Several agriculturally valuable plants store their pollen in tube-like poricidal anthers, which release pollen through buzz pollination. In this process, bees rapidly vibrate the anther using their indirect flight muscles. The stiffness and resonant frequency of the anther are crucial for effective pollen release, yet the impact of turgor pressure on these properties is not well understood. Here, we perform three-point flexure tests and experimental modal analysis to determine anther transverse stiffness and resonant frequency, respectively. Dynamic nanoindentation is used to identify the anther's storage modulus as a function of excitation frequency. We subsequently develop mathematical models to estimate how turgor pressure changes after the anther is removed from a flower, thereby emulating zero water availability. We find that 30 minutes post-ablation, anther stiffness decreases by 60%. Anther resonant frequency decreases by 20% 60 minutes post-ablation. Models indicate turgor pressure in the fresh anther is about 0.2 - 0.3MPa. Our findings suggest that natural fluctuations in turgor pressure due to environmental factors like temperature and light intensity may require bees to adjust their foraging behaviors. Interestingly, anther storage modulus increased with excitation frequency, underscoring the need for more sophisticated mechanical models that consider viscous fluid transport through plant tissue.
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