaā€™s Ural Mountains, or a manmade material that imitates the crystal structure of the natural material.

In the context of perovskite solar panels, itā€™s the manmade crystal structure thatā€™s used in the manufacturing process.

How do perovskite solar panels work?

Perovskite solar panels work by converting daylight into electricity using a layer of perovskite materials, through a process called the photovoltaic effect.Ā 

Compared to traditional silicon panels, perovskite panels can be more efficient, cheaper to manufacture, and more flexible. Some manufacturers are combining perovskite with silicon layers to create hybrid solar cells for even better performance and stability.

However, perovskite solar panels are not currently available for purchase, and it could be several years before this happens.

How are they different from silicon solar panels?

Perovskite solar panels have the advantage of being thinner, lighter, and more flexible than silicon panels, making them easier to use in different applications. Their composition also gives the potential for higher efficiencies and capturing a wider range of light.

However, the latest iteration of perovskite solar panels aren't as stable or reliable as silicon panels, which have been used for decades. In todayā€™s market, 95% of existing solar cells are made of silicon.

Are perovskite solar panels easier to make than silicon panels?

Perovskite solar panels are easier to make than silicon panels in several ways.Ā 

For instance, it only takes very thin layers of perovskite and silicon to make a cell, which helps keep costs low.

The manufacturing process for perovskite is also relatively straightforward and can be done at lower temperatures than that of traditional silicon solar cells.Ā 

These factors contribute to cheaper and more environmentally friendly production costs, making perovskite solar panels an appealing alternative to silicon. Considering the high cost of solar panels, a better and cheaper product can only be a good thing for consumers in the long run.

šŸ¤” Thinking of going solar? Here's why a larger system makes sense ā¬‡ļø

When youā€™re switching to solar, it's worth getting as large a solar & battery system as you can.

A few extra solar panels won't add much to the overall cost, but in most cases they'll have a big impact on your energy bill savings.

And for the majority of homes, a larger battery will significantly increase the value you get from your solar panels.

To understand all the key reasons in detail, check out the articles below.

How efficient are perovskite solar panels?

According to data from the National Renewable Energy Laboratory, perovskite solar cells have achieved the same peak efficiency rate as silicon solar cells in laboratory conditions (26.1%).

However, by layering perovskite on top of silicon (called ā€˜tandem solar cellsā€™), this combines the best of both materials. Perovskite is better at absorbing a part of the light spectrum that silicon can't handle well, while silicon is more stable. The efficiency of this combination has recently reached a staggering 34.6%.

Unfortunately, this superior performance has only been achieved with small solar cells in laboratories, so itā€™s unclear if this could be translated on a much larger scale. In most cases, once you combine solar cells into a whole panel it can dramatically reduce efficiency.Ā 

This combination also comes with increased production costs, as adding silicon is more expensive than producing cells made only of perovskite.

Scientist holding a perovskite-silicon tandem solar module (Oxford PV)

(Source: Oxford PV)

What are the pros and cons of perovskite solar panels?

Perovskite solar panels offer exciting potential for renewable energy generation, but there are still a number of significant drawbacks to be overcome.

The advantages of perovskite solar panels

  • Low carbon footprint
  • Easier and cheaper to produce
  • High efficiency potential
  • Flexibility

Perovskite solar panels use raw materials that are cheap, abundant and easy to find all over the world. The manufacturing process for perovskite solar panels is also relatively simple and can be conducted at lower temperatures than that of traditional silicon panels.Ā 

This simplicity means perovskite solar panels have a smaller carbon footprint during production than silicon solar panels, and it also makes perovskite panels easier and cheaper to produce.

Perovskite solar cells offer a high efficiency potential for converting daylight into electricity. They can absorb a broader spectrum of light than silicon cells, including visible and infrared wavelengths, which means they can generate more electricity.

Perovskite solar panels only need a very thin layer of perovskite material, which allows for lightweight and flexible panel designs. They could work well in a variety of innovative settings, including curved surfaces, building-integrated photovoltaics, and portable electronics.

The disadvantages of perovskite solar panels

  • Challenges in scaling up manufacturing
  • Shorter service life and lower stability
  • Environmental concerns, particularly related to lead content

Although perovskite solar cells have shown impressive results in laboratory settings, translating this success to industrial-scale manufacturing remains a challenge. We currently have some very efficient perovskite solar cells, but manufacturers need to produce whole panels that donā€™t lose efficiency in the process.

Currently, perovskite solar cells are unstable and have a significantly shorter life than silicon cells. Perovskite cells are more sensitive to things like oxygen, moisture and heat, which can significantly degrade their performance in a matter of months. Naturally, this is a vital area of research for perovskite solar panel manufacturers.

According to TNO, current perovskite modules contain small amounts of lead, which pose concerns about their environmental impact. However, efforts are underway to eliminate the use of hazardous materials altogether, with a focus on proper disposal and recycling practices to make sure lead doesnā€™t leach into the environment.

Are perovskite solar panels currently available?

Despite the exciting developments in the lab, perovskite solar panels are still a long way from being commercially available. Manufacturers have been aiming to bring the panels to market for years, but repeated delays have raised doubts about their realistic timeline.Ā 

Achievements in laboratory settings with small-scale solar cells donā€™t always translate directly to commercial-scale production. And stability issues have posed significant challenges to ongoing research and development.Ā 

The solar panel industry still has a lot of work to do to overcome the practical issues around durability and large-scale manufacturing before we can buy perovskite solar for our homes.

If youā€™d like to find out how much a solar & battery system could save you on your energy bills, answer a few quick questions below and weā€™ll provide an estimate.

Perovskite solar panels: FAQs

When can I buy perovskite solar panels?

While advancements continue in research and development, perovskite solar panels arenā€™t yet available for purchase.Ā 

Manufacturers have been optimistic about bringing them to market in the next few years, but issues with the panelsā€™ stability and manufacturing scalability have caused delays.Ā 

How efficient are perovskite solar panels?

When layered on top of silicon in ā€˜tandemā€™ structures, perovskite solar cell efficiency has reached at least 34.6% in laboratory conditions, which is a big step forward for solar technology.

However, these efficiencies have so far only been achieved with individual solar cells, not whole solar panels.

What are the drawbacks of perovskite solar cells?

Perovskite solar cells have several disadvantages, including stability issues that affect their long-term performance and durability. They are more sensitive to heat, moisture and oxygen, which causes them to degrade much faster than silicon cells.Ā 

There are also question marks about their environmental impact, as the use of lead in some perovskite cells has raised concerns about safe disposal.

Finally, there are still challenges around scaling up the production of perovskite panels to a viable commercial level.

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Photo of author Melody Abeni

Written byMelody Abeni

Based in London, Melody is a specialist green technology writer who has been covering sustainability, climate action and ESG for the past five years, after gathering operational experience in green investing and financial services. She has written for various industry publications, including renewable technology advisor The Eco Experts, and she holds a Masterā€™s degree in law from Birkbeck University.

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