A team of researchers at the University of Houston has invented a new type of solar energy harvesting system that has broken the efficiency record of all existing technologies and could one day be deployed to use solar power 24/7, according to a press release by the institution.

Solar energy is the most abundant form of renewable energy available to us. Advances in solar energy harvesting systems mean that we can harvest a fair percentage of sunlight that is received upon Earth and efforts are ongoing to increase this number every day.

The result was an STPV that was closer to achieving the Landsberg limit and increasing the chances of making a single junction photovoltaic cells, thereby further increasing the efficiency of the system.

Such STPVs would be more compact and could also be combined with a thermal energy storage unit to generate electricity 24/7. This would be a much easier system to build up and use when compared to plans of putting mirrors in space to access solar energy at night to transition to a carbon-free electric grid.

According to estimates by the Solar Energy Technologies Office at the U.S. Department of Energy, solar energy could account for as much as 45 percent of the U.S. electric supply by 2050. A system of nonreciprocal STPVs could drastically increase this number, and the severe limitation associated with solar energy would go away.

The research findings were published last month in the journal Physical Review Applied.

Abstract

Traditional solar thermophotovoltaics (STPVs) rely on an intermediate layer to tailor sunlight for better efficiencies. However, the thermodynamic efficiency limit of STPVs, which has long been understood to be the blackbody limit (85.4%), is still far lower than the Landsberg limit (93.3%), the ultimate efficiency limit for solar energy harvesting. In this work, we show that the efficiency deficit is caused by the inevitable back emission of the intermediate layer towards the sun resulting from the reciprocity of the system. We hereby propose nonreciprocal solar theromophotovoltaics (NSTPV) that utilize an intermediate layer with nonreciprocal radiative properties. Such a nonreciprocal intermediate layer can substantially suppress its back emission to the sun and funnel more photon flux towards the cell. We show that, with such improvement, the NSTPV system can reach the Landsberg limit, and practical NSTPV systems with single-junction photovoltaic cells can also experience a significant efficiency boost.