Open AccessSurpassing Mt. Everest: extreme flight performance of alpine bumble-bees
Author(s) -
Michael E. Dillon,
Robert Dudley
Publication year - 2014
Publication title -
biology letters
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.596
H-Index - 110
eISSN - 1744-957X
pISSN - 1744-9561
DOI - 10.1098/rsbl.2013.0922
Subject(s) - foraging , biology , altitude (triangle) , insect flight , effects of high altitude on humans , ecology , aerodynamics , lift (data mining) , atmospheric sciences , aeronautics , aerospace engineering , computer science , physics , anatomy , engineering , geometry , mathematics , data mining
Animal flight at altitude involves substantial aerodynamic and physiological challenges. Hovering at high elevations is particularly demanding from the dual perspectives of lift and power output; nevertheless, some volant insects reside and fly at elevations in excess of 4000 m. Here, we demonstrate that alpine bumble-bees possess substantial aerodynamic reserves, and can sustain hovering flight under hypobaria at effective elevations in excess of 9000 m, i.e. higher than Mt. Everest. Modulation of stroke amplitude and not wingbeat frequency is the primary means of compensation for overcoming the aerodynamic challenge. The presence of such excess capacity in a high-altitude bumble-bee is surprising and suggests intermittent behavioural demands for extreme flight performance supplemental to routine foraging.
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