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1. Appearance Modeling of Iridescent Feathers with Diverse Nanostructures

   https://doi.org/10.1145/3687983  

   Yu, Yunchen; Weidlich, Andrea; Walter, Bruce; d'Eon, Eugene; Marschner, Steve (December 2024, ACM Transactions on Graphics)

   Many animals exhibit structural colors, which are often iridescent, meaning that the perceived colors change with illumination conditions and viewing perspectives. Biological iridescence is usually caused by multilayers or other periodic structures in animal tissues, which selectively reflect light of certain wavelengths and often result in a shiny appearance---which almost always comes with spatially varying highlights, thanks to randomness and irregularities in the structures. Previous models for biological iridescence tend to each target one specific structure, and most models only compute large-area averages, overlooking spatial variation in iridescent appearance. In this work, we build appearance models for biological iridescence using bird feathers as our case study, investigating different types of feathers with a variety of structural coloration mechanisms. We propose an approximate wave simulation method that takes advantage of quasi-regular structures while efficiently modeling the effects of natural structural irregularities. We further propose a method to distill our simulation results into distributions of BRDFs, generated using noise functions, that preserve relevant statistical properties of the simulated BRDFs. This allows us to model the spatially varying, glittery appearance commonly seen on feathers. Our BRDFs are practical and efficient, and we present renderings of multiple types of iridescent feathers with comparisons to photographic images. 

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2. Avian Coloration Genetics: Recent Advances and Emerging Questions

   https://doi.org/10.1093/jhered/esab015  

   Price-Waldman, Rosalyn; Stoddard, Mary Caswell (May 2021, Journal of Heredity)

   vonHoldt, Bridgett (Ed.)

   Abstract The colorful phenotypes of birds have long provided rich source material for evolutionary biologists. Avian plumage, beaks, skin, and eggs—which exhibit a stunning range of cryptic and conspicuous forms—inspired early work on adaptive coloration. More recently, avian color has fueled discoveries on the physiological, developmental, and—increasingly—genetic mechanisms responsible for phenotypic variation. The relative ease with which avian color traits can be quantified has made birds an attractive system for uncovering links between phenotype and genotype. Accordingly, the field of avian coloration genetics is burgeoning. In this review, we highlight recent advances and emerging questions associated with the genetic underpinnings of bird color. We start by describing breakthroughs related to 2 pigment classes: carotenoids that produce red, yellow, and orange in most birds and psittacofulvins that produce similar colors in parrots. We then discuss structural colors, which are produced by the interaction of light with nanoscale materials and greatly extend the plumage palette. Structural color genetics remain understudied—but this paradigm is changing. We next explore how colors that arise from interactions among pigmentary and structural mechanisms may be controlled by genes that are co-expressed or co-regulated. We also identify opportunities to investigate genes mediating within-feather micropatterning and the coloration of bare parts and eggs. We conclude by spotlighting 2 research areas—mechanistic links between color vision and color production, and speciation—that have been invigorated by genetic insights, a trend likely to continue as new genomic approaches are applied to non-model species. 

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3. Evolution of brilliant iridescent feather nanostructures

   https://doi.org/10.7554/eLife.71179  

   Nordén, Klara Katarina; Eliason, Chad M; Stoddard, Mary Caswell (December 2021, eLife)

   The brilliant iridescent plumage of birds creates some of the most stunning color displays known in the natural world. Iridescent plumage colors are produced by nanostructures in feathers and have evolved in diverse birds. The building blocks of these structures—melanosomes (melanin-filled organelles)—come in a variety of forms, yet how these different forms contribute to color production across birds remains unclear. Here, we leverage evolutionary analyses, optical simulations, and reflectance spectrophotometry to uncover general principles that govern the production of brilliant iridescence. We find that a key feature that unites all melanosome forms in brilliant iridescent structures is thin melanin layers. Birds have achieved this in multiple ways: by decreasing the size of the melanosome directly, by hollowing out the interior, or by flattening the melanosome into a platelet. The evolution of thin melanin layers unlocks color-producing possibilities, more than doubling the range of colors that can be produced with a thick melanin layer and simultaneously increasing brightness. We discuss the implications of these findings for the evolution of iridescent structures in birds and propose two evolutionary paths to brilliant iridescence. 

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4. Control of Gliding Motility and C. lytica Biofilm Iridescence via Substrate Mechanics

   https://doi.org/10.1002/adfm.202519874  

   Scutte, Annie; Katuri, Jaideep; Omeke, Samuel; Rivera‐Santiago, Nellymar; Williams, Cianna; Sullivan, Claretta; Ali, Jamel (November 2025, Advanced Functional Materials)

   Abstract Structural coloration in biological systems arises from the interaction of light with micro‐ and nanoscale structures, producing vivid, pigment‐free optical effects. While this phenomenon is well‐documented in butterflies and birds, recent reports have revealed that certain microorganisms, particularly those in theBacteroidetesphylum, also exhibit striking structural coloration when formed into biofilms. In the marine bacteriumCellulophaga lytica(C. lytica), iridescence emerges dynamically during biofilm development and is tightly coupled to gliding motility, a surface‐associated mechanism of locomotion. However, the influence of environmental mechanics on this self‐organizing photonic behavior remains poorly understood. This investegation demonstrates how substrate properties, specifically agar stiffness and salt‐modulated stress relaxation, regulate the gliding motility and emergent iridescence ofC. lyticabiofilms. Time‐lapse imaging, quantitative optical analysis, and bulk rheological measurements demonstrate that increasing agar stiffness enhances early‐stage collective motility and promotes the formation of green‐iridescent biofilms. Furthermore, salt concentration modulates the viscoelastic properties of the substrate, impacting both motility dynamics and the spatial evolution of structural color. Correlating substrate stiffness and development time with observed dominant iridescent hue enables the construction of a phase map revealing distinct regimes of photonic behavior, thus providing a framework for designing biologically‐inspired living optical systems with customizable structural colour. 

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5. Photonic paper: Multiscale assembly of reflective cellulose sheets in Lunaria annua

   https://doi.org/10.1126/sciadv.aba8966  

   Guidetti, G.; Sun, H.; Marelli, B.; Omenetto, F. G. (July 2020, Science Advances)

   null (Ed.)

   Bright, iridescent colors observed in nature are often caused by light interference within nanoscale periodic lattices, inspiring numerous strategies for coloration devoid of inorganic pigments. Here, we describe and characterize the septum of the Lunaria annua plant that generates large (multicentimeter), freestanding iridescent sheets, with distinctive silvery-white reflective appearance. This originates from the thin-film assembly of cellulose fibers in the cells of the septum that induce thin-film interference–like colors at the microscale, thus accounting for the structure’s overall silvery-white reflectance at the macroscale. These cells further assemble into two thin layers, resulting in a mechanically robust, iridescent septum, which is also significantly light due to its high air porosity (>70%) arising from the cells’ hollow-core structure. This combination of hierarchical structure comprising mechanical and optical function can inspire technological classes of devices and interfaces based on robust, light, and spectrally responsive natural substrates. 

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