The science of static electricity Anuradha Bhagwat
It can strike without warning,
at any moment.
You may be walking across a soft carpet
and reaching for the door knob
when suddenly…zap!
To understand static electricity,
we first need to know a bit
about the nature of matter.
All matter is made up of atoms
that consist of three
types of smaller particles:
negatively charged electrons,
positively charged protons,
and neutral neutrons.
Normally, the electrons and protons
in an atom balance out,
which is why most matter you come across
is electrically neutral.
But electrons are tiny
and almost insignificant in mass,
and rubbing or friction can give
loosely bound electrons
enough energy to leave their atoms
and attach to others,
migrating between different surfaces.
When this happens,
the first object is left
with more protons than electrons
and becomes positively charged,
while the one with more electrons
accumulates a negative charge.
This situation is called
a charge imbalance,
or net charge separation.
But nature tends towards balance,
so when one of these newly charged bodies
comes into contact with another material,
the mobile electrons
will take the first chance they get
to go where they’re most needed,
either jumping off the negatively
charged object,
or jumping onto
the positively charged one
in an attempt to restore
the neutral charge equilibrium.
And this quick movement of electrons,
called static discharge,
is what we recognize as that sudden spark.
This process doesn’t happen
with just any objects.
Otherwise you’d be getting
zapped all the time.
Conductors like metals and salt water
tend to have loosely
bound outer electrons,
which can easily flow between molecules.
On the other hand, insulators
like plastics, rubber and glass
have tightly bound electrons
that won’t readily jump to other atoms.
Static build-up is most likely to occur
when one of the materials involved
is an insulator.
When you walk across a rug,
electrons from your body
will rub off onto it,
while the rug’s insulating wool
will resist losing its own electrons.
Although your body and the rug
together are still electrically neutral,
there is now a charge polarization
between the two.
And when you reach to touch the door knob,
zap!
The metal door knob’s loosely
bound electrons hop to your hand
to replace the electrons
your body has lost.
When it happens in your bedroom,
it’s a minor nuisance.
But in the great outdoors,
static electricity can be a terrifying,
destructive force of nature.
In certain conditions,
charge separation will occur in clouds.
We don’t know exactly how this happens.
It may have to do with the circulation
of water droplets
and ice particles within them.
Regardless, the charge
imbalance is neutralized
by being released towards another body,
such as a building,
the Earth,
or another cloud in a giant spark
that we know as lightning.
And just as your fingers can be zapped
over and over in the same spot,
you better believe that lightning
can strike the same place more than once.