The national park lies above an underground
evaporite layer or
salt bed, which is the main cause of the formation of the arches, spires, balanced rocks,
sandstone fins, and eroded monoliths in the area. This salt bed is thousands of feet thick in places and was deposited in the
Paradox Basin of the
Colorado Plateau some 300 million years ago (Mya) when a sea flowed into the region and eventually evaporated. Over millions of years, the salt bed was covered with debris eroded from the
Uncompahgre Uplift to the northeast. During the Early
Jurassic (about 200 Mya), desert conditions prevailed in the region and the vast
Navajo Sandstone was deposited. An additional sequence of stream laid and windblown sediments, the
Entrada Sandstone (about 140 Mya), was deposited on top of the Navajo. Over 5,000 feet (1,500 m) of younger sediments were deposited and have been mostly eroded. Remnants of the cover exist in the area including exposures of the
Cretaceous Mancos Shale. The arches of the area are developed mostly within the Entrada formation. The weight of this cover caused the salt bed below it to liquefy and thrust up layers of rock into
salt domes. The evaporites of the area formed more unusual "salt
anticlines" or linear regions of uplift. The problem lies within the soil's crust, which is composed of
cyanobacteria, algae, fungi, and lichens that grow in the dusty parts of the park. Factors that make Arches National Park sensitive to visitor damage include being a semiarid region, the scarce, unpredictable rainfall, lack of deep freezing, and lack of plant litter, which results in soils that have both a low resistance to and slow recovery from, compressional forces such as foot traffic. Methods of indicating effects on the soil are cytophobic soil crust index, measuring of water infiltration, and t-tests that are used to compare the values from the undisturbed and disturbed areas.
Arch formation Geological processes that occurred over 300 million years ago caused a
salt bed to be deposited, which today lies beneath the landscape of Arches National Park. Over time, the salt bed was covered with
sediments that eventually compressed into rock layers that have since been named
Entrada Sandstone. Rock layers surrounding the edge of the salt bed continued to erode and shift into vertical sandstone walls called
fins. Sand collected between vertical walls of the fins, then slightly acidic rain combined with
carbon dioxide in the air allowed for the chemical formation of
carbonic acid within the trapped sand. Over time, the carbonic acid dissolved the
calcium carbonate that held the
sandstone together. Many of the
rock formations have weaker layers of rock on bottom that are holding stronger layers on top. The weaker layers would
dissolve first, creating openings in the rock.
Gravity caused pieces of the stronger rock layer to fall piece by piece into an arch shape.
Arches form within rock fins at points of intense fracturing localization, or weak points in the rock's formation, caused by horizontal and vertical discontinuities. Lastly, water, wind, and time continued this
erosion process and ultimately created the arches of Arches National Park. Vertical arches can be developed from Slick rock members, a combination of Slick rock members and Moab members, or Slick rock members resting above Dewey rock members. Horizontal arches (also called potholes) are formed when a vertical pothole formation meets a horizontal
cave, causing a union into a long arch structure. The erosion process within Arches National Park will continue as time continues to pass. Continued erosion combined with vertical and horizontal stress will eventually cause arches to collapse, but still, new arches will continue to form for thousands of years.
Climate According to the
Köppen climate classification system, Arches Visitor Center has a
cold semi-arid climate (
BSk). {{Weather box|width=auto ==Plants and animals==