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It's midnight and all is still,
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except for the soft skittering
of a gecko hunting a spider.
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Geckos seem to defy gravity,
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scaling vertical surfaces
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and walking upside down
without claws,
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adhesive glues or super-powered spiderwebs.
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Instead, they take advantage
of a simple principle:
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that positive
and negative charges attract.
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That attraction binds together
compounds, like table salt,
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which is made of positively
charged sodium ions
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stuck to negatively charged chloride ions.
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But a gecko's feet aren't charged
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and neither are the surfaces
they're walking on.
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So, what makes them stick?
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The answer lies in a clever combination
of intermolecular forces
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and stuctural engineering.
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All the elements in the periodic table
have a different affinity for electrons.
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Elements like oxygen and fluorine
really, really want electrons,
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while elements like hydrogen and lithium
don't attract them as strongly.
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An atom's relative greed for electrons
is called its electronegativity.
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Electrons are moving around all the time
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and can easily relocate
to wherever they're wanted most.
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So when there are atoms with different
electronegativities in the same molecule,
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the molecules cloud of electrons
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gets pulled towards
the more electronegative atom.
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That creates a thin spot
in the electron cloud
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where positive charge
from the atomic nuclei shines through,
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as well as a negatively charged
lump of electrons somewhere else.
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So the molecule itself isn't charged,
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but it does have positively
and negatively charged patches.
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These patchy charges can attract
neighboring molecules to each other.
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They'll line up so that
the positive spots on one
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are next to the negative
spots on the other.
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There doesn't even have to be a strongly
electronegative atom
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to create these attractive forces.
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Electrons are always on the move,
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and sometimes they pile up
temporarily in one spot.
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That flicker of charge is enough
to attract molecules to each other.
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Such interactions between
uncharged molecules
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are called van der Waals forces.
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They're not as strong as the interactions
between charged particles,
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but if you have enough of them,
they can really add up.
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That's the gecko's secret.
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Gecko toes are padded
with flexible ridges.
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Those ridges are covered
in tiny hair-like structures,
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much thinner than human hair,
called setae.
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And each of the setae is covered
in even tinier bristles called spatulae.
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Their tiny spatula-like shape is perfect
for what the gecko needs them to do:
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stick and release on command.
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When the gecko unfurls its flexible toes
onto the ceiling,
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the spatulae hit at the perfect angle
for the van der Waals force to engage.
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The spatulae flatten,
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creating lots of surface area
for their positively
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and negatively charged patches to find
complimentary patches on the ceiling.
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Each spatula only contributes a minuscule
amount of that van der Waals stickiness.
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But a gecko has about two billion of them,
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creating enough combined force
to support its weight.
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In fact, the whole gecko could dangle
from a single one of its toes.
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That super stickiness
can be broken, though,
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by changing the angle just a little bit.
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So, the gecko can peel its foot back off,
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scurrying towards a meal
or away from a predator.
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This strategy, using a forest
of specially shaped bristles
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to maximize the van der Waals forces
between ordinary molecules
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has inspired man-made materials
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designed to imitate
the gecko's amazing adhesive ability.
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Artificial versions aren't as strong
as gecko toes quite yet,
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but they're good enough to allow
a full-grown man
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to climb 25 feet up a glass wall.
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In fact, our gecko's prey is also using
van der Waals forces
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to stick to the ceiling.
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So, the gecko peels up its toes
and the chase is back on.
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