Iridescent flowers? Contribution of surface structures to optical signaling

The color of natural objects depends on how they are structured and pigmented. In flowers, both the surface structure of the petals and the pigments they contain determine coloration. The aim of the present study was to assess the contribution of structural coloration, including iridescence, to over...

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Bibliographic Details
Published in:The New phytologist 2014-07, Vol.203 (2), p.667-673
Main Authors: Kooi, Casper J, Wilts, Bodo D, Leertouwer, Hein L, Staal, Marten, Elzenga, J. Theo M, Stavenga, Doekele G
Format: Article
Language:English
Subjects:
Angiosperms
Backscattering
color
Color vision
Coloration
Colors
Colour
Cones
corolla
Diffraction patterns
Flat surfaces
Flowers
Flowers - anatomy & histology
Flowers - physiology
Flowers - ultrastructure
Hibiscus - anatomy & histology
Hibiscus - physiology
image analysis
Iridescence
Light
lighting
Ligules
Magnoliophyta
Matricaria - anatomy & histology
Matricaria - physiology
Microscopy, Electron, Scanning
Optical communication
Optical reflection
petal striations
Petals
Pigmentation
Pigments
Plant species
Plants
plant–pollinator signaling
Pollination
Pollinators
reflection
Scatterometers
scatterometry
Signal reflection
Signal Transduction
Signaling
Spectral reflectance
Striations
Surface Properties
Surface structure
Surveying
surveys
Ultraviolet reflection
Vacuoles
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Summary:The color of natural objects depends on how they are structured and pigmented. In flowers, both the surface structure of the petals and the pigments they contain determine coloration. The aim of the present study was to assess the contribution of structural coloration, including iridescence, to overall floral coloration. We studied the reflection characteristics of flower petals of various plant species with an imaging scatterometer, which allows direct visualization of the angle dependence of the reflected light in the hemisphere above the petal. To separate the light reflected by the flower surface from the light backscattered by the components inside (e.g. the vacuoles), we also investigated surface casts. A survey among angiosperms revealed three different types of floral surface structure, each with distinct reflections. Petals with a smooth and very flat surface had mirror‐like reflections and petal surfaces with cones yielded diffuse reflections. Petals with striations yielded diffraction patterns when single cells were illuminated. The iridescent signal, however, vanished when illumination similar to that found in natural conditions was applied. Pigmentary rather than structural coloration determines the optical appearance of flowers. Therefore, the hypothesized signaling by flowers with striated surfaces to attract potential pollinators presently seems untenable.
ISSN:0028-646X
1469-8137
DOI:10.1111/nph.12808