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Every color you see in front
of you can be found in nature.
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Some plant, animal, or mineral
bears almost every hue imaginable.
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But which of these colors are you
least likely to see in the natural world?
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There are two factors that drive
the rarity of color in nature:
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physics and evolution.
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Let’s start with physics.
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Colors are generated when wavelengths
of light interact with objects,
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and most of the colors
you’ve seen outside a screen
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were produced in one of two ways.
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In absorption-based colors,
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certain wavelengths are absorbed
by an object, while others are not.
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The result is a matte final color
generated by these leftover light waves.
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Most naturally occurring colors
fall into this category,
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including those of many fruits
and flowers.
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Plants are full of compounds called
pigments that absorb light waves
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as part of photosynthesis,
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the process by which
they convert sunlight into energy.
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While different plants have evolved
different pigments
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that result in different colors,
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higher energy wavelengths are more easily
absorbed than lower energy ones.
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And blue light has some
of the highest energy wavelengths
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in the visible spectrum.
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Numerous pigments have evolved
to absorb blue light,
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including chlorophyll, which absorbs blue
and red wavelengths
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to produce nature’s trademark green.
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However, green light is still
fairly energetic,
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and the most common class of pigments
evolved to absorb these wavelengths
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as well.
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There are over 1,100 types
of carotenoids,
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pigments which absorb high energy
blue and green light,
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while leaving behind the lower energy
red and yellow light.
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While carotenoids are present
in most green plants,
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they only become visible each fall
when chlorophyll gets broken down
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to save energy for the winter.
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But whether they’re working alone
or side by side,
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these pigments absorb
blue light in virtually all plants.
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Even fruits and flowers that appear blue
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actually have pigments
that are red or purple,
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and only truly turn blue
under specific chemical conditions.
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So, is blue the rarest color
in nature?
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Not quite.
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Absorption is just one of the two
main ways light generates color.
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In the second method, some wavelengths
are scattered and amplified—
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overpowering the others to determine
an object's final color.
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These structural colors occur
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because some objects around us are made
of microscopic particles
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which can form nanostructures
that interfere with visible light.
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For example, this feather has
no blue pigments in it.
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But when light strikes it,
the electrons within its nanostructure
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vibrate at the same frequency
as the weight.
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This makes the particles send
out a new wave with the same frequency,
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starting a chain reaction that amplifies
and scatters blue light.
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Nanostructures of various shapes and sizes
scatter different wavelengths,
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but they typically scatter high-energy
wavelengths most easily—
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making blue
the most common structural color.
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Meanwhile, low-energy wavelengths
like red are only weakly scattered.
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Even when something evolves
specific nanostructures
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that strongly scatter red light
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they still resonate
with other wavelengths,
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only appearing red at some angles
of illumination and observation.
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This gives us two contenders
for nature’s rarest color:
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absorption-based matte blues
and structural iridescent reds.
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Between these two,
structural reds are much rarer.
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Only a handful of animals and rocks
scatter red light
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and none of them scatter
red light exclusively.
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But since red and blue are rare
in one way and common in another,
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we actually end up seeing
both colors quite often.
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So what color is least likely
to be generated
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in structural and absorption-based forms?
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The answer is violet.
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Not to be confused with purple, which is
just a combination of red and blue light,
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violet occupies a small portion
of the visible light spectrum.
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There are only a few nanostructures
precise enough
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to exclusively scatter violet light.
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And violet wavelengths are even
more energetic than blue ones,
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making them likely to be absorbed
by pigment.
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So if you ever stumble
onto the iridescent violet wings
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of a purple emperor butterfly,
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take a second to appreciate
one of nature’s rarest spectacles.
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