• Noor Solar Power Plant in Al Dhafra region of Abu Dhabi, photo courtesy of WAM

Khalifa University’s Dr. Matteo Chiesa, Professor of Mechanical Engineering, and PhD student Harry Apostoleris, reveal how large solar plants in the UAE can sell unsubsidized electricity for under 3c/kWh and still turn a profit

When the Noor Abu Dhabi solar power plant was switched on in June, it became the cheapest operational solar plant in the world, and the third time within two years that the UAE has broken the record for cheap solar.

At 2.94 US cents per kilowatt-hour, Noor demonstrates that large-scale renewable energy can compete with fossil fuels, which today typically cost in the range of 4-6 US cents per kWh.

The significant cost decline in solar power has been driven primarily by technological innovation, but also innovation in project structuring and financing; a critical finding which was reported by Khalifa University’s Dr. Matteo Chiesa, Professor of Mechanical Engineering, and PhD student Harry Apostoleris in a paper published last year in the journal Nature Energy.

“We studied the different cost components of the Masdar/EDF-developed Mohammed Bin Rashid Solar Park Phase3 project, which will sell electricity for 2.99¢/kWh, and other large solar projects in the UAE and began to understand, piece by piece, how each of these cost components were reduced to the point that the electricity generated by these plants could be sold for under 3¢/kWh,” Apostoleris explained.

The UAE is the first country to breach the 3 ¢/kWh barrier. Many people assumed that the government put in large hidden subsidies to make the cost so low. In the US, Europe and other places, solar energy has historically been subsidized, either by a feed-in tariff or by tax incentives. But in these large UAE solar plants, the electricity is unsubsidized.

“We found that many factors played a small, but important role in bringing costs down. For example, the UAE’s utility companies signed long 25-years or more contracts to buy electricity from these solar power plants, which gives the developers more time to pay off the initial investment. The UAE was one of the first countries to make 25-year contracts standard for solar power plants, instead of the 15-20 year contracts more commonly seen in the past,” Apostoleris said.

The study also reports that certain costs, like construction and maintenance labor, are lower in the UAE than in European or US markets, where most cost studies are done. The plants also have a unique hybrid ownership structure – they are partly owned by the companies that built them, and partly by the utility – which allows some costs to be shared between the project developer and the utility company.

The two factors that reportedly had the biggest impact on driving costs down were the cost of solar panels and costs related to financing.

Thanks to mass production, a solar panel that would have cost US$500 at the beginning of this decade now costs less than US$100. Furthermore, the market has been flooded by massive manufacturing companies producing new solar panels as fast as they can.

“Developers in the UAE were able to take advantage of this buyer’s market to purchase huge amounts of hardware very cheaply, which greatly reduces the cost of building the plant,” Apostoleris said.

The project developers were also able to get large loans at low interest rates alongside major investments from state-backed companies, representing a true innovation in the financing and project structuring.

A follow-up paper, published in the proceeding of the 46^th IEEE Photovoltaics Specialist’s Conference, and presented at the conference meeting in Chicago last month, focused on the financing packages that were given to the UAE’s solar projects.

“We developed a cost model to demonstrate that, under the given financing terms, the projects are profitable even when selling electricity for less than 3¢/kWh,” Apostoleris explained.

In the paper, the researchers suggest ways that other countries can follow the lead of the UAE by developing programs to support low-cost financing of large renewable energy projects.

“Many countries have a capability of issuing large state-backed loans to project developers or making direct investments in well-designed solar projects. Our aim in these two papers is both to show people how the UAE was able to produce the world’s cheapest unsubsidized solar energy, and to suggest ways that other countries can learn from our experience to support the continued expansion of solar energy,” Dr. Chiesa remarked.

Erica Solomon
Senior Editor
29 July 2019

Dr. Ammar Nayfeh describes the innovative research taking place at Khalifa University to drive down costs and increase efficiency of solar cells

By Dr. Ammar Nayfeh

While harnessing the power of the sun is nothing new – Alexandre Edmond Becquerel discovered the photovoltaic effect in 1839 whereby electricity is generated from sunlight – finding increasingly better ways to convert an ever larger share of sunlight into electricity has become arguably one of the most important research challenges of our time.

When first discovered, photovoltaic power was very inefficient. Even when the first commercial solar photovoltaic panel was unveiled in 1954, it converted just 6 percent of the energy from sunlight to electricity. The first solar panels used selenium, but researchers in the 1950s realized that semiconducting materials like silicon were more efficient. The only problem? Silicon solar cells were expensive to produce—and the 6 percent efficiency rate was achieved with a silicon solar cell.

We have made significant progress over the past 50 years. Today, the most efficient solar panel on the market has an efficiency rating of 22.2 percent. But as solar power becomes responsible for delivering a large and exponentially growing fraction of the world’s energy needs, improving efficiency even further is critical.

Solar power presents a problem of two halves: getting high-efficiency cells but at a low cost. Khalifa University, through its flagship research institute Masdar Institute, has long been at the forefront of research into solar technology and its projects have been solving this problem.

As Associate Professor of Electrical Engineering and Computer Science at Khalifa University, I lead on a number of projects aimed at advancing new materials and devices to improve solar cell efficiencies.

One such project was the result of a collaboration between Khalifa University and the Massachusetts Institute of Technology (MIT). We developed an innovative multi-junction solar cell that leverages a unique ‘step-cell’ design approach and low-cost silicon using gallium arsenide phosphide-based materials. The new step-cell combines two different layers of sunlight-absorbing material to harvest a broader range of the sun’s energy and benefits from a novel, low-cost manufacturing process.

Former Khalifa University PhD Student and now professor at University of Dubai, Dr. Sabina Abdul Hadi, provided the foundational research for this step-cell as part of her doctoral thesis. She realized that when the top gallium arsenide phosphide layer completely covered the bottom silicon layer, the lower energy photos were absorbed by the silicon germanium—the substrate on which the gallium arsenide phosphide is grown—thus limiting solar cell efficiency. By etching away the top layer and exposing some of the silicon layer, she was able to increase the efficiency and add a new degree of freedom in the design.

The step cell design allows for cheaper fabrication and, while there is still a lot of research and development that needs to be undertaken prior to commercialization, innovations like this are an exciting part of a rapidly growing research area and industry.

In traditional silicon-based PV cells, only some of the sun’s wavelengths from the visible light spectrum are absorbed and converted into electricity. Much of the research being done by me and my research group is focused on exploring how to use advanced materials to access the full spectrum of solar energy.

For example, the use of silicon and gold nanomaterials on solar cells was investigated with two KU MSc graduates, Kazi Islam and Farsad Chowdhury. We demonstrated that by using nanomaterials on the surface of solar cells, we can enhance the solar cells’ light trapping properties. The nanoparticles increase a solar cell’s ability to absorb sunlight by increasing the amount of surface scattering or by having the ability to absorb photons and re-emit them at a lower energy the solar cell can use.

In another project with Dr. Nazek El Etab, PhD graduate from KU and current Postdoc at KAUST in Saudi Arabia, we used atomic layer deposition (ALD) – an advanced method of coating a material by depositing it in thin films, one atomic layer at a time – to grow zirconium dioxide and zinc oxide nanomaterials. We layered the nanomaterials on a solar cell to enhance efficiency.

With former Khalifa University PhD student Dr. Aaesha Alnuaimi, currently Head of Solar Research at Dubai Electricity and Water Authority (DEWA), we fabricated graphene-silicon solar cells by introducing a thin layer of a high dielectric constant material, which is an insulator that becomes polarized when an electric field is applied, also using the ALD method. The efficiency of the graphene-silicon solar cells quadrupled with the interlayer relative to the same cells without the interlayer.

Developing new methods to make high-efficient solar cells affordable is a major focus of my research. I worked with Dr. Ghada Dushaq, PhD graduate from KU and current Postdoc at New York University Abu Dhabi, to develop a low temperature germanium growth method for gallium arsenide using plasma-enhanced chemical vapor deposition (PECVD). Germanium provides a crystal lattice compatible with that of gallium arsenide and so the germanium layer can be used as the bottom cell in a multi junction solar cell, or as a virtual substrate on which to grow gallium arsenide. Gallium arsenide is a semiconductor material that allows more efficient photon absorption and high output power density than most materials. In a current collaboration with Stanford University, we recently demonstrated an important breakthrough in the growth of gallium arsenide directly on a low-temperature germanium layer.

More recently, Khadija Jumaa, a 2019 KU MSc graduate, presented a paper at the IEEE Photovoltaic Specialist Conference (PVSC) conference in Chicago in June 2019 on the most efficient way to grow amorphous silicon, which are used in thin-film silicon solar cells, using a PECVD growth method. In this work, she studied how different temperatures affect the growth of amorphous silicon using PECVD, and determined the optimal temperature required to grow amorphous silicon, which will contribute towards finding even cheaper and more sustainable ways to develop amorphous silicon for lower-cost solar cells.

All this advanced material based solar research work leverages the outstanding clean room and testing facility we have in the UAE at the Khalifa University Masdar Institute campus.

As the team from Khalifa University works towards developing new materials and devices for high-efficiency solar panels to global energy production, it is inspiring and encouraging to know that research like this in the UAE can lead to an avalanche of improvements down the line, creating potential for a technological leap in the industry, at a time when the world is looking to renewable energy to power an increasingly energy-hungry planet.

Dr. Ammar Nayfeh is Associate Professor of Electrical Engineering and Computer Science at Khalifa University of Science and Technology