The Iridescent Glow of Certain Bird Feathers
From: Princeton University
December 21, 2021 -- The iridescent
shimmer that makes birds such as peacocks and hummingbirds so striking is
rooted in a natural nanostructure so complex that people are only just
beginning to replicate it technologically. The secret to how birds produce
these brilliant colors lies in a key feature of the feather's nanoscale design,
according to a study led by Princeton University researchers and published in
the journal eLife.
The researchers found an evolutionary
tweak in feather nanostructure that has more than doubled the range of iridescent
colors birds can display. This insight could help researchers understand how
and when brilliant iridescence first evolved in birds, as well as inspire the
engineering of new materials that can capture or manipulate light.
As iridescent birds move, nanoscale
structures within their feathers' tiny branch-like filaments -- known as
barbules -- interact with light to amplify certain wavelengths depending on the
viewing angle. This iridescence is known as structural coloration, wherein
crystal-like nanostructures manipulate light.
"If you take a single barbule from
an iridescent feather, cross-section it and put it under an electron
microscope, you'll see an ordered structure with black dots, or sometimes black
rings or platelets, within a gray substrate," said first author Klara
Nordén, a Ph.D. student in the lab of senior author Mary Caswell Stoddard,
associate professor of ecology and evolutionary biology at Princeton and
associated faculty in Princeton's High Meadows Environmental Institute (HMEI).
"The black dots are pigment-filled sacs called melanosomes, and the gray
surrounding them is feather keratin. I find these nanoscale structures just as
beautiful as the colors they produce."
Curiously, the melanosome structures
come in variety of shapes. They can be rod-shaped or platelet-shaped, solid or
hollow. Hummingbirds, for example, tend to have hollow, platelet-shaped
melanosomes, while peacocks have rod-shaped melanosomes. But why birds evolved
iridescent nanostructures with so many different types of melanosomes has been
a mystery, with scientists unsure if some melanosome types are better than
others at producing a broad range of vibrant colors.
To answer this question, the researchers
combined evolutionary analysis, optical modeling and plumage measurements --
all of which allowed them to uncover general design principles behind
iridescent feather nanostructures.
Nordén and Stoddard worked with
co-author Chad Eliason, a postdoctoral fellow at The Field Museum, to first
survey the literature and compile a database of all described iridescent
feather nanostructures in birds, which included more than 300 species. They
then used a family tree of birds to illustrate which groups evolved the
different melanosome types.
There are five primary types of
melanosomes in iridescent feather nanostructures: thick rods, thin rods, hollow
rods, platelets and hollow platelets. Except for thick rods, all of these
melanosome types are found in brilliantly colored plumage. Because the
ancestral melanosome type is rod-shaped, previous work focused on the two
obvious features unique to iridescent structures: platelet shape and hollow
interior.
However, when the researchers evaluated
the results of their survey, they realized that there was a third melanosome
feature that has been overlooked -- thin melanin layers. All four melanosome
types in iridescent feathers -- thin rods, hollow rods, platelets and hollow
platelets -- create thin melanin layers, much thinner than a structure built
with thick rods. This is important because the size of the layers in the structures
is key to producing vibrant colors, Nordén said.
"Theory predicts that there is a
kind of Goldilocks zone in which the melanin layers are just the right
thickness to produce really intense colors in the bird-visible spectrum,"
she said. "We suspected that thin rods, platelets or hollow forms may be
alternative ways to reach that ideal thickness from the much larger ancestral
melanosome size -- the thick rods."
The researchers tested their idea on
bird specimens at the American Museum of Natural History in New York City by
measuring the color of iridescent bird plumage that results from nanostructures
with different melanosome types. They also used optical modeling to simulate
the colors that would be possible to produce with different types of melanosomes.
From these data, they determined which feature -- thin melanin layers, platelet
shape or hollowness -- has the greatest influence on the range and intensity of
color. Combining the results of the optical modeling and plumage analyses, the
researchers determined that thin melanin layers -- no matter the shape of the
melanosomes -- nearly doubled the range of colors an iridescent feather could
produce.
"This key evolutionary breakthrough
-- that melanosomes could be arranged in thin melanin layers -- unlocked new
color-producing possibilities for birds," Stoddard said. "The diverse
melanosome types are like a flexible nanostructural toolkit, offering different
routes to the same end: brilliant iridescent colors produced by thin melanin layers."
This may explain why there exists such a
great diversity of melanosome types in iridescent nanostructures. Iridescent
nanostructures likely evolved many times in different groups of birds, but, by
chance, thin melanin layers evolved from a thick rod in different ways. Some
groups evolved thin melanin layers by flattening the melanosomes (producing
platelets), others by hollowing out the interior of the melanosome (producing
hollow forms), and yet others by shrinking the size of the rod (producing thin
rods).
The findings of the study could be used
to reconstruct brilliant iridescence in prehistoric animals, Nordén said.
Melanosomes can be preserved in fossil feathers for millions of years, which
means that paleontologists can infer original feather color -- even iridescence
-- in birds and dinosaurs by measuring the size of fossilized melanosomes.
"Based on the thick solid rods that
have been described in the plumage of Microraptor, for example, we
can say that this feathered theropod likely had iridescent plumage much more
like that of a starling than that of a peacock," Nordén said.
The composition of melanosomes and
keratin in bird feathers could hold clues for engineering advanced iridescent
nanostructures that can efficiently capture or manipulate light, or be used to
produce eco-friendly paints that do not require dyes or pigments. Super-black
coatings such as Vantablack similarly use nanostructures that absorb and
disperse rather than reflect light, similar to the black plumage of species in
the birds-of-paradise (Paradisaeidae) family.
Iridescent feathers also could lead to a
richer understanding of multifunctional materials, Nordén said. Unlike
human-made materials, which are often developed for a single function, natural
materials are inherently multipurpose. Melanin not only helps produce
iridescence; it also protects birds from dangerous ultraviolet radiation,
strengthens feathers and inhibits microbial growth.
"What if the different types of
melanosomes initially evolved for some reason unrelated to the iridescent color
-- such as for making the feather mechanically stronger, or more resistant to
microbial attack," Nordén said. "These are some of the questions we
are excited to tackle next."
https://www.sciencedaily.com/releases/2021/12/211221133545.htm
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