![]() ![]() įDTD is often used in conjunction with experimental techniques to probe how organisms’ structures produce a variety of optical effects, and the workflow is accessible to researchers from many different backgrounds.įDTD is a good choice of method for researchers who wish to simulate a naturalistic broadband light source, study complicated structures that cannot easily be analyzed through analytical optical theory alone, conduct parameter sweeps over structures of interest, and test potential bio-inspired applications. ![]() The finite-difference time-domain (FDTD) method is a powerful numerical modeling technique to study how light interacts with materials, allowing researchers to obtain reflection, transmission, diffraction, absorption, and more. ![]() Optical simulations can help explore the frontier of micro- and nano-scale biodiversity, gain insights into colorful signals and sexual selection, identify evolutionary innovations across environments, and guide the design of new technologies inspired by natural structures. Living creatures use micro- and nano-scale structures to manipulate light (e.g., for antireflection, maximal reflection, iridescent coloration, and efficient photosynthesis). ![]()
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