A two-sided silicon solar cell—positioned here on aluminum cylinders—is illuminated from above by an infrared laser. Image: Fraunhofer ISEThere is more to solar radiation than meets the eye: sunburn develops from unseen ultraviolet (UV) radiation, while we sense infrared radiation as heat on our skin, though invisible to us. Solar cells also ‘see’ only a portion of solar radiation: approximately 20% of the energy contained in the solar spectrum is unavailable to cells made of silicon—they are unable to utilize a part of the infrared radiation, the short-wavelength infrared (IR) radiation, for generating power.

Researchers of the Fraunhofer Institute for Solar Energy Systems ISE in Freiburg, together with their colleagues at the Univ. of Bern, Switzerland, and the Heriot-Watt Univ. in Edinburgh, Scotland, have now for the first time made a portion of this radiation usable with the assistance of a practical up-converter. The technology that transforms infrared into usable light has been known about since the 1960s. However, it has only been investigated in connection with solar cells since 1996.

“We have been able to adapt both the solar cells and the up-converter so as to obtain the biggest improvement in efficiency so far,” reports Stefan Fischer happily, a scientist at ISE. The potential is big: silicon solar cells theoretically convert about 30% of sunlight falling upon them into electrical power. Up-converters could increase this portion to a level of 40%.

A ladder for light particles

However, how does the up-converter manage to utilize the infrared radiation for the solar cells? As solar radiation falls on the solar cells, they absorb the visible and near-infrared light. The infrared portion is not absorbed, however, it goes right through them. On the backside, the radiation runs into the up-converter—essentially a microcrystalline powder made of sodium yttrium fluoride embedded in a polymer. Part of the yttrium has been replaced by the scientists with the element erbium, which is active in the optical range and responsible in the end for the up-conversion.

As the light falls on this up-converter, it excites the erbium ions. That means they are raised to a higher energy state. You can imagine this reaction like climbing up a ladder: an electron in the ion uses the energy of the light particle to climb up the first step of the ladder. A second light particle enables the electron to climb to the second step, and so on. An ion that has been excited in this manner can “jump down” from the highest step or state. In doing so, it emits light with an energy equal to all of the light particles that have helped the electron to climb on up. The up-converter collects, so to speak, the energy of several of these particles and transfers it to a single one. This has so much energy then that the solar cells “see” it and can utilize it.

Researchers had to adapt the solar cells in order to be able to employ an up-converter such as this. Normally, metal is vapour-deposited on the backside, enabling current to flow out of the solar cells—so no light can shine through normally.

“We equipped the solar cells with metal lattices on the front and rear sides so that IR light can pass through the solar cells. In addition, the light can be used by both faces of the cell—we call this a bi-facial solar cell,” explains Fischer.

Scientists have applied specialized anti-reflection coatings to the front and rear sides of the solar cell. These cancel reflections at the surfaces and assure that the cells absorb as much light as possible.

“This is the first time we have adapted the anti-reflection coating to the backside of the solar cell as well. That could increase the efficiency of the modules and raise their energy yields. The first companies are already trying to accomplish this by implementing bi-facial solar cells,” says Fischer, emphasizing the potential of the approach.

Source: Fraunhofer Society