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You might tend to assume that everyone sees the world in pretty much the same way, within
the same sets of colors that we call visible light, as if we were all coloring with the
same box of crayons.
But the truth is, how many colors you can perceive actually depends on what you're working
with.
Our eyes are these amazing energy converters, taking light energy and turning it into chemical
energy and transmitting it to our brains through nerves. And within our retinas at the backs
of our eyes are receptor cells called cones and rods.
Rods allow us to see in black and white and grey, and they're still effective in dim light,
and most humans have more than one hundred and twenty million of them. Cones on the other
hand are they eye's color receptors, we only have six million of those, and they enable
us to see fine detail in well-lit conditions.
Most people have three types of cones: blue, red and green, and each receptor is triggered
by different wavelengths of light. The brain combines the signals from the three types
of receptors to produce what we perceive as color. When you put all the various combinations
from these three receptors together, most humans can see about one million colors. This
is called trichromacy.
Color-blindness usually occurs when a person is missing one of those cone receptors - almost
always either red or green. This is called dichromacy, and it reduces the ability to
distinguish between those two colors.
Interestingly, there are varying degrees of color blindness. Dichromatics can see about
ten thousand colors, but humans with monochromacy, who are missing two or all three types of
cones, only perceive about one hundred colors - mostly shades of grey.
And because the genes that affect color vision are on the X chromosome, disparities in color
vision often correspond with your sex.
Biological males only have one X chromosome, so they're more likely to inherent color blindness
- about 8% of men have some form of it. But biological females have two X chromosomes,
so for them to be affected they have to have the color blindness trait on both of their
sex chromosomes. As a result, color blindness in women is really rare, showing up less than
1% of the time.
But the X chromosome is also where scientists have recently found a genetic mutation that
may be linked to a sort of technicolor superpower.
In 2010, British scientists identified the first known Tetrachromat - a woman whose eyes
has a fourth type of cone that can register shades between red and green - basically enabling
her to perceive at least one hundred million colors.
This, too, seems to be a sex-linked trait, and other studies have suggested that as many
3% of the world's women may have this ability, in which case paint companies and crayon makers
are gonna have a lot of new names to come up with.
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