Modeling Floral and Arthropod Electrostatics Using a Two-Domain AAA-Least Squares Algorithm

Relationships between plants and insects vitally underpin the health of global ecosystems and food production. Through coevolution, insects have acquired a variety of senses in response to the emergence of floral cues such as scent, color, and shape. Therefore, the recent discovery of electroreception among terrestrial arthropods motivates the investigation of floral electrics as part of their wider sensory ecology. We examine how a flower’s morphology and material properties produce and propagate detectable, ecologically relevant electrical signals in several biologically inspired scenarios. Since the electrical field both interior and exterior to the flower must be solved for, we develop an extension of the two-dimensional AAA-least squares algorithm for solving such two-domain electrostatics problems. It is found that the electrical signals produced by the plant can reveal information to the insect about the flower shape, available pollen, and the presence of other nearby arthropods. These results show good qualitative agreement with an equivalent three-dimensional scenario, computed using finite element methods. The extension of the AAA-least squares algorithm to two-domain problems provides a fast and accurate method for modeling electrostatic problems, with possible further application in fluid dynamics and magnetostatics. Biologically, our results highlight the significant role floral electrics may play in plant-pollinator and predator-prey relationships, unveiling previously unstudied facets of these key relationships.