| Solar power developments
Another 1800 MW of PV for MBR solar park
Dubai Electricity and Water Authority (DEWA) has signed a contract with Masdar (Abu Dhabi Future Energy Company) to build and operate the 1800 MW of photovoltaics comprising the sixth phase of the Mohammed bin Rashid Al Maktoum solar park, described as the world’s largest single site solar facility.
Completion of this sixth phase, at a cost of AED5.51 billion, will take the total installed capacity of the solar park to 4660 MW. The current installed capacity is 2427 MW and a further 433 MW is under construction. All phases of this landmark project are expected to be completed by 2030, representing a total investment of AED50 billion. Masdar says it was selected for the sixth phase from 23 “high-calibre international
bidders” and offered a levelised cost of energy (LCOE) of USD 1.6215 cents per kWh, the lowest for any of DEWA’s solar independent power producer (IPP) model projects to date. Mohammed Jameel Al Ramahi, Masdar CEO, said; “Following our successful delivery of phase three of the Mohammed bin Rashid Al Maktoum Solar Park as part of an international consortium, this latest award once again shows that Masdar is a global leader in clean energy as we move forwards from 20 GW capacity today to reach 100 GW of clean energy capacity by 2030 driving decarbonisation at home and abroad.” Masdar is active in more than 40 countries.
Dubai is aiming for 100% clean energy by 2050.
Above and below: Mohammed bin Rashid Al Maktoum Solar Park (photos: DEWA)
Combination of stressors key to testing perovskite cells
Perovskite solar cells should be subjected to a combination of stress tests simultaneously to best predict how they will function outdoors, according to researchers at the US Department of Energy’s National Renewable Energy Laboratory (NREL).
Solar cells must endure a set of harsh conditions—often with variable combinations of changing stress factors—to judge their stability, but most researchers conduct these tests indoors with a few fixed stressing conditions. While these tests provide some necessary insight, understanding which stressor applied during indoor tests provided predictive correlations with outdoor operation is critical. “We must understand how well perovskite solar cells will perform outdoors, under real conditions, to move this technology closer to commercialisation,” said Kai Zhu, a senior scientist in the Chemistry and Nanoscience Center at NREL. “That’s why we identified accelerated testing protocols that can be conducted in the laboratory to reveal how these cells would function after six months in operation outside.”
Zhu is lead author of a newly published paper, “Towards linking lab and field lifetimes of perovskite solar cells,” which appears in the journal Nature. His co-authors from NREL are Qi Jiang, Robert Tirawat, Ross Kerner, E. Ashley Gaulding, Jimmy Newkirk, and Joseph Berry. Other co-authors are from the University of Toledo, who have collaborated with Zhu on several other recent papers about perovskites. Outdoor conditions, such as humidity, heat, and even light, put stress on solar cells. As a result, the efficiency of solar cells declines and power production decreases over time. To reach the reliability targets for commercialisation of perovskite technology, protocols must first be established so that improvements from different groups can be easily validated and compared. Researchers tend to test the stability of perovskite solar cells by exposing them to light and under low temperatures. However, a broad range of testing conditions exist, making it challenging to compare different studies and discern their relevance to achieving the reliability needed for commercialization.
The NREL-led research team put perovskite
solar cells through a battery of tests. During the test for operational stability, the cells retained more than 93% of their maximum efficiency after about 5030 hours of continuous operation. The cells were subjected to thermal cycling, with temperatures repeatedly fluctuating between -40 and 85 degrees Celsius. After 1000 cycles, the cells showed an average of about 5% degradation.
The tests addressed different stressors, such as light and heat, separately. However, in real- world conditions, these individual factors act simultaneously to affect solar cell performance. When combined, for example, light and heat significantly accelerate performance degradation or cause new problems that were otherwise absent or occurring at slower rates when testing separately.
The researchers concluded that high temperature and illumination is the most critical combination of stressors for understanding how well a perovskite solar cell will perform outdoors.
The US Department of Energy Solar Energy Technologies Office funded the research.
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