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In 1800, the explorer
Alexander von Humboldt
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witnessed a swarm of electric eels
leap out of the water
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to defend themselves
against oncoming horses.
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Most people thought the story
so unusual that Humboldt made it up.
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But fish using electricity is more common
than you might think;
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and yes, electric eels are a type of fish.
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Underwater, where light is scarce,
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electrical signals offer ways
to communicate,
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navigate,
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and find—plus in rare cases stun-- prey.
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Nearly 350 species of fish
have specialized anatomical structures
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that generate
and detect electrical signals.
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These fish are divided into two groups,
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depending on how much
electricity they produce.
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Scientists call the first group
the weakly electric fish.
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Structures near their tails
called electric organs
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produce up to a volt of electricity,
about two-thirds as much as a AA battery.
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How does this work?
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The fish's brain sends a signal through
its nervous system to the electric organ,
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which is filled with stacks of hundreds
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or thousands of disc-shaped
cells called electrocytes.
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Normally, electrocytes pump out sodium
and potassium ions
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to maintain a positive charge outside
and negative charge inside.
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But when the nerve signal arrives
at the electrocyte,
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it prompts the ion gates to open.
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Positively charged ions flow back in.
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Now, one face of the electrocyte
is negatively charged outside
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and positively charged inside.
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But the far side
has the opposite charge pattern.
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These alternating charges
can drive a current,
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turning the electrocyte
into a biological battery.
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The key to these fish's powers
is that nerve signals are coordinated
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to arrive at each cell
at exactly the same time.
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That makes the stacks of electrocytes
act like thousands of batteries in series.
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The tiny charges from each one
add up to an electrical field
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that can travel several meters.
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Cells called electroreceptors
buried in the skin
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allow the fish to constantly sense
this field
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and the changes to it caused
by the surroundings or other fish.
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The Peter’s elephantnose fish,
for example,
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has an elongated chin
called a schnauzenorgan
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that's riddled in electroreceptors.
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That allows it to intercept signals
from other fish,
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judge distances,
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detect the shape and size
of nearby objects,
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and even determine whether
a buried insect is dead or alive.
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But the elephantnose
and other weakly electric fish
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don't produce enough electricity
to attack their prey.
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That ability belongs
to the strongly electric fish,
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of which there are only
a handful of species.
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The most powerful strongly electric
fish is the electric knife fish,
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more commonly known as the electric eel.
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Three electric organs span
almost its entire two-meter body.
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Like the weakly electric fish,
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the electric eel uses its signals
to navigate and communicate,
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but it reserves its strongest
electric discharges for hunting
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using a two-phased attack that susses out
and then incapacitates its prey.
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First, it emits two
or three strong pulses,
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as much as 600 volts.
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These stimulate the prey's muscles,
sending it into spasms
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and generating waves
that reveal its hiding place.
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Then, a volley of fast,
high-voltage discharges
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causes even more intense
muscle contractions.
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The electric eel can also curl up
so that the electric fields
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generated at each end
of the electric organ overlap.
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The electrical storm eventually
exhausts and immobilizes the prey,
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and the electric eel
can swallow its meal alive.
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The other two strongly electric fish
are the electric catfish,
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which can unleash 350 volts
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with an electric organ
that occupies most of its torso,
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and the electric ray, with kidney-shaped
electric organs on either side of its head
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that produce as much as 220 volts.
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There is one mystery in the world
of electric fish:
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why don't they electrocute themselves?
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It may be that the size
of strongly electric fish
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allows them to withstand their own shocks,
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or that the current passes out
of their bodies too quickly.
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Some scientists think that special
proteins may shield the electric organs,
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but the truth is, this is one mystery
science still hasn't illuminated.
closed TED
