Tuesday, August 31, 2010

Geothermal: Getting energy from the Earth

A good round-up of the potential and current status of geothermal
energy around the world.


Geothermal: Getting energy from the Earth

by Lester Brown

31 Aug 2010 10:32 AM

Steam rising from a geothermal power plant in Iceland.Steam rising
from a geothermal power plant in Iceland.Photo: Wikipedia CommonsThe
heat in the upper six miles of the Earth's crust contains 50,000 times
as much energy as found in all the world's oil and gas reserves
combined. Despite this abundance, only 10,700 megawatts of geothermal
electricity generating capacity have been harnessed worldwide.

Partly because of the dominance of the oil, gas, and coal industries,
which have been providing cheap fuel by omitting the costs of climate
change and air pollution from fuel prices, relatively little has been
invested in developing the Earth's geothermal heat resources. Over the
last decade, geothermal energy has been growing at scarcely 3 percent
a year.

Roughly half the world's existing generating capacity is in the United
States and the Philippines. Indonesia, Mexico, Italy, and Japan
account for most of the remainder. Altogether some 24 countries now
convert geothermal energy into electricity. El Salvador, Iceland, and
the Philippines respectively get 26, 25, and 18 percent of their
electricity from geothermal power plants.

The potential of geothermal energy to provide electricity, to heat
homes, and to supply process heat for industry is vast. Among the
countries rich in geothermal energy are those bordering the Pacific in
the so-called "Ring of Fire," including Chile, Peru, Colombia, Mexico,
the United States, Canada, Russia, China, Japan, the Philippines,
Indonesia, and Australia. Other geothermally rich countries include
those along the Great Rift Valley of Africa, such as Kenya and
Ethiopia, and those around the Eastern Mediterranean.

Beyond geothermal electrical generation, an estimated 100,000 thermal
megawatts of geothermal energy are used directly -- without conversion
into electricity -- to heat homes and greenhouses and as process heat
in industry. This includes, for example, the energy used in hot baths
in Japan and to heat homes in Iceland and greenhouses in Russia.

An interdisciplinary team of 13 scientists and engineers assembled by
the Massachusetts Institute of Technology (MIT) in 2006 assessed U.S.
geothermal electrical generating potential. Drawing on the latest
technologies, including those used by oil and gas companies in
drilling and in enhanced oil recovery, the team estimated that
enhanced geothermal systems could be used to massively develop
geothermal energy. This technology involves drilling down to the hot
rock layer, fracturing the rock and pumping water into the cracked
rock, then extracting the superheated water to drive a steam turbine.
The MIT team notes that with this technology, the United States has
enough geothermal energy to meet its energy needs 2,000 times over.

Though it is still costly, this technology can be used almost anywhere
to convert geothermal heat into electricity. Australia is currently
the leader in developing pilot plants using this technology, followed
by Germany and France. To fully realize this potential for the United
States, the MIT team estimated that the government would need to
invest $1 billion in geothermal research and development in the years
immediately ahead, roughly the cost of one coal-fired power plant.

Even before this exciting new technology is widely deployed, investors
are moving ahead with existing technologies. For many years, U.S.
geothermal energy was confined largely to the Geysers project north of
San Francisco, easily the world's largest geothermal generating
complex, with 850 megawatts of generating capacity. Now the United
States, which has more than 3,000 megawatts of geothermal generation,
is experiencing a geothermal renaissance. Some 152 power plants under
development in 13 states are expected to nearly triple U.S. geothermal
generating capacity. With California, Nevada, Oregon, Idaho, and Utah
leading the way, and with many new companies in the field, the stage
is set for massive U.S. geothermal development.

Indonesia, richly endowed with geothermal energy, stole the spotlight
in 2008 when it announced a plan to develop 6,900 megawatts of
geothermal generating capacity. The Philippines is also planning a
number of new projects.

Among the Great Rift countries in Africa -- including Tanzania, Kenya,
Uganda, Eritrea, Ethiopia, and Djibouti -- Kenya is the early leader.
It now has over 100 megawatts of geothermal generating capacity and is
planning 1,200 more megawatts by 2015. This would nearly double its
current electrical generating capacity of 1,300 megawatts from all

Japan, which has a total of 535 megawatts of generating capacity, was
an early leader in this field. Now, following nearly two decades of
inactivity, this geothermally rich country -- long known for its
thousands of hot baths -- is again beginning to build geothermal power

In Europe, Germany has five small geothermal power plants in operation
and some 150 plants in the pipeline. Werner Bussmann, head of the
German Geothermal Association, says, "Geothermal sources could supply
Germany's electricity needs 600 times over."

Beyond geothermal power plants, geothermal (ground source) heat pumps
are now being widely used for both heating and cooling. These take
advantage of the remarkable stability of the Earth's temperature near
the surface and then use that as a source of heat in the winter when
the air temperature is low and a source of cooling in the summer when
the temperature is high. The great attraction of this technology is
that it can provide both heating and cooling and do so with 25-50
percent less electricity than would be needed with conventional
systems. In Germany, for example, there are now 178,000 geothermal
heat pumps operating in residential or commercial buildings. This base
is growing steadily, as at least 25,000 new pumps are installed each

In the direct use of geothermal heat, Iceland and France are among the
leaders. Iceland's use of geothermal energy to heat almost 90 percent
of its homes has largely eliminated coal for this use. Geothermal
energy accounts for more than one third of Iceland's total energy use.
Following the two oil price hikes in the 1970s, some 70 geothermal
heating facilities were constructed in France, providing both heat and
hot water for an estimated 200,000 residences. Other countries that
have extensive geothermally based district-heating systems include
China, Japan, and Turkey.

Geothermal heat is ideal for greenhouses in northern countries.
Russia, Hungary, Iceland, and the United States are among the many
countries that use it to produce fresh vegetables in the winter. With
rising oil prices boosting fresh produce transport costs, this
practice will likely become far more common in the years ahead.

Among the 22 countries using geothermal energy for aquaculture are
China, Israel, and the United States. In California, for example, 15
fish farms annually produce some 10 million pounds of tilapia, striped
bass, and catfish using warm water from underground.

Hot underground water is widely used for both bathing and swimming.
Japan has 2,800 spas, 5,500 public bathhouses, and 15,600 hotels and
inns that use geothermal hot water. Iceland uses geothermal energy to
heat 135 public swimming pools, most of them year-round open-air
pools. Hungary heats 1,200 swimming pools with geothermal energy.

If the four most populous countries located on the Pacific Ring of
Fire -- the United States, Japan, China, and Indonesia -- were to
seriously invest in developing their geothermal resources, they could
easily make this a leading world energy source. With a conservatively
estimated potential in the United States and Japan alone of 240,000
megawatts of generation, it is easy to envisage a world with thousands
of geothermal power plants generating some 200,000 megawatts of
electricity by 2020. For direct use of geothermal heat, the 2020 Plan
B goal is 500,000 thermal megawatts. All together, the geothermal
potential is enormous.

Adapted from Chapter 5, "Stabilizing Climate: Shifting to Renewable
Energy,� in Lester R. Brown, Plan B 4.0: Mobilizing to Save

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