How a Geysers work?

Geysers are intermittent hot springs or fountains in which columns of water are ejected with great force at various intervals, often rising 30 to 60 meters (100 to 200 feet) into the air. After the jet of water ceases, a column of steam rushes out, usually with a thunderous roar. Perhaps the most famous geyser in the world is Old Faithful in Yellowstone National Park (Figure 1).

Old Faithful
Figure 1 – Old Faithful This geyser in Wyoming’s Yellowstone National Park is one of the most famous in the world. Contrary to popular legend, it does not erupt every hour on the hour. Time spans between eruptions vary from about 65 minutes to more than 90 minutes and have generally increased over the years due to changes in the geyser’s plumbing. (Photo by Jeff Vanuga/Corbis)

The great abundance, diversity, and spectacular nature of geysers and other thermal features in Yellowstone undoubtedly was the primary reason for it’s becoming the first national park in the United States. Geysers are also found in other parts of the world, notably New Zealand and Iceland. In fact, the Icelandic word geyser, meaning “to gush,” gives us the name geyser.

How a Geysers Work?

Geysers occur where extensive underground chambers exist within hot igneous rocks. How they operate is shown in Figure 2. As relatively cool groundwater enters these chambers, it is heated by the surrounding rock.

How a Geysers Work
Figure 2 – How a geyser works A geyser can form if the underground plumbing does not allow heat to be readily distributed by convection.

At the bottom of the chambers, the water is under great pressure because of the weight of the overlying water. This great pressure prevents the water from boiling at the normal surface temperature of 100°C (212°F). For example, water at the bottom of a 300-meter (1000-foot) water-filled chamber must attain nearly 230°C (450°F) before it will boil. The heating causes the water to expand, and as a result, some is forced out at the surface. This loss of water reduces the pressure on the remaining water in the chamber, which lowers the boiling point. A portion of the water deep within the chamber quickly turns to steam, and the geyser erupts. Following the eruption, cool groundwater again seeps into the chamber, and the cycle begins anew.

Geyser Deposits

When groundwater from hot springs and geysers flows out at the surface, material in solution is often precipitated, producing an accumulation of chemical sedimentary rock. The material deposited at any given place commonly reflects the chemical makeup of the rock through which the water circulated. When the water contains dissolved silica, a material called siliceous sinter, or geyserite, is deposited around the spring. When the water contains dissolved calcium carbonate, a form of limestone called travertine, or calcareous tufa, is deposited. The latter term is used if the material is spongy and porous.

hot springs in Yellowstone
Figure 3 – Yellowstone’s Mammoth Hot Springs Although most of the deposits associated with geysers and hot springs in Yellowstone National Park are silica-rich geyserite, the deposits here consist of a form of limestone called travertine. (Photo by Jamie and Judy Wild/ Danita Delimont/Alamy)

The deposits at Mammoth Hot Springs in Yellowstone National Park are more spectacular than most others (Figure 3). As the hot water flows upward through a series of channels and then out at the surface, the reduced pressure allows carbon dioxide to separate and escape from the water. The loss of carbon dioxide causes the water to become supersaturated with calcium carbonate, which then precipitates. In addition to containing dissolved silica and calcium carbonate, some hot springs contain sulfur, which gives water a poor taste and unpleasant odour. This is undoubtedly the case at Rotten Egg Spring, Nevada.

By: E. J. Tarbuck, F. K. Lutgens Illustrated by D. Tasa. Featured pic from JimAnna chronicles

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