Bee buzzes help keep track of decreasing population
Long-tongued bumble bee queens of Bombus balteatus visit flowers of the alpine skypilot Polemonium viscosum. These large bees have a distinctive flight buzz, the bee version of a cargo-plane flying from flower to flower. Photo courtesy of Zoe Moffett, Colorado College
“Causes of pollinator decline are complex and include diminishing flower resources, habitat loss, climate change, increased disease incidence and exposure to pesticides, so pinpointing the driving forces remains a challenge,” said Candace Galen, professor of biological science in the MU College of Arts and Science. “For more than 100 years, scientists have used sonic vibrations to monitor birds, bats, frogs and insects. We wanted to test the potential for remote monitoring programs that use acoustics to track bee flight activities.”
Bombus balteatus queen collecting nectar from the alpine clover, Trifolium parryi. The buzzes of bees flying from flower to flower tell scientists how much pollination the clover population is getting over time and predict seed production in these alpine wildflowers. Photo courtesy of Jennifer Geib, Appalachian State University
First, the team analyzed the characteristic frequencies—what musicians call the pitch—of bee buzzes in the lab. Then, they placed small microphones attached to data storage devices in the field and collected the acoustic survey data from three locations on Pennsylvania Mountain, Colorado, to estimate bumble bee activity.
Using the data, they developed algorithms that identified and quantified the number of bee buzzes in each location and compared that data to visual surveys the team made in the field. In almost every instance, the acoustic surveys were more sensitive, picking up more buzzing bees.
A research team led by Candace Galen has developed an inexpensive acoustic listening system using data from small microphones in the field to monitor bees in flight. Photo credit: Melody Kroll, Division of Biological Sciences
“Eavesdropping on the acoustic signatures of bee flights tells the story of bee activity and pollination services,” Galen said. “Farmers may be able to use the exact methods to monitor pollination of their orchards and vegetable crops and head off pollination deficits. Finally, global ‘citizen scientists’ could get involved, monitoring bees in their backyards.”
Currently, using the algorithms developed in this study, the team is developing a smartphone app that could record buzz activity as well as document the bees photographically. Future studies could determine whether bees detect competitors by sound and whether flowers have chemical responses to bee buzzes, Galen said.
Source: University of Missouri