Materially engineered artificial pollinators

Materially engineered artificial pollinators are experimental radiowave-controlled micro-drones that use ionic liquid gels for artificial pollination without living insects.[1][2][3][4][5][6][7][8]

The researchers who are developing this technology published their findings in the 9 February issue of the journal Chem[1][9] and hope that their research will help counter the problems caused by declining honeybee populations, meeting the modern agricultural demands of colonies and benefit farmers.[1]

Early history

In 2007 Eijiro Miyako, chemist at the National Institute of Advanced Industrial Science and Technology (AIST) Nanomaterial Research Institute, worked to make liquids that could be used as electrical conductors. One of his attempts generated a sticky gel, which was at the time considered a failure. After 8 years this gel was found during a lab cleanup. The researchers were astonished that it had not degraded, retaining its viscosity. Svetlana Chechetka, colleague of Miyako, notes that "conventional gels are mainly made of water and can't be used for a long time, so we decided to use this material for research". Inspired by concerns over honeybees and news reports on robotic insects, Miyako decided to investigate whether the gel could be used to pick up pollen. Miyako collected ants from near his institute, placed a droplet of the gel on some of them and let them wander around for a while in a box of tulips. The ants with the gel on them had more pollen than those without. Separate experiments with houseflies discovered a different phenomenon: the gel produces a camouflage effect, changing colour in response to various light sources, which could be used to help artificial pollinators avoid predators.[1]

Drone tests

After these early insect successes, Miyako wanted to move on to drones. He settled on a smaller model that could fly around through flower fields the way a bee does, and simulated the bee's hairy skin by using horse hair coated with the gel.[1] The team flew the 4 × 4 cm sized[2] mechanical bees over pink-leaved Japanese lilies (Lilium japonicum), letting them absorb the pollen. The drones were then flown to a second flower, where grains were deposited to artificially pollinate the plants, causing them to begin the process of generating seeds. This did not occur with control drones (without the gel and hair).[1]

Miyako states that "the findings, which will have applications for agriculture and robotics, among others, could lead to the development of artificial pollinators and help counter the problems caused by declining honeybee populations", that they "believe that robotic pollinators could be trained to learn pollination paths using global positioning systems and artificial intelligence"[1] and that the concept demonstrated "should be expandable to other research areas, including chemical composites, agriculture, biomimetic science, and robotics".[9]

See also

References

  1. "Sticky gels turn insect-sized drones into artificial pollinators". Retrieved 11 February 2017.
  2. Potenza, Alessandra (9 February 2017). "Bee optimistic: this drone can still pollinate plants even if all the bees die". The Verge. Retrieved 11 February 2017.
  3. "Robotic bee could help pollinate crops as real bees decline". New Scientist. Retrieved 11 February 2017.
  4. "Could tiny robots be the answer to the honeybee crisis?". ABC News. 10 February 2017. Retrieved 11 February 2017.
  5. Khan, Amina. "As bee populations dwindle, robot bees may pick up some of their pollination slack". Los Angeles Times. Retrieved 11 February 2017.
  6. Regalado, Antonio. "Researchers just used a drone to pollinate a flower". MIT Technology Review. Retrieved 11 February 2017.
  7. "Japanische Forscher entwickeln Bienen-Drohnen als Bestäuber" (in German). Retrieved 11 February 2017.
  8. "Sticky gels turn insect-sized drones into artificial pollinators". Retrieved 11 February 2017.
  9. Chechetka, Svetlana A.; Yu, Yue; Tange, Masayoshi; Miyako, Eijiro (February 2017). "Materially Engineered Artificial Pollinators". Chem. 2 (2): 224–239. doi:10.1016/j.chempr.2017.01.008. Retrieved 11 February 2017.
This article is issued from Wikipedia. The text is licensed under Creative Commons - Attribution - Sharealike. Additional terms may apply for the media files.