These Record-Breaking New Solar Panels Produce 60 Percent More Electricity

Experimental cells that combine silicon with a material called perovskite have broken the efficiency record for converting solar energy—and could eventually supercharge how we get electricity.

THIS ARTICLE IS republished from The Conversation under a Creative Commons license.

The sight of solar panels installed on rooftops and large energy farms has become commonplace in many regions around the world. Even in the gray and rainy UK, solar power is becoming a major player in electricity generation.

This surge in solar is fueled by two key developments. First, scientists, engineers, and those in industry are learning how to make solar panels by the billions. Every fabrication step is meticulously optimized to produce them very cheaply. The second and most significant is the relentless increase in the panels’ power conversion efficiency—a measure of how much sunlight can be transformed into electricity.

The higher the efficiency of solar panels, the cheaper the electricity. This might make you wonder: Just how efficient can we expect solar energy to become? And will it make a dent in our energy bills?

Commercially available solar panels today convert about 20 to 22 percent of sunlight into electrical power. However, new research published in Nature has shown that future solar panels could reach efficiencies as high as 34 percent by exploiting a new technology called tandem solar cells. The research demonstrates a record power-conversion efficiency for tandem solar cells.

What Are Tandem Solar Cells?

Traditional solar cells are made using a single material to absorb sunlight. Currently, almost all solar panels are made from silicon—the same material at the core of microchips. While silicon is a mature and reliable material, its efficiency is limited to about 29 percent.

To overcome this limit, scientists have turned to tandem solar cells, which stack two solar materials on top of each other to capture more of the sun’s energy.

In the new Nature paper, a team of researchers at the energy giant LONGi has reported a new tandem solar cell that combines silicon and perovskite materials. Thanks to their improved sunlight harvesting, the new perovskite-silicon tandem has achieved a world record 33.89 percent efficiency.

Perovskite solar materials, which were discovered less than two decades ago, have emerged as the ideal complement to the established silicon technology. The secret lies in their light absorption tunability. Perovskite materials can capture high-energy blue light more efficiently than silicon.

In this way, energy losses are avoided and the total tandem efficiency increases. Other materials, called III-V semiconductors, have also been used in tandem cells and achieved higher efficiencies. The problem is they are hard to produce and expensive, so only small solar cells can be made in combination with focused light.

The scientific community is putting tremendous effort into perovskite solar cells. They have kept a phenomenal pace of development with efficiencies (for a single cell in the lab) rising from 14 percent to 26 percent in only 10 years. Such advances enabled their integration into ultra-high-efficiency tandem solar cells, demonstrating a pathway to scale photovoltaic technology to the trillions of watts the world needs to decarbonize our energy production.

The Cost of Solar Electricity

The new record-breaking tandem cells can capture an additional 60 percent of solar energy. This means fewer panels are needed to produce the same energy, reducing installation costs and the land (or roof area) required for solar farms.

It also means that power plant operators will generate solar energy at a higher profit. However, due to the way that electricity prices are set in the UK, consumers may never notice a difference in their electricity bills. The real difference comes when you consider rooftop solar installations where the area is constrained and the space has to be exploited effectively.

The price of rooftop solar power is calculated based on two key measures: first, the total cost to install solar panels on your roof, and second, how much electricity they will generate over 25 years of operation. While the installation cost is easy to obtain, the savings from generating solar electricity at home are a bit more nuanced. You can save money by using less energy from the grid, especially in periods when it is costly, and you can also sell some of your surplus electricity back to the grid. However, grid operators pay a very small price for this electricity, so sometimes it is more advantageous to use a battery and store the energy for use at night.

Using average considerations for a typical British household, I have calculated the cash savings to consumers using rooftop solar panels. If we can improve panel efficiency from 22 percent to 34 percent without increasing the installation cost, savings in electricity bills will rise from £558ְ ($747) per year up to £709 ($950) per year. A 27 percent bump in cash savings that would make solar rooftops extremely attractive, even in gray and cloudy Britain.

So When Can We Buy These New Solar Panels?

As research continues, considerable efforts are being made to scale up this technology and ensure its long-term durability. The record-breaking tandem cells are made in laboratories and are smaller than a postage stamp. Translating such high performance to meter-square areas remains a vast challenge.

Yet we are making progress. Earlier this month, Oxford PV, a solar manufacturer at the forefront of perovskite technology, announced the first sale of its newly developed tandem solar panels. They have successfully tackled the challenges of integrating two solar materials and making durable and reliable panels. While they are still far from 34 percent efficiency, their work shows a promising route for next-generation solar cells.

Another consideration is the sustainability of the materials used in tandem solar panels. Extracting and processing some of the minerals in solar panels can be hugely energy-intensive. Besides silicon, perovskite solar cells require the elements lead, carbon, iodine, and bromine as components to make them work properly. Connecting perovskite and silicon also requires scarce materials containing an element called indium, so there is plenty of research still required to address these difficulties.

Despite the challenges, the scientific and industrial communities remains committed to developing tandem solar devices that could be integrated into almost anything—cars, buildings, and planes.

The recent developments toward high-efficiency perovskite-silicon tandem cells indicate a bright future for solar power, ensuring that solar continues to play a more prominent role in the global transition to renewable energy.

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