Basaltic and Volcanic Aquifers are formed by volcanic activity at the earths surface. Volcanic rocks have a wide range of chemical, mineralogic, structural, and hydraulic properties, due mostly to variations in rock type and the way the rock was ejected and deposited. Unaltered pyroclastic rocks, for example, might have porosity and permeability similar to poorly sorted sediments. Hot pyroclastic material, however, might become welded as it settles, and, thus, be almost impermeable. Silicic lavas tend to be extruded as thick, dense flows, and they have low permeability except where they are fractured. Basaltic lavas tend to be fluid, and, they form thin flows that have considerable pore space at the tops and bottoms of the flows. Numerous basalt flows commonly overlap, and the flows are separated by soil zones or alluvial material that form permeable zones. Columnar joints that develop in the central parts of basalt flows create passages that allow water to move vertically through the basalt. Basaltic rocks are the most productive aquifers in volcanic rocks.
The variety of rocks resulting from volcanic activity is so great, it is difficult to find representative examples. Basaltic rocks form most of the volcanic-rock aquifers mapped. These flows cover extensive areas in the northwestern United States and Hawaii. In places, the basaltic-rock aquifers are extremely thick. For example, those of the Columbia Plateau aquifer system in Washington are more than 2,544 meters thick in places, and those of the Snake River Plain aquifer system in Idaho are locally more than 800 meters thick. In most places, however, the thickness of these aquifers is 100 meters or less. Ground-water flow in the basaltic-rock aquifers is local to intermediate. In Idaho, the basaltic-rock aquifers are extremely permeable, and numerous large springs discharge several tens of cubic meters per second from them.