Quantcast

Is the hornet our key to renewable energy?

As every middle-school child knows, in the process of photosynthesis, plants take the sun’s energy and convert it to electrical energy. Now a Tel Aviv University team has demonstrated how a member of the animal kingdom, the Oriental hornet, takes the sun’s energy and converts it into electric power — in the brown and yellow parts of its body — as well.

“The interesting thing here is that a living biological creature does a thing like that,” says physicist Prof. David Bergman of Tel Aviv University’s School of Physics and Astronomy, who was part of the team that made discovery. “The hornet may have discovered things we do not yet know.” In partnership with the late Prof. Jacob Ishay of the university’s Sackler Faculty of Medicine, Prof. Bergman and his doctoral candidate Marian Plotkin engaged in a truly interdisciplinary research project to explain the biological processes that turn a hornet’s abdomen into solar cells.

The research team made the discovery several years ago, and recently tried to mimic it. The results show that the hornet’s body shell, or exoskeleton, is able to harvest solar energy. They were recently published in the German journal Naturwissenschaften.

Discovering a new system for renewable energy?

Previously, entomologists noted that Oriental wasps, unlike other wasps and bees, are active in the afternoon rather than the morning when the sun is just rising. They also noticed that the hornet digs more intensely as the sun’s intensity increases.

Taking this information to the lab, the Tel Aviv University team studied weather conditions like temperature, humidity and solar radiation to determine if and how these factors also affected the hornet’s behavior, but found that UVB radiation alone dictated the change.

In the course of their research, the Tel Aviv University team also found that the yellow and brown stripes on the hornet abdomen enable a photo-voltaic effect: the brown and yellow stripes on the hornet abdomen can absorb solar radiation, and the yellow pigment transforms that into electric power.

The team determined that the brown shell of the hornet was made from grooves that split light into diverging beams. The yellow stripe on the abdomen is made from pinhole depressions, and contains a pigment called xanthopterin. Together, the light diverging grooves, pinhole depressions and xanthopterin change light into electrical energy. The shell traps the light and the pigment does the conversion.

A biological heat pump

The researchers also found a number of energy processes unique to the insect. Like air conditioners and refrigerators, the hornet has a well-developed heat pump system in its body which keeps it cooler than the outside temperature while it forages in the sun. This is something that’s not easy to do, says Prof. Bergman.

To see if the solar collecting prowess of the hornet could be duplicated, the team imitated the structure of the hornet’s body but had poor results in achieving the same high efficiency rates of energy collection. In the future, they plan to refine the model to see if this “bio-mimicry” can give clues to novel renewable energy solutions.

The research team also discovered that hornets use finely honed acoustic signals to guide them so they can build their combs with extraordinary precision in total darkness. Bees can at least see what they are doing, explains Prof. Bergman, but hornets cannot — it’s totally dark inside a hornet nest.

American Friends of Tel Aviv University (www.aftau.org) supports Israel’s leading, most comprehensive and most sought-after center of higher learning. Independently ranked 94th among the world’s top universities for the impact of its research, TAU’s innovations and discoveries are cited more often by the global scientific community than all but 10 other universities.

Internationally recognized for the scope and groundbreaking nature of its research and scholarship, Tel Aviv University consistently produces work with profound implications for the future.




The material in this press release comes from the originating research organization. Content may be edited for style and length. Want more? Sign up for our daily email.