Photochemical Turbo Power for Solar Cells

Red light from a laser pointer is converted into higher-energy yellow<br />light as it passes through the liquid photochemical upconverter.<br />Source: University of Sydney, Australia

Red light from a laser pointer is converted into higher-energy yellow
light as it passes through the liquid photochemical upconverter.
Source: University of Sydney, Australia

How organic molecules make yellow light from red.

They have developed a kind of “turbo for solar cells”, called photochemical upconversion: Two energy-poor photons that would normally be ineffective in the solar cell are merged into one energy-rich photon, which can then contribute towards the electricity yield. Further research in this direction may make it possible to exceed the 30 percent mark. The team has published its results in the journal “Energy & Environmental Science” (DOI: 10.1039/C2EE21136J).

The photochemical solar-cell turbo uses organic molecules to merge energy-poor red photons together into energy-richer yellow photons. The secret is in the choice of molecules, of which two different types are placed behind the solar cell in solution. The task of the first molecule type is to absorb the energy-poor light particles and to store their energy. The crux here is that these molecules enter a persistent state in which the spins, or magnetic moments, of the light-excited electrons in each molecule line up in parallel. This prevents re-emission of the absorbed particles.

This persistent state of the first molecule type lasts long enough for the energy to be transferred into a persistent state of a second type of organic molecule. This energy transfer takes place when the two types of molecule encounter each other in the solution. If two excited molecules of the second type then encounter each other, then one of them returns to its base state. The other thereupon assumes an even higher energy state, which is extremely short-lived. This latter molecule then sends off a single photon of high enough energy to be absorbed by the solar cell.

“We are thus the first to demonstrate an efficiency gain in a solar cell by photochemical upconversion,” says project head Dr. Klaus Lips of the HZB Institute for Silicon Photovoltaics. “The achieved increase in solar cell efficiency is still low – about 0.1 percent absolute – and the sunlight even had to be concentrated fifty times, but the path to further improvement is clearly discernible.” Yet it is rocky and hard, as Lips emphasizes: “For the concept study now published, we had not used a 25 percent high-capacity solar cell yet, as will be needed for later practical application.” They now have to redevelop the organic molecules of the photochemical upconverter so that they do not have to be dissolved in a liquid. They will also have to perform their action under normal, unconcentrated sunlight, and an infrared converter will be required for crystalline silicon.

“The concepts for this were developed in close cooperation between Sydney and HZB,” says Klaus Lips. The essential advantage of this ‘3rd generation photovoltaics’ over other approaches is there is no need for costly redevelopment of solar cells; rather, merely adding the upconverter would in principle suffice to boost the efficiency. Klaus Lips concludes: “Just as you would build a turbo into a car to make it go faster – and wouldn’t necessarily go and design an entirely new car.”

Further Information:

Timothy Schmidt
School of Chemistry
University of Sydney, Australia
Tel.: +61 (439) 386109
t.schmidt@chem.usyd.edu.au

HS

  • Copy link

You might also be interested in

  • Battery research with the HZB X-ray microscope
    Science Highlight
    18.11.2024
    Battery research with the HZB X-ray microscope
    New cathode materials are being developed to further increase the capacity of lithium batteries. Multilayer lithium-rich transition metal oxides (LRTMOs) offer particularly high energy density. However, their capacity decreases with each charging cycle due to structural and chemical changes. Using X-ray methods at BESSY II, teams from several Chinese research institutions have now investigated these changes for the first time with highest precision: at the unique X-ray microscope, they were able to observe morphological and structural developments on the nanometre scale and also clarify chemical changes.
  • BESSY II: New procedure for better thermoplastics
    Science Highlight
    04.11.2024
    BESSY II: New procedure for better thermoplastics
    Bio-based thermoplastics are produced from renewable organic materials and can be recycled after use. Their resilience can be improved by blending bio-based thermoplastics with other thermoplastics. However, the interface between the materials in these blends sometimes requires enhancement to achieve optimal properties. A team from the Eindhoven University of Technology in the Netherlands has now investigated at BESSY II how a new process enables thermoplastic blends with a high interfacial strength to be made from two base materials: Images taken at the new nano station of the IRIS beamline showed that nanocrystalline layers form during the process, which increase material performance.
  • Hydrogen: Breakthrough in alkaline membrane electrolysers
    Science Highlight
    28.10.2024
    Hydrogen: Breakthrough in alkaline membrane electrolysers
    A team from the Technical University of Berlin, HZB, IMTEK (University of Freiburg) and Siemens Energy has developed a highly efficient alkaline membrane electrolyser that approaches the performance of established PEM electrolysers. What makes this achievement remarkable is the use of inexpensive nickel compounds for the anode catalyst, replacing costly and rare iridium. At BESSY II, the team was able to elucidate the catalytic processes in detail using operando measurements, and a theory team (USA, Singapore) provided a consistent molecular description. In Freiburg, prototype cells were built using a new coating process and tested in operation. The results have been published in the prestigious journal Nature Catalysis.