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  <title><![CDATA[PhD Defense by Ethan Wold]]></title>
  <body><![CDATA[<p>In partial fulfillment of the requirements for the degree of</p><p>Doctor of Philosophy in Quantitative Biosciences<br>in the School of Biological Sciences</p><p>Ethan Wold</p><p>Defends his thesis:<br>Evolution of rapid wingbeats in insects through supra-resonant elasticity and actuation</p><p>Wednesday, April 16, 2025<br>12:00pm Eastern<br>Location: Howey Physics Building N201-202<br>Zoom: https://gatech.zoom.us/j/99358246173</p><p>Advisor:&nbsp;<br>Dr. Simon Sponberg<br>School of Physics<br>Georgia Institute of Technology</p><p>Committee:&nbsp;<br>Dr. Nicholas Gravish<br>Department of Mechanical and Aerospace Engineering<br>University of California – San Diego</p><p>Dr. Gregory Sawicki<br>Woodruff School of Mechanical Engineering<br>Georgia Institute of Technology</p><p>Dr. Saad Bhamla<br>School of Chemical and Biomolecular Engineering<br>Georgia Institute of Technology</p><p>Dr. Flavio Fenton&nbsp;<br>School of Physics<br>Georgia Institute of Technology</p><p>Abstract:<br>&nbsp; &nbsp; &nbsp;Nature’s fastest fliers, swimmers, and runners have evolved to generate and control<br>mechanical power over very short timescales to move around the world. Insects push this<br>form of locomotion to the extreme, generating wingbeats across three orders of magnitude<br>in wingbeat frequency. The presence of elasticity in the thorax of insects gives them<br>resonant mechanics, suggesting that insects may flap at their resonant frequency to fly more<br>efficiently. For fast-flapping insects like bees and flies, specialized stretch-activated flight<br>muscles self-excite to limit cycle oscillations at a frequency that is influenced by resonance.<br>However, a lack of direct, comparative studies of insect exoskeleton and muscle limits our<br>understanding of whether and how insect flight systems are broadly tuned to resonance.<br>This work explores how insect wingbeat frequencies are influenced by and emerge<br>from morphology, elasticity, and actuation. In Aim 1, we explore how the material<br>properties of insect exoskeleton behave under non-sinusoidal conditions typical of flight.<br>In Aim 2, we measured resonant properties comparatively across moths that vary in<br>wingbeat frequency, illuminating which features of the flight system change to enable<br>favorable resonant mechanics. In Aim 3, we use materials testing and a biophysical<br>model of stretch-activated muscle to show that fast-flapping insects’ wingbeat frequencies<br>are dictated by interplay between muscle and mechanical timescales. Finally, in Aim 4,<br>we develop an experimental paradigm for giving muscle novel physiological properties in<br>closed-loop called the physiological dynamic clamp. We use it to uncover the minimal<br>physiology needed to elicit transitions in flight actuation mode in real flight muscle, which<br>have enabled wingbeat frequency diversification in insects over evolutionary time.</p><p>&nbsp;</p>]]></body>
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