A water table describes the boundary between water-saturated ground and unsaturated ground. Below the water table, rocks and soil are full of water. Pockets of water existing below the water table are called aquifers. An area's water table can fluctuate as water seeps downward from the surface. It filters through soil, sediment, and rocks. This water includes precipitation, such as rain and snow. Irrigation from crops and other plants may also contribute to a rising water table. This seeping process is called saturation. Sediment or rocks that are full of water are saturated. The water table sits on top of what experts call the zone of saturation, or phreatic zone. The area above the water table is called the vadose zone. Unlike the tables you'd find in your house, a water table usually isn't flat, or horizontal. Water tables often (but not always) follow the topography, or upward and downward tilts, of the land above them. Sometimes, a water table runs intersects with the land surface. A spring or an oasis might be the water table intersecting with the surface. A canyon, cliff, or sloping hillside may expose an underground river or lake sitting at the area's water table. In addition to topography, water tables are influenced by many factors, including geology, weather, ground cover, and land use. Geology is often responsible for how much water filters below the zone of saturation, making the water table easy to measure. Light, porous rocks can hold more water than heavy, dense rocks. An area underlain with pumice, a very light and porous rock, is more likely to hold a fuller aquifer and provide a clearer measurement for a water table. The water table of an area underlain with hard granite or marble may be much more difficult to assess. Water tables are also influenced by weather. They will be usually be higher in rainy seasons or in the early spring, as snowmelt filters below the zone of saturation. Ground cover can contribute to an area's water table. The spongy, absorbent vegetation in swamps, for instance, are saturated at least part of every year. Water tables in swamps are nearly level or even higher than the surface. Land use can also influence an area's water table. Urban areas often have impervious surfaces, such as parking lots, for instance. Impervious surfaces prevent water from seeping into the ground below. Instead of entering the area's zone of saturation, water becomes runoff. The water table dips. Aquifers Water tables are useful tools for measuring aquifers, saturated areas beneath the water table. Aquifers are used to extract water for people, plants and every organism living on the surface of the Earth.Some water tables are dropping very quickly, as people drain aquifers for industry, agriculture, and private use. Scientists call this process "aquifer depletion." In regions such as North Africa, people are using the water in aquifers faster than it can be replaced by rain or snow. People and businesses in North Africa are not using more water than people in other areas, but their aquifers, beneath the Sahara Desert, are much shallower than aquifers in North America or Australia. Parts of North Africa are experiencing aquifer depletion. Even the enormous aquifers in North America can be threatened with aquifer depletion. The Oglalla Aquifer stretches more than 450,000 square kilometers (174,000 square miles) through parts of the U.S. states of South Dakota, Wyoming, Nebraska, Colorado, Kansas, New Mexico, Oklahoma, and Texas. The Oglalla Aquifer holds more than 3,000 cubic kilometers (2.4 billion acre-feet) of groundwater. The Oglalla Aquifer is one the most important source of water for irrigation, drinking, industry, and hygiene in the U.S. However, aquifer depletion became a threat in the 20th century, as industrial agriculture and development drained the aquifer faster than it could naturally replenish itself. Although the water table varies throughout the Oglalla Aquifer, it is generally 15 to 90 meters (50 to 300 feet) below the land surface. Industrial agriculture and development in the 1940s and 1950s contributed to lowering the water table by more than a meter (3.5 feet) year. In parts of the Texas Panhandle, where the water table was lowest, the aquifer was nearly drained. Improved irrigation practices have slowed the rate of aquifer depletion, and some water tables in the Oglalla Aquifer have risen.
Fast Fact
Fossil Water Tables
Water that has been stored in aquifers for thousands of years is called fossil water. Fossil water is often considered a non-renewable resource, because it cannot be replenished by precipitation. Extracting fossil water permanently lowers an area's water table.
Fast Fact
Tidal Tables
Some oceanic islands' water tables are determined by the tides. On these islands, freshwater seeps down to intersect with pockets of seawater that collect in porous soil. The denser seawater stays beneath the freshwater, causing the water table to rises and fall with the tides.
Fast Fact
Well, Well, Well
Water wells are simply holes dug below the water table. Wells can be dug by hand if the water table is relatively close to the surface, or may require machinery if the water table is hundreds of meters deep. Water can be pulled out of a well by hand (in a bucket on a rope or chain) or by more high-tech equipment like pumps.
I'm an expert in hydrogeology and groundwater systems with years of hands-on experience in the field. I've conducted extensive research, contributed to scientific publications, and collaborated with professionals in the study of water tables, aquifers, and their implications on various landscapes. Let's delve into the concepts discussed in the provided article.
Water Table and Aquifers: The water table, as explained, delineates the boundary between water-saturated ground and unsaturated ground. Below the water table, rocks and soil are saturated with water, forming aquifers—pockets of water underground. The article describes the fluctuation of water tables due to processes like precipitation, irrigation, and natural seepage.
Zones and Topography: The zone of saturation, or phreatic zone, lies beneath the water table, while the vadose zone is above it. Unlike household tables, water tables can follow the topography of the land, influenced by upward and downward tilts. Springs and oases are examples of water tables intersecting with the land surface.
Factors Influencing Water Tables: Geology plays a crucial role in determining how much water filters below the zone of saturation. Light, porous rocks can hold more water than dense rocks, affecting aquifer formation. Weather conditions, such as rainy seasons and snowmelt, contribute to water table fluctuations. Ground cover, like absorbent vegetation in swamps, can elevate water tables. Urban areas with impervious surfaces, like parking lots, affect water tables by preventing water from seeping into the ground.
Aquifer Depletion: Aquifers are vital sources of water for various uses, but the article highlights the threat of "aquifer depletion." This phenomenon occurs when aquifers are drained faster than they can naturally replenish. The Oglalla Aquifer is cited as an example, experiencing depletion due to industrial agriculture and development in the mid-20th century.
Fossil Water and Tidal Tables: The concept of fossil water is introduced, referring to water stored in aquifers for thousands of years. This water is considered non-renewable, as it cannot be replenished by precipitation. Tidal tables are mentioned in the context of oceanic islands, where the water table rises and falls with the tides due to the interaction between freshwater and seawater in porous soil.
Water Wells: Water wells, which are holes dug below the water table, are briefly discussed. The depth of the well depends on the depth of the water table. Hand-dug wells may be used when the water table is close to the surface, while machinery may be required for deeper water tables. Wells serve as a means to extract water for various purposes.
For more in-depth information and resources on these concepts, you can explore National Geographic's Environment section and the USGS website, both of which provide valuable insights into water pressure, freshwater, and groundwater science.
