An
aquitard is a zone within the Earth that restricts the flow of groundwater from one aquifer to another. An aquitard can sometimes, if completely impermeable, be called an
aquiclude or
aquifuge. Aquitards are composed of layers of either
clay or non-porous rock with low
hydraulic conductivity.
Saturated versus unsaturated Groundwater can be found at nearly every point in the Earth's shallow subsurface to some degree, although aquifers do not necessarily contain
fresh water. The Earth's crust can be divided into two regions: the
saturated zone or
phreatic zone (e.g., aquifers, aquitards, etc.), where all available spaces are filled with water, and the
unsaturated zone (also called the
vadose zone), where there are still pockets of air that contain some water, but can be filled with more water.
Saturated means the pressure head of the water is greater than
atmospheric pressure (it has a gauge pressure > 0). The definition of the water table is the surface where the
pressure head is equal to atmospheric pressure (where gauge pressure = 0).
Unsaturated conditions occur above the water table where the pressure head is negative (absolute pressure can never be negative, but gauge pressure can) and the water that incompletely fills the pores of the aquifer material is under
suction. The
water content in the unsaturated zone is held in place by surface
adhesive forces and it rises above the water table (the zero-
gauge-pressure isobar) by
capillary action to saturate a small zone above the phreatic surface (the
capillary fringe) at less than atmospheric pressure. This is termed tension saturation and is not the same as saturation on a water-content basis. Water content in a capillary fringe decreases with increasing distance from the phreatic surface. The capillary head depends on soil pore size. In
sandy soils with larger pores, the head will be less than in clay soils with very small pores. The normal capillary rise in a clayey soil is less than but can range between . The capillary rise of water in a small-
diameter tube involves the same physical process. The water table is the level to which water will rise in a large-diameter pipe (e.g., a well) that goes down into the aquifer and is open to the atmosphere.
Aquifers versus aquitards Aquifers are typically saturated regions of the subsurface that produce an economically feasible quantity of water to a well or
spring (e.g., sand and
gravel or fractured
bedrock often make good aquifer materials). An aquitard is a zone within the Earth that restricts the flow of groundwater from one aquifer to another. A completely impermeable aquitard is called an
aquiclude or
aquifuge. Aquitards contain layers of either clay or non-porous rock with low
hydraulic conductivity. In mountainous areas especially near rivers, the main aquifers are typically unconsolidated
alluvium, that is horizontal layers of materials deposited by water processes such as rivers and streams. In cross-section, they appear as layers of alternating coarse and fine materials. Coarse materials, because of the high energy needed to move them, tend to be found nearer to their source, such as mountain fronts or rivers, whereas the fine-grained material travels farther, to the flatter parts of the basin or overbank areas—sometimes called the pressure area. Since there are less fine-grained deposits near the source, those aquifers, also known as the fore-bay area, are often unconfined or in hydraulic communication with the land surface.
Confined versus unconfined An unconfined aquifer has no impermeable barrier immediately above it, such that the water level can rise in response to recharge. A confined aquifer has an overlying impermeable barrier that prevents the water level in the aquifer from rising any higher. An aquifer in the same geologic unit may be confined in one area and unconfined in another.
Unconfined aquifers are sometimes also called
water table or
phreatic aquifers, because their upper boundary is the
water table or phreatic surface (see
Biscayne Aquifer). Typically (but not always) the shallowest aquifer at a given location is unconfined, meaning it does not have a confining layer (an aquitard or aquiclude) between it and the surface. The term "perched" refers to ground water accumulating above a low-permeability unit or strata, such as a clay layer. This term is generally used to refer to a small local area of ground water that occurs at an elevation higher than a regionally extensive aquifer. The difference between perched and unconfined aquifers is their size (perched is smaller). Confined aquifers are aquifers that are overlain by a confining layer, often made up of clay. The confining layer might offer some protection from surface contamination. If the distinction between confined and unconfined is not clear geologically (i.e., if it is not known if a clear confining layer exists, or if the geology is more complex, e.g., a fractured bedrock aquifer), the value of storativity returned from an
aquifer test can be used to determine it (although aquifer tests in unconfined aquifers should be interpreted differently than confined ones). Confined aquifers have very low
storativity values (much less than 0.01, and as little as ), which means that the aquifer is storing water using the mechanisms of aquifer matrix expansion and the compressibility of water, which typically are both quite small quantities. Unconfined aquifers have storativities (typically called
specific yield) greater than 0.01 (1% of bulk volume); they release water from storage by the mechanism of actually draining the pores of the aquifer, releasing relatively large amounts of water (up to the drainable
porosity of the aquifer material, or the minimum volumetric
water content).
Isotropic versus anisotropic In
isotropic aquifers or aquifer layers the hydraulic conductivity (K) is equal for flow in all directions, while in
anisotropic conditions it differs, notably in horizontal (Kh) and vertical (Kv) sense. Semi-confined aquifers with one or more aquitards work as an anisotropic system, even when the separate layers are isotropic, because the compound Kh and Kv values are different (see
hydraulic transmissivity and
hydraulic resistance). When calculating
flow to drains or
flow to wells in an aquifer, the anisotropy is to be taken into account lest the resulting design of the drainage system may be faulty.
Porous, karst, or fractured To properly manage an aquifer its properties must be understood. Many properties must be known to predict how an aquifer will respond to rainfall, drought, pumping, and
contamination. Considerations include where and how much water enters the groundwater from rainfall and snowmelt, how fast and in what direction the groundwater travels, and how much water leaves the ground as springs.
Computer models can be used to test how accurately the understanding of the aquifer properties matches the actual aquifer performance. Environmental regulations require sites with potential sources of contamination to demonstrate that the
hydrology has been
characterized. Sandy deposits formed in
shallow marine environments and in
windblown sand dune environments have moderate to high permeability while sandy deposits formed in
river environments have low to moderate permeability. as illustrated by the water slowly seeping from sandstone in the accompanying image to the left. Porosity is important, but,
alone, it does not determine a rock's ability to act as an aquifer. Areas of the
Deccan Traps, a
basaltic lava formation in west-central India, are examples of rock formations with high porosity but low permeability, making them poor aquifers. Similarly, the micro-porous (Upper
Cretaceous)
Chalk Group of south east England, although having a reasonably high porosity, has a low grain-to-grain permeability, with its good water-yielding characteristics mostly due to micro-fracturing and fissuring.
Karst .
Karst aquifers typically develop in
limestone. Surface water containing natural
carbonic acid moves down into small fissures in limestone. This carbonic acid gradually dissolves limestone thereby enlarging the fissures. The enlarged fissures allow a larger quantity of water to enter which leads to a progressive enlargement of openings. Abundant small openings store a large quantity of water. The larger openings form a conduit system that drains the aquifer to springs. Characterization of karst aquifers requires field exploration to locate
sinkholes, swallets,
sinking streams, and
springs in addition to studying
geological maps. Conventional hydrogeologic methods such as aquifer tests and potentiometric mapping are insufficient to characterize the complexity of karst aquifers. These conventional investigation methods need to be supplemented with
dye traces, measurement of spring discharges, and analysis of water chemistry. U.S. Geological Survey dye tracing has determined that conventional groundwater models that assume a uniform distribution of porosity are not applicable for karst aquifers. Linear alignment of surface features such as straight stream segments and sinkholes develop along
fracture traces. Locating a well in a fracture trace or intersection of fracture traces increases the likelihood to encounter good water production. Voids in karst aquifers can be large enough to cause destructive collapse or
subsidence of the ground surface that can initiate a catastrophic release of contaminants. The rapid groundwater flow rates make
karst aquifers much more sensitive to groundwater contamination than porous aquifers. == Human use of groundwater ==