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BY JONATHAN ATTEBERRY
Imagine taking
all of the water from your neighborhood swimming pool, pouring it into a
massive, magma-powered pressure cooker and shooting the water
hundreds of feet in the air.
 |
Old Faithful may be the
world's most well-known geyser.
|
Yet, despite
the unbelievable forces that drive their eruptions, geysers are among the
rarest and most fragile natural phenomena on Earth.
Landslides, earthquakes and many other factors
can alter a geyser's eruptions or destroy the geyser altogether.
What's more,
nature isn't the only thing that can impact a geyser: Man has helped to destroy
numerous geysers as well, sometimes unintentionally and sometimes through
deliberate acts of vandalism.
As of 2009,
there are only about a thousand geysers left active on the planet, in geyser
fields in such diverse locales as Iceland, New Zealand, Chile and the U.S.
The one thing
all of these locations have in common with one another is a high level of geothermal
activity, one of the key components of geyser formations.
Geothermal
energy, which is taken from heat within the Earth, drives volcanoes,
hot springs and other forms of geothermal activity.
Still, a
geothermal energy source is just one necessary part of a typical geyser
formation.
In this
article, we'll explore what else it takes to form a geyser, what exactly causes
one to erupt and what makes some geysers so unique.
Along the way,
we'll also take a look at some springs that look and act like geysers, but
operate in a completely different way.
How Geysers Form and Erupt
We'll examine
each of these separately and then explore how they work together to cause
geysers to erupt.
· Water supply: Clearly, a geyser needs a
water supply. What might not be so apparent, however, is where the water in a
geyser's eruption comes from.
The answer
depends on the geyser. Many geysers are located near rivers and pull water from
them.
Others seem to
depend more on rain and snow filtering miles beneath the ground for their water
supply.
· Plumbing system: A geyser's plumbing system
is a series of fissures in the Earth that start at the geyser's mouth and run
miles beneath the Earth's surface, where the system
connects to the geyser's heat source.
Each geyser's
plumbing system is different: Some consist of a single long, vertical shaft,
while others connect to large pockets of water beneath the surface.
Certain types
of soil are much more suitable for the plumbing system's formation,
particularly soils that contain a high concentration of rhyolite, a
volcanic rock that contains minerals that seal the geyser's plumbing system.
This mineral
lining is crucial to the geyser's formation, as geysers operate under
tremendous pressure and the plumbing system must be able to contain this
pressure for the geyser to function.
· Heat source: We already know that
geysers occur in areas of high geothermal activity, but where does that energy
come from?
The water in
geysers is heated by magma that lies around 3 miles (4.8 kilometers) beneath
the surface of the Earth.
While that
might seem like a long way down, magma underneath a geyser field is actually
relatively close to the Earth's surface.
There are
different reasons why the magma is so close to the Earth's surface, though many
geyser fields are located on the edges of the Earth's tectonic plates.
These plates,
which compose the Earth's lithosphere, are constantly in motion, creating
faults and generating tremendous energy.
This activity
can cause earthquakes and volcanoes, and it can also create heat sources for
geysers.
In the next
section, we'll learn why the boiling point of water is so critical to
understanding how a geyser erupts.
How Do Geysers Erupt?
Now that we
understand how the key components of a geyser work, let's figure out how these
parts work together to create such spectacular eruptions.
Since the
plumbing system is miles deep, the water at the bottom of the geyser's
plumbing is under incredible pressure from the water above it. Think of the
entire system as a giant pressure cooker.
Pressure
cookers work by creating a sealed, pressurized enclosure that helps to cook
food much faster than cooking it in a normal pot.
Pressure
cookers can do this because water's boiling point rises as it's pressurized.
Think of what actually happens when water boils: Water starts to churn and
bubbles of air begin to surface.
If more
pressure pushes down on the water, water needs more and more energy (in the
form of heat) to overcome that pressure and start pushing bubbles to the
surface.
This explains
why water inside a pressure cooker can reach temperatures of more than 125
degrees Celsius (257 degrees Fahrenheit), while the boiling point of water at
standard pressure is only 100 degrees Celsius (212 degrees Fahrenheit).
Now consider
the massive pressures placed on water within a geyser's plumbing system.
Water in such
a system can reach incredibly high temperatures (and store incredible amounts
of energy as a result) before it starts to boil.
As the magma
at the base of the geyser transfers heat throughout the system, more energy
gets trapped in the water. Eventually, pockets of water begin to reach their
boiling point and become turbulent.
This
turbulence pushes a relatively small quantity of water out of the opening of
the geyser, decreasing the amount of pressure on the water remaining in the
geyser.
With this
sudden pressure drop (and corresponding drop in boiling point), the water in
the geyser flashes into steam.
These
eruptions last as long as the water in the geyser remains hot enough to push
water out of the geyser opening.
Eventually,
the entire system will either run out of water or the water will cool down
enough for the eruption to stop. The cycle, of course, starts all over again.
COLD GEYSERS
While most
geysers are hot enough to scald you, so-called cold-water geysers are
a different story.
These geysers,
such as Crystal Geyser in Utah and Brubbel Geyser in Germany, are driven by
carbon dioxide-rich water trapped beneath the surface of the Earth.
Similar to how
heat-driven geysers work, when pressure on a cold-water geyser decreases, the
carbon dioxide bubbles in the water expand and push water out of the geyser in
an eruption.
Exploring the World's Most Famous Geysers
While every
geyser operates in fundamentally the same way, all geysers are not created
equal. In this section, we'll explore some of the world's most famous geysers
and what makes them stand out above the rest.
· Geysir: This geyser, located in
Iceland's Haukadalur valley, was first discovered in 1294, making the Geysir
the oldest known geyser on the planet. Geysir's activity slowed toward the end
of the 19th century and it became dormant around 1915.
In 1935,
however, an earthquake reactivated the geyser, which currently erupts about
every eight to 10 hours. Geysir remains a major tourist attraction to this day.
· Old Faithful: Probably the most famous
geyser on Earth, Old Faithful is famous for its 100- to
180-foot (30 to 55 meter) high eruptions, as well as for the regularity with
which these eruptions occur (hence the name).
The geyser
takes about 45 to 110 minutes between eruptions, though more recently, its
eruptions have tended to be larger and consequently farther apart as more water is needed to replenish the geyser.
Old Faithful
is also a great example of a cone geyser.
Unlike
fountain geysers, which erupt from a pool of water, cone geysers erupt from a
cone shaped structure formed from the mineral-rich water that constantly shoots
from its opening.
· Grand Geyser: The tallest regularly
erupting geyser on Earth, Grand Geyser routinely fires water up to 200 feet (61
meters) into the air.
Located in
Yellowstone National Park, Grand Geyser is a great example of a fountain
geyser.
Unlike cone
geysers, which tend to produce a fairly vertical, constant column of water,
fountain geysers erupt in a much more chaotic fashion.
· Strokkur Geyser: This geyser, named after
the Icelandic verb "to churn," is known for its frequent eruptions,
which occur five to 10 minutes apart.
First active
in 1789, Strokkur became inactive in 1896 after an earthquake hit the area and
blocked its plumbing system.
In 1963,
locals cleared the blockage and the geyser has remained active ever since.
· Steamboat Geyser: Don't bother waiting for
one of Steamboat's massive eruptions.
While
Steamboat is considered to be the world's tallest active geyser, shooting water
up to 300 feet (91 meters) in the air, the geyser is also notoriously finicky.
At one point,
the geyser went 50 years without an eruption.
· Waimangu Geyser: The highest geyser
eruption of all time took place at New Zealand's Waimangu Valley.
In 1902, a
geyser in the valley reportedly spouted water 1,475 feet (450 meters) in the
air.
Unfortunately,
the geyser became inactive after a landslide in 1904, putting a premature end
to a truly spectacular sight.
WHAT'S WITH THE NAME?
You probably
don't have to stretch your imagination to figure out how geothermal features
like hot springs and mud pools get their names.
The origin of
the word "geyser," on the other hand, is a bit more mysterious.
The word
"geyser" actually relates back to the first geyser ever discovered,
Iceland's Geysir. Geysir, discovered in 1294, is fittingly named after the
Icelandic verb "to gush" (gjósa).
Human Interaction with Geysers
 |
| People should be careful around geysers. In 2001, an erupting geyser in Kuirau Park, New Zealand, damaged trees in the area and splattered the park with mud. |
Considering
the spectacle of a geyser eruption, it's no surprise that tourism is the most
common way that people interact with geysers.
Tourism serves
to educate the public both on how geysers work and on what it takes to protect
these natural resources.
Parks often
take great care to control how tourists interact with geysers, in part because
tourists can harm geysers with their trash and debris, but also because geysers
are quite capable of harming tourists as well.
In 1903, four
tourists visiting New Zealand got caught in a geyser jet in Waimangu Valley.
The eruption killed all four people and carried them more than a mile (1.6
kilometers) away from its source.
While such
incidents are rare, we should always remain conscious of the amazing forces
behind geysers.
Geysers serve
as more than tourist attractions, however.
The same
geothermal energy that drives geyser activity can also be used to generate
power for houses and businesses.
While
geothermal energy can provide a clean source of electricity, tapping into that
source can sometimes create major consequences for geothermal features in the
area by draining the geyser fields of their water or energy.
People have
also been known to intentionally destroy geysers through vandalism, throwing
trash and debris into a geyser's opening and blocking its plumbing system.
It's somewhat
ironic, then, that man has also gone to great lengths to create
"artificial" geysers by digging wells that tap into a geothermal heat
source.
While that
type of geyser has a man-made plumbing system, its eruptions are driven by the
same forces that power its natural counterparts.
People have
also put a lot of energy into repairing natural geysers, as in the case of Iceland's
Strokkur Geyser.
As we
understand more about how fragile geysers are, we'll see more measures put in
place to protect these natural wonders.
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