Houses with and without lightning
rods are shown above. When lightning strikes
the house without a lightning rod at left the
powerful return stroke travels into the house
destroying the TV and possibly starting the house on
fire. With a
lightning rod, an upward discharge launched off the
top of the lightning rod intercepts the stepped
leader and safely carries the lightning current
through a thick wire around the house and into the
ground. Lightning rods do work
and they have changed little since their initial
development in the 1700s. Most of the
newer buildings on campus are protected with
lightning rods. If you look carefully at
the roof of Old Main, which was recently
remodeled, you'll see lightning rods.
The connection between the stepped leader and
the upward discharge creates a "short circuit" between
the charge in the cloud and the charge in the ground.
Does lightning travel upward
or downward? The answer is it does both. It starts
with a downward leader than is followed by an upward moving
return stroke.
Many cloud-to-ground flashes end at this point. In
about 50% of cloud to ground discharges, the stepped
leader-upward discharge-return stroke sequence repeats itself
(multiple times) with a few subtle differences. That's
covered below.
5. Multiple strokes flashes - dart leaders
and subsequent return strokes
A downward dart leader
travels from the cloud to the ground. The dart leader
doesn't step but travels smoothly and follows the channel
created by the stepped leader (avoiding the branches).
It is followed by a slightly less powerful subsequent return
stroke that travels back up the channel to the cloud.
This second stroke might be followed by a third, a fourth,
and so on. The subsequent return stroke channel
usually doesn't have branches.
Here's a stepped leader-upward
connecting discharge-return stroke animation
(you'll see the stepped leader, upward discharges, and
the first return stroke. Two additional
subsequent strokes are shown without the dart leader).
The sketch above and the photo below show a multiple stroke
flash consisting of 4 separate return strokes. There is enough
time between separate return strokes (around 1/20th to 1/10th
of a second) that your eye can separate the individual flashes
of light. Separate return strokes cause the flickering
you sometimes see when looking at lightning.
6. Positive (cloud-to-ground)
lightning
We've been looking at strikes that originate in the
negative charge center is a thunderstorm (discharge at left
in figure above). Occasionally a lightning
stroke will travel from the positive charge region in the
top of the thunderstorm cloud to ground (shown at right in
the figure above). These types of strikes are more
common at the ends of storms and in winter storms.
This is probably because the top part of the cloud gets
pushed sideways away from the middle and bottom portions of
the cloud. Positive strokes are very powerful.
They sometimes produce an unusually loud and long-lasting
clap of thunder.
7. Upward lightning
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A very nice picture of an upward lightning
initiated by Freedom Tower in New York City.
The photo was taken from the Empire State Building (source
of this image).
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Here's an even rarer form of lightning. Lightning
sometimes starts at the ground and travels upward.
Upward lightning is generally only initiated by mountains and
tall objects such as a skyscraper or a tower of some kind (the
Empire State Building is struck many times every year, it's
usually lightning that the building itself initiated; some
very early studies of lightning were carried out there).
Note the discharge is different in another way also.
These discharges are initiated by an upward leader. This
is not followed by a return stroke, like you might expect, but
by a more normal downward leader. Once the 2nd leader
reaches the ground, an upward return stroke travels back up
the channel to the cloud.
8. Rocket triggered lightning
The fact that lightning
could begin with an upward discharge that begins at the
ground led (French) scientists to develop a technique to
trigger lightning by firing a small rocket up toward a
thunderstorm. The rocket is connected by a thin wire
to the ground. When the rocket gets 50 to 100 m above
the ground an upward streamer will develop off of the top of
the wire. Once the streamer reaches the cloud it can
initiate a "normal" series of downward dart leaders and
upward subsequent return strokes.
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Photograph of a triggered
lightning discharge taken from a few 100 meters
away. The straight part of the channel is
where the discharge followed the wire. The
lightning channel becomes much more jagged when
traveling through air above the wire. (source
of this photo)
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A closeup of triggered lightning
striking the launch tower. The green portion
of the image at left is produced by heating and
vaporization of the copper wire used to trigger the
discharge. The brighter whiter strokes
of lightning are seen at right. They have been
spread across the picture by wind. Photo
credit: Doug Jordan and Martin Uman International
Center for Lightning Research and Testing
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Scientists are able to take closeup photographs and make
measurements of lightning currents using triggered
lightning. Triggered lightning can also be used to test
the operation of lightning protection devices.
Here's a link to
the video that was showed in class.
The abbreviation NLDN that you'll see at the start of the
video stands for National
Lightning Detection Network. The headquarters of
this company is located here in Tucson.
In the first 1:30 of the video you'll see natural lightning
occurring in the Tucson area during the summer (both
intracloud and cloud to ground discharges). Look
for the flickering that means multiple return strokes in a
flash.
Between 1:30 and about 2:00 you'll see lightning activity
photographed at the Grand Canyon. Lightning at the Grand
Canyon preferentially strikes the edges of the canyon, a
location to avoid if you're there during a thunderstorm.
Next, between about 2:00 and 2:40 photographs of lightning
striking large wind turbines in Kansas. A lightning
strike to one of the turbine blades can cause damage that is
very expensive to repair. At 2:16 and again at about
2:24 you'll see very bright lightning flashes that momentarily
overexpose the video. These were probably positive cloud
to ground discharges. And look carefully at the
discharge that occurs between about 2:28 and 2:31 on the
video. Notice the upward pointing branching. This
was an upward discharge initiated by one of the wind turbines.
Starting about 2:50 and for the remainder of the video
you'll see some rocket triggered lightning. These
experiments were done at the International Center for
Lightning Research and Testing (ICLRT) run by the University
of Florida near Gainesville, FL.
The green glow that you might have noticed in some of
the triggered lightning video probably comes from vaporization
of the copper wire that is carried upward by the rocket.
If you're someone that enjoys watching lightning storms you
may remember having seen a similar green glow when lightning
strikes the ground. I suspect this is caused by a strike
to a transformer on an electric power pole. The copper
wire in the transformer is vaporized by the lightning.
The vaporization of different chemical compounds is what gives
fireworks their distinctive colors. This
link lists some of the chemical compounds and the colors
they produce.
9. Fulgurites
When lightning strikes the ground it will often melt the
soil (especially sandy soil) and leave behind a rootlike
structure called a fulgurite. A fulgurite is just a
narrow (1/2 to 1 inch across) segment of melted sand
(glass). The photographs of fulgurites above were found
at the University
of Florida lightning triggering site.
10. Lightning safety
Lightning is a serious weather hazard. Here are some
lightning safety rules that you should keep in mind during
thundery weather.
Stay away from tall isolated objects during
a lightning storm. You can be hurt or
killed just by being close to a lightning
strike even if you're not struck
directly. Lightning currents often
travel outward along the surface of the
ground (or in water) rather than going
straight down into the ground. Just
being close to something struck by lightning
puts you at risk. When
you hear of someone being struck by
lightning and living to tell about it, it
was often a nearby rather than a direct
strike.
An
automobile with a metal roof and body provides
good protection from lightning. Many
people think this is because the tires insulate
the car from the ground. But the real
reason cars are safe is that the lightning
current will travel through the metal and around
the passengers inside. The rubber tires
really don't play any role at all. The
people in Florida in the video that were
triggering lightning with rockets were inside a
metal trailer and were perfectly safe. All
of the connections made to equipment outside the
trailer were done using fiber optics, there were
no metal wires entering or leaving the
trailer.
You shouldn't
use a corded phone or electrical appliances during
a lightning storm because lightning currents can
follow wires into your home. Cordless phones
and cell phones are safe. It is also a good
idea to stay away from plumbing as much as
possible (don't take a shower during a lightning
storm, for example). Vent pipes are
connected to the plumbing and go up to the roof of
the house which puts them in a perfect location to
be struck by lightning.
To estimate the
distance to a lightning strike count the number of
seconds between the flash of light and when you first
hear the thunder. Divide this by 5 to get the
distance in miles.
The latest lightning safety
recommendation is the 30/30 Rule.
The 30/30 rule
People should seek shelter if the delay between a lightning
flash and its thunder is 30 seconds or less
(the lightning is within 6 miles).
People should remain under cover until 30 minutes after the final
clap of thunder. The powerful positive
strokes often occur at the ends of thunderstorms.
