A team of scientists, headed by a Pakistani, has developed a solar cell technology that sets two new world records of efficiency in the lab. The approach could help foster clean energy initiatives to combat the global warming issue.
Yasir Siddique, a PhD scholar at the Korea Institute of Energy Research (KIER) and the University of Science and Technology (UST), Daejeon, South Korea, has designed and fabricated solution-processed Copper Indium Sulphu Selenide (CISSe) solar cells.
The stable solution-processed, low bandgap CISSe device perfectly works as a single cell, but could also be sandwiched with other thin-film solar cell materials having suitable bandgap as top cell-like recently emerging solar cell technology of perovskite in tandem solar cell configuration.
The bandgap is the amount of energy needed to free the electron from any semiconductor; the lower the bandgap the more it produces electricity.
Our sun is an average 150 million kilometres away but a primary source of light and heat for our planet. Theoretically, the sun throws 1,360 watts per square metre of mixed energy on a surface directly facing it.
However, the sunlight on any solar cell largely reflected or passed through the structure and a few per cent of energy converts directly from sunlight into electricity. So, the power conversion rate, roughly called the efficiency is the degree to which a solar cell converts energy from sunrays.
There are many types of solar cells with varied efficiencies. The first, second and third generation of solar cells is another way to describe them. Different types of solar cell have different efficiencies, for instance, traditional silicon cell has efficiency from 15 to 20 per cent while concentrated solar cells could be 41 per cent efficient but need focused beams at one place.
However, Siddique’s cell falls in the emerging trend of Tandem solar technology and is now most efficient in its category.
Siddique’s recent innovation took three years to develop and finally the CISSe only cell allows the efficiency of 14.4 per cent when it is blended with perovskite (perovskite/CISSe) cell touched the efficiency of 23.03 per cent. This is the highest efficiency as compared to all solution-processed (perovskite/CISSe) solar cell category.
Siddique’s record efficiency solar cell has been certified Photovoltaic test laboratory at KIER, is an ISO/IEC17025 certified test centre and accredited by Korea Laboratory Accreditation Scheme (KOLAS) which signed the ILAC-MRA (International Laboratory Accreditation Cooperation-Mutual Recognition Arrangement). The patent is to be filed soon and the studies published in the top research journal of the world Energy and Environmental Science have an impact factor of 38.532.
“It is the single largest high impact research published from KIER, Daejeon Campus in the recent times,” Yasir Siddique said.
THE RECEPIE: In the previous record, a team of Chinese, Americans and Australians declared 13.5 per cent efficiency of the same type of solar cells. But that cell fabrication was only possible in glass-based glove box filled with Nitrogen gas. A huge amount of Nitrogen was needed in mass production which made commercialisation nearly impossible.
Siddique also devised a magic ingredient to make the device more stable and it was a molecular ink.
“We successfully eradicated the need for Nitrogen and carved the cell in an open [ambient] air environment. The CISSe based thin film was made possible due to the addition of N, N-dimethylformamide (DMF) based molecular ink which has the ability to make highly stable complexes with Thiourea and metal chlorides,” Siddique added.
Later on, the KIER team used air annealing temperature – common heating and cooling method used in electronics – not only to remove carbon contents in the cell’s absorber film but also proposed a way to control and acquire an optimum degree of crystallisation of the precursor layer. Perfect crystallisation is much needed for desired results.
Air annealing is used to further enhance the physical, optical or structural properties in electronics fabrication. For example, heat treatment of steel is a common procedure in which the metal is made more ductile.
Air annealing of four exact samples was performed on 210, 230, 280 and 330 degrees centigrade. Out of these temperatures, 230°C has been found to be experimentally optimum air annealing temperature and at this temperature, they were able to fabricate a CISSe solar cell device having a certified world record efficiency of 14.4 percent.
This study revealed that air annealing temperature in solution-processed chalcogenide device formation is a significantly important parameter to control the electrical properties, unlike previously published research where all the emphasis has been given to selenisation temperature and pressure.
In the next move, a thin perovskite solar cell was placed upon CISSe cell for further study. The Eureka moment observed when this double-layered; all-solution processed perovskite/CISSe tandem solar cell shows the efficiency of 23.03 percent which is also a world record in this category of solar cells.
Discovered in the 1800s by Russian scientists, Perovskite is an emerging promising mineral to carve efficient solar cells and Siddique further enhanced this by adding the CISSe device.
Long last stability is another important factor of solar panels. For instance, the traditional silicon-based cell can withstand all weathering conditions for 20 to 30 years. The KIER’s cell has promising stability as well.
“We have analysed our new record holder solar cell for the past one year and it is working on the same efficiency perfectly,” Siddique said.